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Impacts of epigenetic reprogramming on innate immunity

Published online by Cambridge University Press:  04 June 2024

Jie Fu
Affiliation:
Key Laboratory of Molecular Animal Nutrition, Ministry of Education, College of Animal Sciences, Zhejiang University, Hangzhou, China Key Laboratory of Animal Nutrition and Feed Science in Eastern China, Ministry of Agriculture, Hangzhou, Zhejiang Province, China
Yizhen Wang*
Affiliation:
Key Laboratory of Molecular Animal Nutrition, Ministry of Education, College of Animal Sciences, Zhejiang University, Hangzhou, China Key Laboratory of Animal Nutrition and Feed Science in Eastern China, Ministry of Agriculture, Hangzhou, Zhejiang Province, China
*
Corresponding author: Yizhen Wang; Email: [email protected]
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Abstract

The innate immune response is the host’s first line of defense, promptly activated upon pathogen invasion. Its precise and rapid activation relies on innate immune cells (IICs). Upon recognizing danger signals postinfection or injury, they release various innate immune effectors to eliminate invading pathogens or damaged cells, thus supporting the host’s immune homeostasis. Epigenetic modifications, by shaping chromatin structures, orchestrate specific gene transcription patterns to regulate the lineage development, differentiation, and activation of IICs. This intricate process ultimately contributes to effective pathogen clearance and IICs’ healthy development and differentiation. To thoroughly elucidate the epigenetic mechanisms underlying the development and differentiation of IICs, this review first introduces the fundamental concepts and latest advancements in this field. We then delve into how the immune microenvironment or other signaling molecules shape the epigenetic landscapes of distinct IIC subsets during their lineage development and differentiation. Furthermore, we summarize how different epigenetic modification profiles mediate specific transcriptional patterns, thereby influencing the lineage development, differentiation, and activation of IICs in response to infections or injuries. Finally, we discuss several unresolved critical issues from the perspective of targeting epigenetic modifications to modulate the innate immune response. In summary, this review aims to uncover the molecular mechanisms underlying the development, differentiation, and activation of IICs from an epigenetic perspective, providing theoretical foundations for scientific and medical researchers pursuing disease treatments.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Zhejiang University and Zhejiang University Press.

Introduction

During differentiation, development, infection, stress, and damage repair, innate immune cells (IICs), including macrophages, dendritic cells (DCs), neutrophils, and innate lymphoid cells (ILCs), assume specific gene expression patterns in response to the modulation of the local immune microenvironment (Zhang and Cao Reference Zhang and Cao2021). These patterns confer distinct phenotypes and biological functions to the IICs. IICs recognize danger signals following infection or injury through pattern recognition receptors (PRRs), which can detect pathogen-associated molecular patterns (PAMPs) or damage-associated molecular patterns (DAMPs). Subsequently, IICs release various innate immune effectors to eliminate invading pathogens and damaged cells, contributing to the resolution of inflammation and the lineage development and differentiation of IICs (Guo et al. Reference Guo, Wang and Liu2022; Li and Wu Reference Li and Wu2021).

The phenotypes of IICs exhibit a remarkable degree of plasticity, and specific phenotypes confer corresponding functions on IICs (Locati et al. Reference Locati, Curtale and Mantovani2020; Tsioumpekou et al. Reference Tsioumpekou, Krijgsman and Leusen2023). Upon pathogen invasion, IICs swiftly convert from inactivated to activated phenotypes to facilitate the eradication of microbial invaders. Conversely, following pathogen clearance, activated IICs transition to a suppressed state, resulting in reduced inflammatory levels (Cao Reference Cao2016; Zhang and Cao Reference Zhang and Cao2021). However, pathogen invasion or sterile inflammatory signals employ diverse strategies to disrupt the defensive capabilities of the innate immune system. The disruption results in compromised lineage development, differentiation, and subsequent activation of IICs, thereby allowing pathogens to parasitize the host. Dysregulation of innate immune responses can lead to outbreaks of organismal inflammation, subsequent diseases, and even mortality (Amatullah and Jeffrey Reference Amatullah and Jeffrey2020; Martins et al. Reference Martins, Carlos and Braza2019). Therefore, deciphering the molecular mechanisms underlying the lineage development, differentiation, and activation of IICs, along with identifying effectors of innate immune responses, would help identify promising therapeutic targets to address dysregulated innate immune responses in infections and inflammatory diseases.

Epigenetic reshaping serves as the dynamic foundation to regulate gene expression (Fig. 1). Chromatin status changes, mediated by histone modifications in enhancer and promoter regions, play a crucial role in the development, differentiation, and activation of IICs

Figure 1. Introduction to epigenetics. Notes: RNA methylation. RNA is transcribed from DNA and subsequently undergoes reversible methylation modifications catalyzed by METTL3/METTL14/WTAP and FTO/ALKBH5. RNA containing m6A modifications is recognized by reader proteins, mediating diverse biological functions. DNA methylation. Methylation modifications are written by the DNMTs family on gene promoters, enhancers, and gene bodies. These methylation modifications influence neighboring genes’ transcription or chromatin’s openness. ncRNAs. lncRNAs and miRNAs are transcribed from DNA. lncRNAs, classified according to their transcriptional sites, influence gene transcription, chromatin accessibility, and mRNA stability through various mechanisms. miRNAs primarily affect mRNA cleavage and translation. Histone modifications and 3D chromatin structure.

(Fraschilla et al. Reference Fraschilla, Amatullah and Jeffrey2022; Hoeksema and de Winther Reference Hoeksema and de Winther2016; Liotti et al. Reference Liotti, Ferrara and Loffredo2022). DNA methylation modifications at specific sites can either hinder or promote the binding of key transcription factors (TFs) responsible for fate conversion in IICs, inducing or impeding the transcription of critical genes involved in lineage development, differentiation, and activation (Bonder et al. Reference Bonder, Luijk and Zhernakova2017; Dekkers et al. Reference Dekkers, Neele and Jukema2019; de la Rica et al. Reference de la Rica, Rodríguez-Ubreva and García2013; Saeed et al. Reference Saeed, Quintin and Kerstens2014). Histone modifications open up new chromatin accessibility regions, allowing DNA binding by specific transcription complexes or TFs, thereby initiating the transcriptional pattern of particular phenotypes in IICs (Álvarez-Errico et al. Reference Álvarez-Errico, Vento-Tormo and Sieweke2015; Li et al. Reference Li, Ye and Peng2022a). Noncoding RNAs (ncRNAs) impact chromatin accessibility and downstream gene expression by interacting with promoters, enhancers, histones, and transcription complexes (Chen et al. Reference Chen, Yang and Wei2020; Han and Chang Reference Han and Chang2015; Li et al. Reference Li, Wu and Fu2014a). RNA m6A methylation not only regulates chromatin accessibility and transcription rate through co-transcriptional mechanisms but also influences the development and differentiation of IIC lineages and the activation of their key genes by mediating nascent RNA splicing and mRNA metabolism (Boulias and Greer Reference Boulias and Greer2023; Sendinc and Shi Reference Sendinc and Shi2023; Tang et al. Reference Tang, Wang and Xiao2023). Relying on the transcriptional patterns of innate immunity-specific phenotypes mediated by epigenetic reshaping, IICs assume distinct phenotypes and biological functions to facilitate pathogen elimination, reduction of inflammatory levels, and healthy development and differentiation. High-throughput sequencing technology quantitatively reveals various epigenetic modification landscapes in different developmental stages and different activation states of IICs, enabling studies on the impact of epigenetics on the development and activation of IIC lineages (Table 1). Epigenetic modifications allow precise and dynamic reversible control of IICs, and dysregulation in this process can lead to various diseases. Hence, considerable clinical potential resides in harnessing the power of epigenetic modifier enzymes, along with their specific inhibitors and activators, to manipulate the epigenetic modification profile of IICs for the treatment or prevention of infection and inflammation-related diseases.

Table 1. Epigenomic techniques

This review aims to explore how the local ecological microenvironment shaped by the host following the development, differentiation, infection, or inflammatory damage of IIC lineages, modulates the gene expression of epigenetic modification groups and their modifying enzymes. Additionally, it investigates how the epigenetic modifications shaped by the local microenvironment and their modifying enzymes reciprocally mediate specific gene expression patterns in IICs, contributing to the regulation of lineage development, differentiation, and timely response to infections and inflammation.

Components and recent advances in epigenetic modifications

DNA methylation

DNA methylation primarily refers to the methylation of the fifth carbon atom of cytosine in CpG dinucleotides, forming 5-methylcytosine (5mC) (Yang et al. Reference Yang, Xu and Wang2023). Two protein families directly participate in DNA methylation pathways: DNA methyltransferases (DNMTs), which promote and maintain DNA methylation, and the ten-eleven translocation (TET) family proteins, which catalyze multiple steps to remove DNA methylation (Fig. 1). Both two families work coordinately to maintain the transcriptional state, exhibiting different site specificity and dependency (Ginno et al. Reference Ginno, Gaidatzis and Feldmann2020; Lyko Reference Lyko2018; Wu and Zhang Reference Wu and Zhang2011). DNMT3A and DNMT3B, aided by DNMT3L, establish de novo DNA methylation (Schmidl et al. Reference Schmidl, Delacher and Huehn2018). Once established, DNA methylation patterns are stably inherited through cell division by DNMT1, endowing DNA methylation with genuine epigenetic modification capabilities (Allis and Jenuwein Reference Allis and Jenuwein2016; Schmidl et al. Reference Schmidl, Delacher and Huehn2018). DNA methylation modulates gene expression primarily by altering DNA accessibility for transcription, leading to downstream recruitment of proteins that regulate chromatin remodeling. On one hand, DNA methylation can obstruct the binding of TFs to promoters (Schübeler Reference Schübeler2015). On the other hand, TFs can recognize methylated DNA and recruit other TFs to remodel chromatin and initiate transcription (Yin et al. Reference Yin, Morgunova and Jolma2017). Thus, methylated DNA can be recognized by proteins like methyl-CpG binding domain proteins and recruit histone deacetylases (HDACs), thus instigating changes in chromatin structure (Jones et al. Reference Jones, Veenstra and Wade1998). DNA methylation at CpG islands, particularly in promoters, leads to transcriptional inhibition. One example is high methylation levels support processes like X chromosome inactivation and imprinting (Schmidl et al. Reference Schmidl, Delacher and Huehn2018; Schübeler Reference Schübeler2015). However, methylation within CpG islands in the gene body is positively correlated with gene expression (Arechederra et al. Reference Arechederra, Daian and Yim2018; Han et al. Reference Han, Cortez and Yang2011; Mittelstaedt et al. Reference Mittelstaedt, Becker and de Freitas2021). Recently, DNA N6-methyldeoxyadenosine (6mA) within the human genome has come to light (Kong et al. Reference Kong, Cao and Deikus2022; Xiao et al. Reference Xiao, Zhu and He2018). Numerous studies underscore the unique biological and pathological significance of 6mA in modulating gene transcription, chromatin structure, and disease progression (Boulias and Greer Reference Boulias and Greer2022; Feng and He Reference Feng and He2023). Current data suggest a potentially conserved function of 6mA in recognizing and clearing exogenous DNA, thereby participating in immune regulation (Boulias and Greer Reference Boulias and Greer2022; Xiao et al. Reference Xiao, Zhu and He2018).

With the continual advancement in DNA methylation sequencing and molecular biology techniques, our understanding of the functions of DNA methylation is challenging and overturning prior simplistic understandings. Epigenetics mediated by DNA methylation represents a crucial pathway governing the development and activation of the innate immune system. Notably, DNA methylation can undergo rapid changes, especially in response to dynamically shifting environments during pathogenic infections (Qin et al. Reference Qin, Scicluna and van der Poll2021a). Remarkably, mounting evidence suggests that pathogens possess the capacity to manipulate DNA methylation or regulate the transcription and activity of DNA methylation-modifying factors like TET and DNMT, leading to transcriptional changes in core gene clusters associated with immune responses (Lutz et al. Reference Lutz, Chay and Pacis2021; Pacis et al. Reference Pacis, Mailhot-Léonard and Tailleux2019, Reference Pacis, Tailleux and Morin2015). These shifts in DNA methylation or its modifying agents can play opposite roles, contributing to host immune defense against pathogens or providing pathogens with the means to evade immune responses. Studies indicate that DNA methylation plays a role in regulating monocyte-to-macrophage differentiation, DCs maturation, macrophage polarization, and in controlling T cell differentiation along with memory responses (Dekkers et al. Reference Dekkers, Neele and Jukema2019; Jain et al. Reference Jain, Shahal and Gabrieli2019; Lau et al. Reference Lau, Adams and Geary2018; McErlean et al. Reference McErlean, Bell and Hewitt2021; Zhang et al. Reference Zhang, He and Xiang2022). Consequently, the utilization of candidate genes and epigenome-wide association studies to profile DNA methylation in infected, injured, and immunologically compromised individuals is being employed to elucidate the biological mechanisms underlying disease susceptibility and severity.

Histone modification

Histones, a group of alkaline proteins found in the nucleus of eukaryotic cells, bind DNA to form nucleosomes, the fundamental structural units of chromatin (Skvortsova et al. Reference Skvortsova, Iovino and Bogdanović2018) (Fig. 1). Generally, a nucleosome comprises 147 base pairs coiled around an octamer consisting of four pairs of histones (H2A, H2B, H3, and H4). Most histones contain a globular domain and an N-terminal tail protruding outside the nucleosome. Under specific enzymatic action, the amino acid residues in the N-terminal tail covalently attach to corresponding biochemical functional groups such as acetyl, methyl, ubiquitin, etc., leading to subsequent posttranslational modifications such as acetylation, methylation, ubiquitination, etc. Notably, covalent modifications of histone N-terminal residues known so far include acetylation, ubiquitination, sumoylation, and biotinylation of lysine; methylation of lysine and arginine; phosphorylation of serine, threonine, and tyrosine, etc. Compared to DNA methylation, histone modifications do not alter the DNA sequence but are more intricate, influencing chromatin structure and transcriptional activity. For instance, histone acetylation serves to diminish the bond strength between histone molecules and DNA or neighboring nucleosomes, relaxing chromatin structure and facilitating accessibility by TFs and chromatin remodeling factors, thus promoting gene transcription and expression. Hence, histone acetylation is often linked to gene activation (Chen et al. Reference Chen, Yang and Wei2020; Pradeepa et al. Reference Pradeepa, Grimes and Kumar2016). The role of histone methylation varies, potentially leading to transcription repression or activation based on the placement of amino acid residues on histone N-termini and the quantity of covalently attached methyl groups. For instance, trimethylation of lysine 4 on histone H3 (H3K4me3) activates transcription, while dimethylation of lysine 9 on histone H3 (H3K9me2) suppresses it (Bernstein et al. Reference Bernstein, Kamal and Lindblad-Toh2005; Comer et al. Reference Comer, Ba and Singer2015). Overall, histone modifications can influence gene expression by altering chromatin structure or recruiting biochemical functional groups. Recently, more and more data suggest the vital importance of histone modifications in gene transcription related to the differentiation and maturation of IIC lineages. These modifications profoundly affect how IICs detect and respond to pathogens, shaping the landscape of associated diseases (Daskalaki et al. Reference Daskalaki, Tsatsanis and Kampranis2018; Li et al. Reference Li, Ye and Peng2022a; Zhao et al. Reference Zhao, Su and Liang2020).

Chromatin remodeling

The condensed state of chromatin hinders processes such as gene transcription, DNA replication, and damage repair at the corresponding chromosomal loci. Consequently, eukaryotes have evolved a set of chromatin remodeling enzymes and associated proteins to regulate chromatin structure through modulating nucleosome assembly, disassembly, and rearrangement on chromatin (Kuzelova et al. Reference Kuzelova, Dupacova and Antosova2023; Narlikar et al. Reference Narlikar, Sundaramoorthy and Owen-Hughes2013; Yang et al. Reference Yang, Jia and Ge2022). One class of proteins involved in this process is the adenosine triphosphate (ATP)-dependent chromatin remodeling complexes (CRCs). These proteins utilize the energy generated by ATP hydrolysis to facilitate the “sliding” of nucleosomes along DNA or mediate the “exchange” between histone variants and canonical histones within the nucleosome. CRCs can be broadly categorized into four major families based on their distinct functional domains: SWI/SNF, ISWI, CHD, and INO80. Despite similarities in protein structure and enzymatic activity among different CRCs, each family exhibits its own specificity. Chromatin remodeling, mediated by CRCs, plays a crucial role in facilitating specific gene transcription, conferring immune cells with the capability to respond to pathogenic infections. For instance, SWI/SNF is involved in chromatin remodeling at the Il-6 gene promoter, thereby promoting Il-6 transcription (Liu et al. Reference Liu, Lu and Zhu2019b). Furthermore, BRG1, an ATPase subunit of the SWI/SNF, is indispensable for the transcription of STAT2-dependent pro-inflammatory cytokine genes during TLR4 activation (Seeley et al. Reference Seeley, Baker and Mohamed2018).

RNA m6A methylation

The discovery of RNA m6A modification dates back to 1974 in murine Novikoff hepatoma cells (Desrosiers et al. Reference Desrosiers, Friderici and Rottman1974). However, it wasn’t extensively studied until 1997 when Bokar et al. isolated the methyltransferase-like 3 (METTL3) protein from Hela cells (Bokar et al. Reference Bokar, Shambaugh and Polayes1997). RNA m6A modification constitutes a dynamic and reversible process that is primarily regulated by three types of enzymes – methyltransferases (writers), demethylases (erasers), and binding proteins (readers) – which collectively modulate posttranscriptional RNA modifications (Fig. 1). The demethylation of RNA m6A primarily relies on the catalysis of demethylases FTO and α-ketoglutarate-dependent dioxygenase ALKBH5 (Jia et al. Reference Jia, Fu and Zhao2011; Zheng et al. Reference Zheng, Dahl and Niu2013). The RNA m6A modification is added to RNA by the multi-subunit writers complex consisting of the METTL3-METTL14 heterodimer and numerous additional adaptor proteins. The methyltransferase complex mainly comprises the catalytic subunit METTL3 (Yao et al. Reference Yao, Sang and Lin2018), the RNA-binding platform METTL14 (Kobayashi et al. Reference Kobayashi, Ohsugi and Sasako2018), and the auxiliary factors Wilms tumor-associated protein WTAP and KIAA1429 (Scholler et al. Reference Scholler, Weichmann and Treiber2018; Schwartz et al. Reference Schwartz, Mumbach and Jovanovic2014). The functional effects of m6A modification on target RNAs are believed to be mediated by “readers” (Riquelme-Barrios et al. Reference Riquelme-Barrios, Pereira-Montecinos and Valiente-Echeverria2018). Among the many “readers,” the YTH domain-containing (YTH) protein family has been well studied (Meyer et al. Reference Meyer, Saletore and Zumbo2012; Patil et al. Reference Patil, Chen and Pickering2016), including cytoplasmic members YTHDF1, YTHDF2, and YTHDF3 (Dominissini et al. Reference Dominissini, Moshitch-Moshkovitz and Schwartz2012; Shi et al. Reference Shi, Wang and Lu2017; Wang et al. Reference Wang, Lu and Gomez2014b, Reference Wang, Zhao and Roundtree2015), as well as nuclear proteins YTHDC1 and YTHDC2 (Hsu et al. Reference Hsu, Zhu and Ma2017; Xu et al. Reference Xu, Wang and Liu2014). In addition to YTH family members, other proteins have been identified to recognize and bind to m6A. The eukaryotic initiation factor 3 complex interacts with m6A-containing 5ʹUTRs through multi-subunit interfaces, directly recruiting the 40S pre-initiation complex to the 5ʹUTR of target mRNA to facilitate translation initiation (Meyer et al. Reference Meyer, Patil and Zhou2015). hnRNPA2/B1 and hnRNPG can bind to m6A-modified RNAs to regulate splicing and microRNA maturation (Alarcon et al. Reference Alarcon, Goodarzi and Lee2015).

RNA m6A modification participates in various biological processes. Recent studies demonstrate that RNA m6A modification not only engages numerous aspects of RNA metabolism, such as splicing, nuclear export, stability, and translation efficiency (Zhou et al. Reference Zhou, Wang and Chang2022), but also dynamically regulates gene transcription directly in a co-transcriptional manner through diverse RNA types, including nascent RNA, long noncoding RNAs (lncRNAs), chromatin-associated regulatory RNAs (carRNAs), endogenous retroviral RNAs, and R-loops (Akhtar et al. Reference Akhtar, Renaud and Albrecht2021; Cen et al. Reference Cen, Li and Cai2020; Li et al. Reference Li, Xia and Tan2020c; Liu et al. Reference Liu, Dou and Chen2020; Sendinc and Shi Reference Sendinc and Shi2023; Xu et al. Reference Xu, He and Kaye2022b, Reference Xu, Li and He2021). On January 31, 2020, the collaborative research team of Chuan He, Dali Han, and Yawei Gao published a groundbreaking study in Science, proposing for the first time that m6A on carRNA regulates chromatin status and transcription (Liu et al. Reference Liu, Dou and Chen2020). They discovered that carRNA can be methylated by METTL3, resulting in m6A modifications. A portion of these m6A-modified carRNAs is recognized by YTHDC1 and degraded through the NEXT complex (Liu et al. Reference Liu, Dou and Chen2020). The m6A modification serves as a switch that affects the abundance of these carRNAs, thereby regulating the chromatin status and downstream transcription nearby. In addition, the absence of m6A leads to the enrichment of certain TFs and an increase in active histone markers, inducing transcriptional activation and an increase in chromatin accessibility (Liu et al. Reference Liu, Dou and Chen2020).

The presence of RNA m6A modification has been demonstrated to sustain cellular self-recognition of endogenous RNA, while its absence can lead to the generation of aberrant endogenous double-stranded RNA in hematopoietic stem cells (HSCs) and progenitor cells, triggering robust innate immune responses and necrosis within the hematopoietic system (Gao et al. Reference Gao, Vasic and Song2020b). The myeloid cell-specific RNA m6A modification promotes differentiation of monocytes into macrophages and granulocytes (Yu et al. Reference Yu, Hu and Chen2021), enhancing their capacity to combat pathogen invasion (Tong et al. Reference Tong, Wang and Liu2021). Deletion of METTL14 in macrophages impairs the functionality of CD8+ T cells (Dong et al. Reference Dong, Chen and Zhang2021). In the latter part of this review, we will delve deeper into how RNA m6A modification regulates the differentiation and plasticity of IICs.

Noncoding RNA

Over 70% of the genetic sequences can be transcribed into RNA, yet only 2% are protein-coding sequences (Carninci et al. Reference Carninci, Kasukawa and Katayama2005; Djebali et al. Reference Djebali, Davis and Merkel2012). ncRNAs are categorized into small miRNAs and long lncRNAs based on their length (Fig. 1). miRNAs primarily function as posttranscriptional inhibitors, estimated to regulate over 60% of protein-coding genes. The seed region of miRNA (2–8 nt of the 5ʹ end) guides the RNA-induced silencing complex to degrade or inhibit mRNA translation in the ribosome by complementarily binding to the target gene’s mRNA (Bartel Reference Bartel2009) (Fig. 1). Notably, miRNAs can bind and regulate multiple target genes, modulate various components of the same signaling pathways, and facilitate rapid responses during infections and immune reactions (Chen et al. Reference Chen, Yang and Wei2020). XIST, one lncRNA that drives X chromosome inactivation, was first discovered in 1991 (Brown et al. Reference Brown, Ballabio and Rupert1991). With the advancement of sequencing technologies, comprehensive lncRNA profiles in different diseases and cell types have been established, revealing hundreds of disease-regulating lncRNAs. While these lncRNAs have diverse transcription sites, their functions and mechanisms remain similar (Fig. 1). For instance, numerous lncRNAs suppress RNA polymerase II or mediate chromatin remodeling and histone modifications, thus influencing downstream gene expression (Chen et al. Reference Chen, Yang and Wei2020; Han and Chang Reference Han and Chang2015). Some lncRNAs form RNA-protein complexes with TFs, altering their structure and activity upon binding, thereby regulating gene expression (Li et al. Reference Li, Wu and Fu2014a). Additionally, lncRNA’s self-transcription can interfere with the transcription of neighboring protein-coding genes. Upstream lncRNAs, during transcription, can selectively relocate to the promoter or enhancer regions of nearby genes, occupying the binding sites for TFs and inhibiting gene transcription (Chen et al. Reference Chen, Dragomir and Yang2022; Ferrè et al. Reference Ferrè, Colantoni and Helmer-Citterich2016; Statello et al. Reference Statello, Guo and Chen2021). LncRNAs also modulate mRNA expression in various disease microenvironments (Chen et al. Reference Chen, Satpathy and Chang2017b; Zhang and Cao Reference Zhang and Cao2016). However, only a limited number of lncRNAs are involved in regulating infections and immune responses (Castellanos-Rubio et al. Reference Castellanos-Rubio, Fernandez-Jimenez and Kratchmarov2016; Gomez et al. Reference Gomez, Wapinski and Yang2013; Ranzani et al. Reference Ranzani, Rossetti and Panzeri2015). Recent research highlights the indispensable role of lncRNAs in controlling immune cell activation (Atianand et al. Reference Atianand, Hu and Satpathy2016; Wang et al. Reference Wang, Xue and Han2014a). A series of lncRNAs such as lincRNA-Cox-2 (Carpenter et al. Reference Carpenter, Aiello and Atianand2013), lincRNA-PACER (Krawczyk and Emerson Reference Krawczyk and Emerson2014), lincRNA-THRIL (Li et al. Reference Li, Chao and Chang2014b), lnc-13 (Castellanos-Rubio et al. Reference Castellanos-Rubio, Fernandez-Jimenez and Kratchmarov2016), lincRNA-EPS (Atianand et al. Reference Atianand, Hu and Satpathy2016), lncRNA-ACOD1 (Wang et al. Reference Wang, Xu and Wang2017), lncRNA-Mirt2 (Du et al. Reference Du, Yuan and Tan2017), and linc-AAM (Chen et al. Reference Chen, He and Zhu2021b) have been reported to regulate macrophage development or activation.

Epigenetic modifications orchestrate phenotypes of IICs

Epigenetic modifications regulate lineage development and polarization of macrophages

The role of epigenetic modification in lineage development of macrophages

Macrophages serve as the first line of defense against invading pathogens and are pivotal in immune responses. They participate in tissue homeostasis, either facilitating or resolving inflammation that can lead to tissue damage or contribute to tissue repair. Saeed et al. investigated the epigenetic modifications and transcriptional dynamics during the monocyte-to-macrophage differentiation (Saeed et al. Reference Saeed, Quintin and Kerstens2014) and found that the epigenetic alterations during this process primarily occurred at promoters and distal regulatory elements. Among these, 1240 promoters showed decreased H3K27 acetylation while 1307 promoters exhibited increased H3K27 acetylation (Saeed et al. Reference Saeed, Quintin and Kerstens2014). This finding suggests a nearly equal number of opened or closed promoter modifications during the monocyte-to-macrophage differentiation process. Further analysis revealed a positive correlation between the existence of H3K27ac elements and the transcriptional activity of adjacent genes (Saeed et al. Reference Saeed, Quintin and Kerstens2014). Additionally, H3K4me1 was found to provide epigenetic memory during this process (Saeed et al. Reference Saeed, Quintin and Kerstens2014). These findings suggest a positive correlation between histone H3 modifications (H3K4me3/H3K27ac) at promoters and enhancers’ distal regulatory elements (H3K4me1/H3K27ac) during monocyte-to-macrophage differentiation (Fig. 2A). Similarly, Dekkers et al. investigated the genome-wide DNA methylation changes during the differentiation of monocytes into macrophages (Dekkers et al. Reference Dekkers, Neele and Jukema2019). They found that during the differentiation process, there were 4283 upregulated differentially methylated CpGs (DMCs) and 1493 downregulated DMCs. Interestingly, these DNA methylation changes were highly localized, typically affecting individual CpGs that are predominantly within enhancer regions bound by specific TFs (H3K4me1) and in active enhancer regions (H3K4me1/H3K27ac) (Fig. 2B). However, this study did not provide sufficient evidence to establish DNA methylation changes as the direct cause driving monocyte differentiation into macrophages. The observed DNA methylation changes might result from downstream impacts of histone modifications or TF binding (Bonder et al. Reference Bonder, Luijk and Zhernakova2017; de la Rica et al. Reference de la Rica, Rodríguez-Ubreva and García2013). Furthermore, occupancy of TF binding sites by TFs inhibits local DNA methylation or vice versa. In addition, Rodríguez et al. observed epigenetic dynamic changes during the differentiation of pre-B cells into macrophages (Rodríguez-Ubreva et al. Reference Rodríguez-Ubreva, Ciudad and Gómez-Cabrero2012) (Fig. 2C). Despite distinct DNA methylation states before and after differentiation were observed, crucial differentiation genes did not exhibit significant changes in DNA methylation. However, C/EBPα was discovered to induce histone modifications in genes associated with macrophage differentiation, by means of binding to highly methylated promoters of macrophage-specific genes and recruiting p300, a transcriptional co-activator and acetyltransferase. This action activated macrophage-specific gene expression, thereby regulating the differentiation of pre-B cells into macrophages (Rodríguez-Ubreva et al. Reference Rodríguez-Ubreva, Ciudad and Gómez-Cabrero2012). This study emphasizes the role and mechanisms of epigenetic modifications in this reprogramming process, highlighting the importance of epigenetic reprogramming in regulating cell fate transitions.

Figure 2. The role of epigenetic modification in lineage development of macrophages. A. The role of H3K27ac and H3K4me3 in guiding monocyte-to-macrophage differentiation. B. Increased DNA methylation during monocyte-to-macrophage differentiation promotes the binding of TFs and active histone elements to relevant differentiation genes. C. Epigenetic patterns during pre-B cell-to-macrophage differentiation. D. Epigenetic characteristics and mechanisms underlying the differentiation of newly settled hepatic macrophages.

A report by Sakai focused on the transcriptomic and epigenetic features of newly settled liver macrophages, contributing valuable insights into the mechanisms through which precursor cells develop tissue-specific phenotypes (Sakai et al. Reference Sakai, Troutman and Seidman2019). By characterizing the transcriptomic and epigenetic alterations of macrophages resettled in the liver post-acute Kupffer cells (KCs) (liver resident macrophage) depletion, they proposed insights into signaling pathways and TFs that promote KCs differentiation. Post-depletion of KCs, recruited monocytes rapidly differentiated into KCs, and the liver environment reprogrammed the enhancer landscape of the recruited monocytes (Fig. 2D). Newly differentiated liver macrophages assumed more accessible chromatin, similar to the observed pattern in KCs. Mechanistic studies revealed that DLL4 activation in sinusoidal endothelial cells triggers the Notch signaling pathway in circulating monocytes. This, in turn, stimulates the expression of KC-specific genes and suppresses the activity of monocyte-specific TFs, thereby giving rise to repopulating liver macrophages (RLMs) (Fig. 2D). Subsequently, the Notch signaling pathway and TGF-β further activate RLMs at KC-specific gene H3K27ac enhancers, inducing the expression of genes that promote differentiation toward KCs, ultimately leading to the formation of KCs.

Taken together, these findings collectively suggest that ecological signals under physiological and pathological environments have the capability to induce specific differentiation or phenotypic transitions in tissue-resident macrophages, precursor cells, and monocytes by reconfiguring their epigenomes.

The role of epigenetic modification in macrophages polarization

Macrophages exhibit remarkable heterogeneity and plasticity, with their phenotype and function regulated by the surrounding environment, a process referred to as macrophage polarization (Ginhoux and Jung Reference Ginhoux and Jung2014; Sica and Mantovani Reference Sica and Mantovani2012). Typically, macrophages sense and engulf the host, presenting fragmented peptides to helper T cells (Th) when pathogens invade the host. Simultaneously, macrophages release pro-inflammatory cytokines and chemokines to eradicate the pathogens, while simultaneously secreting anti-inflammatory cytokines and chemokines to protect the organism. Two discernible polarization states are observed in macrophages: M1, which releases pro-inflammatory cytokines, represents the classically activated macrophages, while M2, releasing anti-inflammatory cytokines, represents alternatively activated macrophages (Gordon and Taylor Reference Gordon and Taylor2005; Patel et al. Reference Patel, Rajasingh and Samanta2017; Steinman and Idoyaga Reference Steinman and Idoyaga2010). Upon exposure to pathogenic inflammatory stimuli, gene transcription in macrophages undergoes significant changes, leading to the activation of macrophages (Fig. 3). Activation enables them to respond to infection and stimuli more effectively, thus establishing immune homeostasis. However, if the transcriptional pattern activated by inflammation persists, macrophages can become excessively activated, thereby compromising host health (Fu et al. Reference Fu, Zong and Jin2023). Substantial evidence suggests macrophage polarization is a reversible and adjustable dynamic process that participates in numerous immune-inflammatory diseases’ onset, progression, and outcomes. Consequently, macrophages have emerged as attractive therapeutic targets and research focal points in recent years. The “reprogramming” of macrophage states represents a promising new therapeutic strategy.

Figure 3. Epigenetic modifications and macrophage polarization. Notes: DNMT1- and DNMT3b-mediated DNA methylation favors M1 macrophage polarization, whereas DNMTS inhibitors-induced DNA demethylation typically promotes M2 macrophage polarization. HDAC3-mediated histone deacetylation commonly enhances M1 macrophage polarization, whereas HDAC1 and HDAC10-mediated histone deacetylation typically favors M2 macrophage polarization. SETDB1-mediated H3K9 methylation and KDM5B-mediated H3K4 methylation often promote M1 macrophage polarization, while JMJD3 and KDM6A-mediated H3K27 demethylation typically favors M2 macrophage polarization. METTL3/METTL14 and YTHDF1-mediated RNA m6A modification contributes to M1 macrophage polarization. Lnc-AAM, LncRNA-GAS5, and LncRNA-CCL2 enhance M1 macrophage polarization, while LncRNA-Dnmt3aos, LncRNA-AK085865, and LncRNA-NEAT1 promote M2 macrophage polarization.

DNA methylation modulates macrophage polarization

DNA methylation has been demonstrated to modulate gene transcription in macrophages in responding to the pathogenic mechanisms of various diseases including inflammation (McErlean et al. Reference McErlean, Bell and Hewitt2021). Jain et al. found that during Lipopolysaccharides (LPS)-induced polarization of macrophages toward the M1 phenotype, there was an overall decrease in 5mC levels, along with an increase of non-methylated CpG sites, suggesting a notable reduction in DNA methylation associated with macrophage M1 polarization (Jain et al. Reference Jain, Shahal and Gabrieli2019). DNMT3a-mediated Pstpip2 methylation enhances macrophage activation and inflammation in liver injury by modulating the STAT1 and nuclear factor kappa B (NF-κB) pathways (Xu et al. Reference Xu, Zhu and Li2022a). Additionally, studies indicate that DNMT3b also regulates macrophage polarization and inflammation. Elevated levels of DNMT3b, associated with pro-inflammatory M1 macrophages, were observed in obese mice; knocking out DNMT3b promoted macrophage polarization toward an alternative M2 state (Yang et al. Reference Yang, Wang and Liu2014). The methylation of the tumor necrosis factor (TNF)-α gene, mediated by Uhrf1, controls pro-inflammatory macrophage polarization in experimental colitis models, resembling inflammatory bowel disease (Qi et al. Reference Qi, Li and Dai2019). Promoting macrophage M2 polarization can be facilitated by inhibiting DNA methylation at the peroxisome proliferator-activated receptor γ1 (PPARγ1)promoter using 5-azacytidine (DNMT inhibitor) or through DNMT1 deficiency (Wang et al. Reference Wang, Cao and Yu2016; Yu et al. Reference Yu, Qiu and Yang2016). These instances provide explicit evidence that inhibiting DNMTs can facilitate the transcriptional activation of M2 macrophage-associated genes. Inhibitors targeting DNMTs may enhance anti-inflammatory responses, thus alleviating damage.

Histone modification regulates macrophage polarization

Epigenetic modifiers such as histone methyltransferases and acetyltransferases exhibit differential expression in macrophage M1/M2 states, suggesting they play a role in maintaining and regulating macrophage M1/M2 polarization (Zhou et al. Reference Zhou, Yang and Chen2017). For instance, HDAC10 is upregulated in macrophages and the upregulation promotes activation of mouse M2 macrophages (Zhong et al. Reference Zhong, Huang and Huang2023). Inhibiting HDAC6 and HDAC8 suppresses macrophage M2 polarization (Li et al. Reference Li, Su and Ren2020a; Shi et al. Reference Shi, Li and Chen2022; Zhou et al. Reference Zhou, Chen and Shi2023). Moreover, inhibition of HDAC6 and HDAC3 substantially suppresses LPS-induced macrophage M1 polarization and reduces pro-inflammatory cytokine production (Yan et al. Reference Yan, Xie and Liu2014). Epigenetic regulation by H3K4 and H3K27 methylation influences M2 macrophage polarization genes. For instance, the STAT6-dependent induction of JMJD3, an H3K27 demethylase, reduces H3K27 methylation in the promoter regions of genes associated with M2 macrophage polarization, thus maintaining their transcriptional activity (Ishii et al. Reference Ishii, Wen and Corsa2009). Histone H3K27 demethylase KDM6A-dependent demethylation regulates Ire1α expression, which enhances M2 macrophage polarization (Chen et al. Reference Chen, Xu and Li2021a). Histone demethylase JMJD1C upregulates miR-302a to promote M1 macrophage polarization (Zhong et al. Reference Zhong, Tao and Yang2021). Knockout of Setdb1, a macrophage-specific H3K9 methyltransferase, in mice upregulated interleukin-6 (IL-6) levels upon LPS stimulation and increased its susceptibility to endotoxic shock, indicating that H3K9 methyltransferase SETBD1 is an epigenetic regulator of pro-inflammatory cytokine expression (Hachiya et al. Reference Hachiya, Shiihashi and Shirakawa2016). Genome-wide analysis of KDM5B binding peaks revealed its selective recruitment to the Nfkbia gene promoter, associated with activated macrophages. KDM5B-mediated erasure of H3K4me3 reduces chromatin accessibility at the Nfkbia gene locus, resulting in reduced IκBα expression and augmented macrophage activation mediated by NF-κB pathway (Zhang et al. Reference Zhang, Gao and Jiang2023a). Additionally, ornithine decarboxylase deficiency during bacterial infection mitigates H3K9 methylation to enhance M1 macrophage polarization (Hardbower et al. Reference Hardbower, Asim and Luis2017).

During LPS-induced M1 macrophage polarization, HDAC3 interacts with activating TF to facilitate transcriptional activation in an enzymatic-independent manner (Nguyen et al. Reference Nguyen, Adlanmerini and Hauck2020). This suggests HDAC3 not only regulates chromatin activity through histone deacetylation but also modulates gene transcription through interacting with key macrophage TFs. Arginine methyltransferase 1 (PRMT1) regulates c-Myc-dependent transcription by altering acetyltransferase p300 recruitment to its promoter. PRMT1 inhibition decreases p300 recruitment to c-Myc target promoters and increases HDAC1 recruitment, thereby reducing transcription at these sites. Inhibiting PRMT1 disrupts induction of several c-Myc-mediated target genes, including PPARG and MRC1, highlighting the necessity of PRMT1 in c-Myc function during M2 macrophage differentiation (Tikhanovich et al. Reference Tikhanovich, Zhao and Bridges2017). These data indicate that various chromatin-modifying factors may interact with same TFs to regulate distinct gene subgroups. In conclusion, the relationship between histone modifications and macrophage polarization is crucial for understanding macrophages’ heterogeneity and functional transition.

RNA m6A methylation regulates macrophage polarization

In the past 5 years, extensive evidence confirmed that RNA methylation plays a crucial role in transcription initiation, regulation of nascent RNA transcription and chromatin-associated RNA m6A methylation, consequently regulating chromatin openness and activity during the development and differentiation of embryonic HSCs. However, the specific impact of RNA methylation in monocyte-to-macrophage differentiation and M0 to M1/M2 polarization remains unclear. Through transcriptomic analysis of nascent RNA, m6A methylation profiling, and chromatin accessibility sequencing, we found that METTL3 regulates m6A modification and transcription of nascent RNA and chromatin-enriched noncoding RNAs (caRNAs) during macrophages polarization from M0 to M1 polarization. The loss of METTL3 significantly reverses the expression of nearly 40% of genes involved in M0 to M1 polarization, including the NF-κB and Janus kinase/signal transducer and activator of transcription (JAK/STAT) signaling pathways. This suggests that RNA m6A methylation modulates the global dynamic transcription and chromatin accessibility during the macrophage transition from M0 to M1, thereby imparting plasticity to macrophages (unpublished data).

In addition, extensive research highlighted the impact of RNA m6A methylation on the stability and translation efficiency of mRNAs that are related to macrophage polarization, thereby mediating the activation of crucial pathways involved in this process. For instance, Qin and colleagues revealed that conditional METTL3 knockout in myeloid cells inhibits liver macrophage as well as T-cell differentiation. This can be attributed to the absence of METTL3 in macrophages, which leads to low levels of Ddit4 mRNA m6A modification and enhanced stability. Ddit4 subsequently suppresses mTOR and NF-κB signaling pathways mediating macrophage activation and inflammatory responses (Qin et al. Reference Qin, Li and Arumugam2021b). Moreover, Tong et al. established a CRISPR screening system to induce M1 polarization in LPS-stimulated macrophages, revealing METTL3 as a critical factor in macrophage activation based on differential TNF-α expression. Mechanistically, METTL3 promotes Irakm mRNA m6A modification and its degradation, leading to Irakm-toll-like receptor (TLR) signaling activation and macrophage M1 polarization (Tong et al. Reference Tong, Wang and Liu2021). Furthermore, research elucidated that METTL3 directly methylates STAT1 mRNA, thus enhancing its stability and STAT1 expression. STAT1 next binds to the promoters of pro-inflammatory genes to promote polarization toward M1 and inhibit M0 to M2 polarization (Li et al. Reference Li, Xu and Huangfu2022b; Liu et al. Reference Liu, Liu and Tang2019c). The METTL3-driven m6A function also stimulates the development of miR-34a-5p which, by interacting with Sirt1 mRNA in KCs to suppress its translation, affects the transcription and translation of certain genes associated with M1 polarization (Pan et al. Reference Pan, Li and Wang2023). Additionally, Han and colleagues demonstrated that the knockout of METTL3 in myeloid cells intensifies Th2 cell responses and exacerbates allergic airway inflammation by activating M2 macrophage. Mechanistically, METTL3 facilitates m6A modification of PTX3 mRNA to promote its YTHDF3-dependent degradation, resulting in reduced PTX3 levels. The decreased PTX3 suppresses macrophage M2 polarization, thereby promoting allergic airway inflammation (Han et al. Reference Han, Liu and Huang2023). These studies collectively emphasize the contribution of METTL3 to promoting macrophage transition from M0 to M1.

Similar to METTL3, METTL14 was also found to facilitate M0 to M1 polarization while inhibiting M0 to M2 polarization. For example, Zheng and colleagues found that METTL14, through m6A modification, enhances Myd88 mRNA stability, consequently promoting Myd88-p65 axis-mediated IL-6 transcription (Zheng et al. Reference Zheng, Li and Ran2022). This process facilitates macrophage M0 to M1 polarization while suppressing M2 polarization, thus promoting foam cell formation and enhancing migration (Zheng et al. Reference Zheng, Li and Ran2022). Additionally, research has indicated that METTL14, through the KAT3B-STING axis, regulates M1 polarization and triggers NLRP3 inflammasome activation in macrophages postischemic stroke (Li et al. Reference Li, Li and Yu2023). Conversely, Wang et al. found a negative regulation of macrophage M1 polarization by METTL14. They observed that LPS-induced KAT2B-mediated acetylation of METTL14 at the K398 site enhances the stability of METTL14 protein, which next promotes m6A modification of Spi2a mRNA via the YTHDF1 axis. Elevated SPI2A binds to IKKβ to inhibit NF-κB pathway, thus inhibiting macrophage M1 polarization (Wang et al. Reference Wang, Ding and Li2023). Similarly, Du et al. identified METTL14-mediated m6A modification on Socs1 mRNA enhances YTHDF1 translation, which eventually inhibits TLR4/NF-κB signal transduction and macrophage M1 polarization (Du et al. Reference Du, Liao and Liu2020). Reintroducing SOCS1 in METTL14 or YTHDF1-deficient macrophages rescued their heightened inflammatory phenotype (Du et al. Reference Du, Liao and Liu2020). Moreover, conditional loss of METTL14 in myeloid cells exacerbated macrophages’ reaction to acute bacterial infection in mice, resulting in higher mortality rates (Du et al. Reference Du, Liao and Liu2020). These findings indicate that m6A-mediated expression of Socs1 maintains a negative feedback loop that regulates macrophage activation during bacterial infections.

The RNA demethylase FTO has been discovered to promote both M1 and M2 polarization. This occurs through selective removal of m6A modifications from Stat1 and Ppar-γ mRNA, thus inhibiting YTHDF2-mediated degradation of Stat1 and Ppar-γ mRNA and hindering macrophage activation (Gu et al. Reference Gu, Zhang and Li2020). Additionally, the RNA demethylase ALKBH5 diminishes the m6A modification on Cdca4 mRNA which leads to the reduced binding of YTHDC2 to its m6A site to inhibit YTHDC2-mediated degradation. The elevated CDCA4 promotes macrophage M2 polarization (Tan et al. Reference Tan, Chen and Wang2024). It has also been reported that the absence of YTHDF2 in macrophages suppresses macrophage M2 polarization by m6A-mediated degradation of Hmox1 mRNA. The lower level of HMOX1 facilitates the release of inflammatory factors (Hu et al. Reference Hu, Yu and Shen2023). Furthermore, Huangfu et al. discovered the interaction between RBM4 and YTHDF2, which leads to the degradation of m6A-modified Stat1 mRNA and subsequently regulates interferon (IFN)-γ-induced M1 polarization (Huangfu et al. Reference Huangfu, Zheng and Xu2020).

The cumulative findings emphasize the crucial role of RNA m6A in the development and polarization of macrophage lineages. It is evident that an increase in METTL3 or METTL14-mediated RNA m6A methylation is recognized by YTHDF1 or YTHDF2, which subsequently promotes M1 macrophage polarization. Conversely, RNA m6A demethylation mediated by FTO or ALKBH5 typically favors M2 macrophage polarization. Therefore, unraveling the underlying molecular mechanisms and identifying key regulatory elements or genes mediated by m6A modifications will aid in designing and developing small molecule inhibitors or activators targeting RNA m6A methylation enzymes or critical genes’ m6A modifications involved in the development and polarization of macrophage lineages, ultimately providing potential therapies for mitigating inflammation resulting from macrophage polarization.

Regulation of macrophage polarization by ncRNAs

lncRNAs play a pivotal role in the specific regulation of macrophage polarization through various mechanisms, mediating the onset and progression of various diseases. Ma et al. reported altered expression of snRNAs during macrophage polarization, showing differences in the expression of hundreds of ncRNAs during M1 polarization of macrophages (Ma et al. Reference Ma, Zhou and Wang2022). The roles and mechanisms of some ncRNAs in regulating macrophage polarization have been elucidated. For instance, linc-AAM is induced early in macrophage activation, and its subsequent upregulation promotes the transcription of a series of immune response genes (IRGs), further fostering macrophage activation (Chen et al. Reference Chen, He and Zhu2021b). linc-AAM can selectively recognize the promoter sequences of IRGs. Simultaneously, the linc-AAM sequence encompasses two CACACA motifs recognized by heterogeneous nuclear ribonucleoprotein L (hnRNPL). Once interaction occurs between the two, it leads to the dissociation of hnRNPL from the hnRNPL-H3 complex, thus fostering chromatin accessibility and promoting IRG transcription (Chen et al. Reference Chen, He and Zhu2021b). It is noteworthy that the knockout of linc-AAM in mice exhibited compromised antigen-specific cellular and humoral immune responses (Chen et al. Reference Chen, He and Zhu2021b), suggesting that linc-AAM-mediated macrophage activation supports the establishment of adaptive immunity. LncRNA-GAS5 overexpression in vitro upregulates STAT1, promoting macrophage polarization toward the M1 phenotype (Hu et al. Reference Hu, Zhang and Liechty2020). LncRNA-MM2P inhibits M1-polarized macrophages’ excessive inflammation by interfering with SHP2-mediated STAT3 dephosphorylation (Peng et al. Reference Peng, Biao and Zhao2023). LncRNA-CCL2 regulates the expression of inflammatory cytokines in macrophages during sepsis (Jia et al. Reference Jia, Li and Cai2018). Li et al. discovered numerous lncRNAs with differential expression in macrophages before and after polarization, among which lncRNA-Dnmt3aos is positioned on the antisense strand of Dnmt3a. Functional experiments further confirm that lncRNA-Dnmt3aos promotes M2 macrophage polarization by regulating downstream Dnmt3a gene expression (Li et al. Reference Li, Zhang and Pei2020b). LncRNA-AK085865 is markedly expressed in allergic asthma mice and drives macrophage polarization toward M2; its depletion reduces M2 macrophage polarization, suggesting that silencing lncRNA-AK085865 could ameliorate allergic asthma airway inflammation by modulating macrophage polarization (Pei et al. Reference Pei, Zhang and Li2020). LncRNA-NEAT1 enhances B7-H3 expression and JAK2-STAT3 signaling activation by downregulating miR-214, promoting M2 macrophage polarization (Gao et al. Reference Gao, Fang and Li2020a). Additionally, miR-30b-5p releases HMGB1 through the UBE2D2/KAT2B/HMGB1 pathway, promoting pro-inflammatory polarization and macrophage recruitment (Qi et al. Reference Qi, Wang and Xia2021).

Epigenetic modifications modulate differentiation and maturation of DCs

In the bone marrow, HSCs generate multipotent progenitors (MPPs), which can further differentiate into common myeloid progenitors (CMPs) and common lymphoid progenitors. CMPs expressing Flt3 differentiate into macrophage-dendritic cell progenitors (MDPs) (Belz and Nutt Reference Belz and Nutt2012; Boe et al. Reference Boe, Hulsebus and Najarro2022; Roquilly et al. Reference Roquilly, Mintern and Villadangos2022). Common DC progenitors (CDPs) derived from MDPs can differentiate into conventional dendritic cell precursors (pre-cDCs) and plasmacytoid DC precursors (pre-pDCs) (Belz and Nutt Reference Belz and Nutt2012; Paul and Amit Reference Paul and Amit2014). Pre-cDCs move from the bone marrow into the bloodstream and migrate to lymphoid and non-lymphoid organs, differentiating into cDCs. As MPPs differentiate into CDPs, the genetic profile for classical DCs (cDCs) and plasmacytoid DCs (pDCs) undergoes epigenetic activation and loss of inhibitory histone marks (Lin et al. Reference Lin, Chauvistré and Costa2015). The process from HSCs differentiation to mature DCs (mDCs) encompasses several intermediate stages, with each stage gradually limiting their developmental and differentiation potential. This suggests that gene expression patterns encounter increasing constraints during lineage cell differentiation. However, existing research indicates that epigenetics participates in reshaping chromatin structure, thereby influencing the transition of gene expression patterns during lineage cell differentiation (Boukhaled et al. Reference Boukhaled, Corrado and Guak2019).

Epigenetic modification influences the differentiation and maturation of DCs by regulating the expression and function of key TFs

Vento et al. compared the DNA methylation dynamics in the differentiation process of monocytes into DCs and macrophages, identifying distinct gene sets experiencing DC-specific or macrophage-specific demethylation. Their findings indicated the role of IL-4 in coordinating STAT6-mediated DNA demethylation, crucial for monocyte differentiation into DCs (Vento-Tormo et al. Reference Vento-Tormo, Company and Rodríguez-Ubreva2016). Pu.1, as a TF, holds a pivotal role in hematopoiesis and exhibits continuous expression along the lineage of DCs. Loss of the histone deubiquitinase MYSM1 impairs DCs development without affecting other myeloid cell lineages, including monocytes, macrophages, and granulocytes. Mechanistic studies revealed that MYSM1 regulates Flt3 transcription by controlling histone modifications and Pu.1 recruitment, thereby controlling the differentiation of DCs and CMPs (Won et al. Reference Won, Nandakumar and Yates2014). To unravel the functional roles of lncRNAs in human DCs, Wang et al. employed lncRNA gene chip analysis to examine the expression profile of lncRNAs in monocyte-derived DCs and LPS-induced mDCs from peripheral blood. They discovered the significantly elevated expression of linc-DC (>100-fold) specifically in mDCs. Mechanistic insights revealed that during the maturation of DCs, the genomic regions of linc-DC gradually acquired an open and accessible chromatin structure favoring H3K4me3 and H3K27ac levels, thereby facilitating the binding of the TF PU.1, ultimately resulting in the production of linc-DC in mDCs. The transcribed linc-DC directly binds to the structural region near the phosphorylation site Tyr705 of STAT3, inhibiting SHP1-mediated dephosphorylation and enhancing STAT3 signaling, thereby promoting DC maturation and maintaining DC functionality (Wang et al. Reference Wang, Xue and Han2014a). Pacis et al. comprehensively reported the DNA methylation profile of monocyte-derived DCs for the first time. They found extensive and rapid loss of DNA methylation during Mycobacterium tuberculosis infection in human DCs (Pacis et al. Reference Pacis, Tailleux and Morin2015), a process dependent on TET2 (Pacis et al. Reference Pacis, Tailleux and Morin2015; Vento-Tormo et al. Reference Vento-Tormo, Company and Rodríguez-Ubreva2016). However, the understanding of how DNA methylation regulates the development from CMPs to DCs and the DNA methylation patterns during the gradual differentiation of DCs from HSCs remains limited. Nevertheless, studies have indicated that Pu.1 can recruit TET2 and DNMT3b to target genes, as observed during osteoclast differentiation from monocytes (de la Rica et al. Reference de la Rica, Rodríguez-Ubreva and García2013). Based on this, it can be speculated that in the development of DCs, Pu.1 might interact with TET and DNMT, inducing DNA methylation of certain regulatory differentiation genes. These interactions can then lead to the recruitment of chromatin-modifying factors, including histone modifiers, to regulate the chromatin state at these genes. This regulation of the chromatin state ultimately affects the transcription of the differentiation genes, promoting their activation or silencing, which is crucial for the proper development and differentiation of DCs.

Irf8 serves as a decisive factor in the development of the DC lineage. It initiates the differentiation of HST and MPP into DCs, and its deficiency inhibits the transition of MDP into CDP (Becker et al. Reference Becker, Michael and Satpathy2012; Chauvistré and Seré Reference Chauvistré and Seré2020; Kurotaki et al. Reference Kurotaki, Kawase and Sasaki2019; Lee et al. Reference Lee, Zhou and Ma2017). Xu et al. identified a novel lncRNA termed lncIrf8, which is transcribed from the downstream +32 kb enhancer of the Irf8 locus and exhibits specific expression in pDCs, while it remains unexpressed in MPPs, CDPs, cDC1s, and cDC2s. lncIrf8 binds to the Irf8 promoter and demonstrates distinct epigenetic characteristics in pDCs compared to cDC1s. Elimination of the lncIrf8 promoter impairs the development of both pDCs and cDC1s, while leaving cDC2s unaffected. However, activating the lncIrf8 promoter notably enhances cDC1s development. In cDC1s, the +32 kb enhancer negatively regulates the interferon regulatory factor 8 (IRF8)-repressive protein complex, thereby restricting the auto-activation and expression of Irf8. Conversely, in pDCs, there is relatively less binding between the IRF8-repressive protein complex and the +32 kb enhancer, resulting in heightened transcription of Irf8 and lncIrf8 (Xu et al. Reference Xu, Li and Kuo2023).

Histone modification modulates differentiation and maturation of DCs

In recent years, scientists have gradually unraveled the roles of various epigenetic modifier enzymes in DC lineage development and activation by generating mice or cells with specific deletions in distinct epigenetic modifications (Søndergaard et al. Reference Søndergaard, Poghosyan and Hontelez2015). For example, Zhang and colleagues discovered the heightened level of HDAC3 in pDCs, and its deficiency significantly impairs pDC development. Mechanistically, the lack of HDAC3 results in a considerable decline in the gene transcriptions related to pDC differentiation, while genes linked to cDC differentiation are notably upregulated, consequently leading to a significant reduction in CDP’s ability to differentiate into pDCs. This is due to the significant increase in H3K27ac, mediated by HDAC3 knockout, at critical genes for pDC differentiation such as Zfp366, Zbtb46, and Batf3, thereby regulating gene expression levels and the development and differentiation of the DC lineage (Zhang et al. Reference Zhang, Wu and He2023b). Moreover, during monocyte-to-DC differentiation, HDAC4 recruitment to the Arg1 promoter region is enhanced, leading to reduced H3 and STAT6 acetylation. This reduction promotes STAT6 binding to the Arg1 promoter and activation of Arg1 transcription, further enhancing the expression of Arg1 and facilitating DC differentiation (Yang et al. Reference Yang, Wei and Zhong2015). PCGF6 serves as a member of the Polycomb group involved in epigenetic regulation. PCGF6 expression is observed in resting-state DCs and is downregulated following DC activation. Furthermore, HDACs mediate STAT3 deacetylation, also contributing to monocyte-to-DC differentiation (Sun et al. Reference Sun, Chin and Weisiger2009). Boukhaled et al. identified that PCGF6 interacts with the H3K4me3 demethylase JARID1c, jointly negatively regulating H3K4me3 modification in DCs, thereby impacting the chromatin accessibility of critical genes crucial for DC activation (Boukhaled et al. Reference Boukhaled, Cordeiro and Deblois2016). These findings suggest that HDACs and histone demethylases, among others, exert control over the fate transition of DCs by modulating chromatin modifications at key gene loci or modifying their TFs during DC maturation and differentiation.

RNA m6A methylation regulates differentiation and maturation of DCs

In recent years, research into the involvement of RNA m6A methylation in regulating DC development and activation has emerged. Yin et al. systematically profiled 16 different HSCs, progenitors, and mature blood cells in the murine hematopoietic system, including MPP, CMP, GMP, MDP, and DC. They observed a higher m6A modification level in long-term HSCs, which subsequently declined as they differentiated into myeloid and erythroid lineages, while the lymphoid cell population exhibited elevated RNA m6A modifications (Yin et al. Reference Yin, Chang and Li2022). This observation suggests that RNA m6A methylation negatively regulates the differentiation of HSCs into myeloid cells and DCs. However, during the maturation process within the DC lineage, Wang and colleagues discovered that METTL3-mediated m6A modifications on transcripts such as Cd40, Cd80, TlrR4, and Tirap enhanced their recognition by YTHDF1, promoting their translation in DCs. This facilitated DC maturation and activation, thereby strengthening cytokine production induced by TLR4/NF-κB signaling (Wang et al. Reference Wang, Hu and Huang2019). This indicates a positive regulatory impact of RNA m6A methylation in the maturation and activation of DCs. Further research by Bai et al. revealed that the loss of the RNA m6A reader protein YTHDF1 led to heightened recruitment of mDCs, elevated MHCII, as well as enhanced secretion of IL-12 (Bai et al. Reference Bai, Wong and Pan2022). Consequently, this promoted infiltration of CD4+ and CD8+ T cells, boosting IFN-γ secretion, and thereby contributing to alleviating disease. Thus, RNA m6A methylation plays a role in modulating DCs during immune responses.

ncRNA modulates differentiation and maturation of DCs

In addition to the aforementioned lncIrf8 and lnc-dc, numerous LncRNAs also participate in regulating the differentiation and maturation of DCs. For instance, LncRNA-MIR155HG can modulate the immune function of DCs by impacting HSC differentiation (Niu et al. Reference Niu, Lou and Sun2020). Moreover, LncRNA-HOTAIRM1 inhibits monocytic differentiation into DCs by targeting the miR-3960/HOXA1 pathway (Xin et al. Reference Xin, Li and Feng2017). HOXA1 serves as a differentiation inhibitory molecule for DCs. The interaction between LncRNA-HOTAIRM1 and miR-3960 promotes HOXA1 expression, leading to the upregulation of monocytic markers CD14 and B7H2, ultimately maintaining the monocytic phenotype and suppressing their differentiation into DCs. Thus, LncRNA-HOTAIRM1, miR-3960, and HOXA1 form a competitive endogenous RNA network, exerting regulatory roles during DC lineage development (Xin et al. Reference Xin, Li and Feng2017). The migration of leukocytes is controlled by interactions between chemokines and their receptors, determining the characteristics and consequences of immune responses driven by DCs (Ardouin et al. Reference Ardouin, Luche and Chelbi2016; Dress et al. Reference Dress, Wong and Ginhoux2018; Worbs et al. Reference Worbs, Hammerschmidt and Förster2017). pDCs mature in response to microbial products or inflammatory signals, subsequently upregulating CCR7. CCL21 and CCL19 act as ligands for CCR7, regulating the drainage of DCs to lymph nodes to induce adaptive immunity (Förster et al. Reference Förster, Davalos-Misslitz and Rot2008; Ohl et al. Reference Ohl, Mohaupt and Czeloth2004; Ulvmar et al. Reference Ulvmar, Werth and Braun2014). Abnormal DCs transport and aggregation are associated with the pathogenesis of diverse inflammatory conditions (Han et al. Reference Han, Li and Zhou2015). Research indicates that the chemokine receptor CCR7 expressed by DCs negatively regulates DC migration by inhibiting m6A modifications on lnc-Dpf3 within DCs, leading to increased lnc-Dpf3 expression and thereby suppressing the occurrence and progression of inflammatory diseases (Liu et al. Reference Liu, Zhang and Chen2019a).

Discussion on the roles of epigenetic modifications on differentiation and maturation of DCs

The regulatory networks and mechanisms governing the plasticity of epigenetic control in the development and phenotypic characteristics of DC subsets have not been as clearly elucidated as in macrophage studies. Many questions remain unanswered in this regard. For instance, how signals from disease and the local microenvironment are transmitted to the epigenetic modifiers and chromatin during the differentiation phases of subsets like MPP, MDP, cDCs, or pDCs, especially during pathogen infections. Furthermore, how chromatin and epigenetic information reciprocally regulate their differentiation, migration, and activation in DCs. Another consideration is whether the differences in the epigenetic landscape of DCs directly reflect the phenotype, function, and activation status of DC subsets.

Epigenetic modifications modulate lineage development and activation of ILCs

In terms of function and development, ILCs resemble T cells but lack adaptive antigen receptors. ILCs primarily consist of ILC1s, ILC2s, ILC3s, and natural killer (NK) cells. Through the expression of various integrins, chemokine receptors, and cytokine receptors, ILCs rapidly sense environmental changes, enabling them to swiftly secrete potent cytokines to combat infections and tissue remodeling (Artis and Spits Reference Artis and Spits2015; Brubaker et al. Reference Brubaker, Bonham and Zanoni2015). The lineage development, differentiation, and maturation of ILCs are also regulated, which depends on specific TFs and epigenetic mechanisms, with the expression of particular TFs also relying on the involvement of multiple epigenetic modifications (Cong et al. Reference Cong, Zhang and Cao2021; Domínguez-Andrés et al. Reference Domínguez-Andrés, Dos Santos and Bekkering2023; Zhang and Cao Reference Zhang and Cao2021).

Epigenetic modifications regulate lineage development and activation of ILC1s, ILC2s, and ILC3s

Epigenetic modification influences lineage development and activation of ILC1s, ILC2s, and ILC3s by mediating the expression and function of key TFs

The ILCs lineage is determined by ID2, a TF that counters the specific gene transcription in T and B cells. Typically, the Id2 gene remains suppressed, awaiting future activation (Guo et al. Reference Guo, Liang and Zhang2015; Michieletto et al. Reference Michieletto, Tello-Cajiao and Mowel2023). Michieletto et al. conducted a comprehensive analysis of mature ILCs’ three-dimensional (3D) genome structure, chromatin accessibility, and gene expression, revealing the mechanism by which ILC2s specifically activate through dynamic reshaping of the Id2 gene locus’s 3D structure during early development (Michieletto et al. Reference Michieletto, Tello-Cajiao and Mowel2023). Their study found that the local 3D structure of the genome is selectively reconnected at sites relevant to ILCs function, facilitating the lineage development and functional differentiation of ILCs. Moreover, multiple interactions between Id2 gene locus and distal cis-regulatory elements bound by ILC2s-associated TFs GATA3 and RORαshape a unique local 3D structure, thereby promoting the development of ILC2s and allergic airway inflammation. Additionally, Mowel et al. discovered that lncRNA-Rroid in ILC1s interacts with the promoter sequence of the adjacent Id2. It is the gene locus of lncRNA-Rroid, rather than the molecule itself, that responds to IL-15 by enhancing chromatin accessibility and facilitating STAT5 deposition in the Id2 promoter, thereby governing the differentiation and function of ILC1s. Moreover, lncRNA-Rroid is also indispensable for the early development and homeostasis of ILC2s and ILC3s (Mowel et al. Reference Mowel, McCright and Kotzin2017).

ncRNA modulates the lineage development and activation of ILC1s, ILC2s, and ILC3s

Numerous ncRNAs participate in regulating ILCs lineage development. For instance, Liu et al. found high expression of lncRNA-Kdm2b expression in ILC3s. Lacking lncRNA-Kdm2b in the hematopoietic system results in reduced numbers and effector functions of ILC3s. This is because lncRNA-Kdm2b promotes the proliferation of ILC3s through activating the TF ZFP292, thereby sustaining ILC3s maintenance. Mechanistically, lncRNA-Kdm2b recruits some CRCs to the Zfp292 promoter to drive its transcription. The lack of ZFP292 disrupts ILC3 maintenance, increasing susceptibility to bacterial infections (Liu et al. Reference Liu, Ye and Yang2017). Furthermore, the circular RNA circTmem241 exhibits high expression in ILC3 and its progenitor cells (Liu et al. Reference Liu, He and Fan2022). Its depletion impairs the function of ILC3 and inhibits antibacterial immunity. Within ILC precursors (ILCPs), circTmem241 interacts with the NONO protein, recruiting the histone methyltransferase ASH1l to the Elk3 promoter. At the Elk3 promoter, ASH1l facilitates H3K4me3 and H3K36me3, thereby heightening chromatin accessibility and initiating Elk3 transcription. Conditional gene editing experiments in ILCPs mice indicated a substantial disruption in the differentiation capability of ILC3s and increased susceptibility to bacterial infections upon the loss of circTmem241, Nono, or Ash11. Conversely, overexpression of Elk3 in mice with ILCPs-specific deficiencies in circTmem241, Nono, or Ash1 defects restored the differentiation ability of ILC3s and enhanced their resistance to infections. This suggests that the circTmem241-Nono-Ash1l-Elk3 axis emerges as pivotal in steering ILCPs toward mature ILC3s, highlighting the axis’ critical regulatory potential in therapeutic strategies targeting infectious diseases (Liu et al. Reference Liu, He and Fan2022). Moreover, circular RNAs also interact with RNA m6A modifications to regulate ILC3 development. Liu et al. discovered the high expression of the circular RNA circZbtb20 in ILC3. The lack of circZbtb20 diminishes ILC3 numbers and increases susceptibility to Citrobacter rodentium infection. Mechanistically, the 1200-1605 region of circZbtb20 interacts directly with ALKBH5. Subsequently, ALKBH5 removes the m6A on Nr4a1 mRNA, which enhances the stability of Nr4a1 mRNA. Subsequently, NR4A1 activates the Notch2 signal to maintain ILC3 homeostasis. Meanwhile, mice with the lack of Alkbh5 or NR4A1 disrupt ILC3s lineage development and intestinal immune homeostasis, rendering them more susceptible to Citrobacter rodentium infection (Liu et al. Reference Liu, Liu and Zhu2021). This further corroborates the role of circZbtb20-Alkbh5-Nr4a1 axis in regulating the development and maturation of ILC3.

RNA m6A methylation modulates the lineage development and activation of ILC1s, ILC2s, and ILC3s

Additionally, RNA m6A methylation participates in regulating ILCs lineage development. Zhang et al. observed that the absence of METTL3 had minimal impact on the homeostasis of ILC or the cytokine-induced responses of ILC1 or ILC3. However, it significantly reduced the proliferation, migration, and effector cytokine production of ILC2, leading to compromised immune function. Mechanistic studies revealed that METTL3 facilitated the high methylation of Gata3 mRNA in ILC2s, thereby enhancing Gata3 mRNA stability to promote ILC2 activation (Zhang et al. Reference Zhang, Zhang and Zhao2023c). GATA3 stands as an essential TF for the development of all ILCs (Yagi et al. Reference Yagi, Zhong and Northrup2014).

Histone modification regulates the lineage development and activation of ILC1s, ILC2s, and ILC3s

Histone acetylation and methylation have also been found to participate in regulating the activation of ILCs. During the multipotent HSC stage, HDAC3 promotes the normal differentiation of immune cells by maintaining chromatin structure and genomic stability. The absence of HDAC3 at this stage prevents lymphoid progenitors from efficient DNA replication, leading to cell cycle S-phase arrest and ultimately diminishing the development and differentiation of ILCs (Summers et al. Reference Summers, Fischer and Stengel2013). Toki and colleagues discovered that trichostatin A, an inhibitor of HDACs, reduced allergen-induced ILC2s activation and the early innate immune response to inhaled protease-containing airborne allergens (Toki et al. Reference Toki, Goleniewska and Reiss2016). The bromodomain and extra-terminal (BET) bromodomain is an evolutionarily conserved protein domain capable of recognizing and binding acetylated lysine residues on histones. Its inhibitor, iBET151, effectively hinders human ILC2 activation and suppresses type 2 immune responses (Kerscher et al. Reference Kerscher, Barlow and Rana2019). Antignano et al. identified the role of lysine methyltransferase G9a in regulating ILC2s development and function (Antignano et al. Reference Antignano, Braam and Hughes2016). They found that hematopoietic cell-specific G9a deficiency led to a drastic reduction in peripheral ILC2s. Mechanistic studies revealed that H3K9me2 mediated by G9a is necessary for silencing ILC3s-related genes in ILC2s and inhibiting the development of ILC3 lineage. Simultaneously, G9a is crucial for promoting the expression of ILC2s-related genes in mature ILC2s. Additionally, studies reported that ILCs from Gfi1-deficient mice exhibited reduced ILC2 frequencies and dysregulated expression of ILC3-related genes (Spooner et al. Reference Spooner, Lesch and Yan2013), a phenotype similar to G9a-deficient ILC2s. Furthermore, Gfi1 has been shown to directly interact with G9a (Duan et al. Reference Duan, Zarebski and Montoya-Durango2005), suggesting that the G9a-Gfi1 interaction may play a crucial role in the epigenetic regulation of ILC development.

Epigenetic modifications modulate lineage development and activation of NK cell

Holmes et al. elucidated the transcriptional and epigenetic networks governing human NK cell differentiation, identifying Bcl11b as a central regulatory factor in several steps of NK cell differentiation (Holmes et al. Reference Holmes, Pandey and Helm2021). BCL11B maintains a transcriptional program that enhances NK cell receptor expression, effector functions, and proliferation in response to viral infections (Holmes et al. Reference Holmes, Pandey and Helm2021). The level of DNA methylation within Fcgra3a promoter negatively correlates with CD16a levels during NK cell maturation (Victor et al. Reference Victor, Weigel and Scoville2018). ID2 also plays a critical role in NK cell development. Nandakumar et al. observed severely impaired NK cell development in mice lacking the histone deubiquitinase MYSM1, which led to suppressed Id2 expression. This deficiency occurred because MYSM1 interacts with NFIL3, facilitating their recruitment to the Id2 gene locus. This interaction shifts the chromatin of the Id2 gene region from a repressed to an activated state, crucially promoting NK cell development (Nandakumar et al. Reference Nandakumar, Chou and Zang2013). This suggests that MYSM1 is a pivotal epigenetic regulator of NK cell development, controlling the chromatin status of the Id2 gene region, which is crucial for NK cell development, and transcriptional regulation of Id2. Moreover, miRNAs have emerged as essential regulators in NK cell development. Reduced levels of miR-181 inhibit the differentiation of hematopoietic progenitor cells into mature NK cells, whereas its overexpression increases NK cell differentiation. Additionally, miR-181 expression in NK progenitors increases as they progress through differentiation stages. Mechanistic studies indicate that miR-181 influences NK cell differentiation by downregulating the Notch signaling pathway through its target, the NF-κB essential modulator (nemo)-like kinase (Cichocki et al. Reference Cichocki, Felices and McCullar2011). Notch signaling appears to be indispensable during NK cell maturation (Schenk et al. Reference Schenk, Bloch and Zimmer2016).

Discussion on epigenetic modifications regulation of the lineage development and activation of ILCs

As mentioned above, epigenetic modifications play an indispensable role in the development and plasticity of ILCs, responding to the local microenvironment shaped during homeostasis and infection, as well as disease signals. Establishing a comprehensive TFs network and epigenetic modification landscape during ILC lineage development would aid in understanding and developing strategies for reprogramming progenitor cells or ILCs using epigenetic modifications and their associated enzymes. This could regulate the host’s innate immune homeostasis.

The role of epigenetic modification in pathogen infection

Epigenetic modifications operate at various levels, including transcription, posttranscriptional modifications, and posttranslational modifications, to regulate innate immune signaling upon infection, thereby preventing infection and inflammatory damage. Upon pathogen invasion, IICs utilize PRRs to detect pathogens, rapidly transmitting the infection signals to the cell nucleus. This process shapes a specific epigenetic modification pattern in IICs and alters the expression of relevant epigenetic enzyme genes. In turn, specific epigenetic modification patterns confer IICs with a distinctive gene expression profile. Subsequently, by activating or suppressing PRRs and regulating the transcription of pro-inflammatory cytokines and antimicrobial peptides (AMPs), these patterns help balance and sustain the intensity of the innate immune response.

Epigenetic modifications modulate the PPRs of IICs to balance the innate immune response

PRRs are essential components of the IICs that perceive PAMPs and DAMPs. They primarily include TLRs, RIG-I-like receptors, and Nod-like receptors (NLRs). Activation of these PRRs induces the production of cytokines and IFNs, thereby initiating antimicrobial and antiviral responses in IICs. Gene expression of PRRs and their signaling molecules is subject to epigenetic regulation, encompassing processes ranging from the initiation of transcription mediated by DNA methylation, histone methylation and acetylation to chromatin remodeling. Additionally, RNA stability and translation rates are modulated by RNA-binding proteins (RBPs) and m6A modification proteins.

Transcriptional regulation

The transcription initiation of PRRs and their signaling molecules represents a crucial checkpoint for IICs to resist pathogenic invasions. Studies have revealed that macrophages, during the early stages of bacterial infection, activate TLR4 by promoting the generation of acetyl-CoA from glucose (Lauterbach et al. Reference Lauterbach, Hanke and Serefidou2019). This enhances histone acetylation, independent of HDACs and HATs. Subsequently, the signaling cascade through MyD88 and TRIF leads to the activation of ATP citrate lyase, further promoting the transcription of LPS-induced gene sets (Lauterbach et al. Reference Lauterbach, Hanke and Serefidou2019) (Fig. 4A). This research underscores the potential of targeting the metabolic-histone acetylation modification axis to regulate innate immune responses against invading pathogens. The histone methyltransferase Ezh1, dependent on lysine methyltransferase activity, directly binds to the proximal promoter of Tollip (TLRs interacting protein), a negative regulator of TLR signaling, and maintains H3K27me3 to suppress Tollip transcription. Consequently, Ezh1 promotes the production of inflammatory cytokines triggered by TLRs by inhibiting the negative regulatory factor Tollip, contributing to the full activation of innate immune responses against invading pathogens (Liu et al. Reference Liu, Zhang and Ding2015). Furthermore, macrophage Ezh2, by suppressing SIRT1-mediated deacetylation, maintains H3K27ac in the promoter of lncRNA-Neat1 (Yuan et al. Reference Yuan, Zhu and Zhang2022) (Fig. 4B). The increased chromatin accessibility facilitates p65-mediated transcription of lncRNA-Neat1, a critical mediator in the assembly and activation of NLRs-mediated inflammasomes. Simultaneously, p53 competes for binding to the lncRNA-Neat1 promoter region, recruiting the deacetylase SIRT1 for H3K27 deacetylation. This antagonizes Ezh2-induced transcription of lncRNA-Neat1 and downstream inflammasome activation. This suggests that Ezh2 and p53, through competitive interactions, maintain H3K27ac, thereby participating in the transcriptional activation of lncRNA-Neat1 and subsequently regulating NLRs activation (Yuan et al. Reference Yuan, Zhu and Zhang2022). The H3K4-specific histone methyltransferase WDR5 and H3K79 methyltransferase DOT1L, by mediating histone methylation, enhance the binding of IRF3 to the Nlrp3 promoter and promote Nlrp3 transcription in liver macrophages induced by STING, thereby enhancing cell pyroptosis and liver inflammation (Xiao et al. Reference Xiao, Zhao and Tai2023) (Fig. 4B). In primary macrophages, KMT2B directly promotes the transcription of the Pigp gene by increasing H3K4me3 levels at its promoter (Austenaa et al. Reference Austenaa, Barozzi and Chronowska2012). The product of Pigp is essential for proper membrane anchoring of CD14, an accessory receptor for TLR3-mediated signaling.

Figure 4. Epigenetic mechanisms mediating PRRs transcription signaling. A. Bacterial infection activates TLR4, leading to the MyD88/TRIF-dependent pathway that promotes glucose metabolism and the production of CoA. This, in turn, regulates histone acetylation modifications, enhancing the transcription of immune response genes. B. The interplay between the pattern recognition receptor NLRP3 and epigenetic modifications.

During the activation of macrophages by LPS, HDAC3 is recruited to ATF2 binding sites, activating Tlr4 transcription (Nguyen et al. Reference Nguyen, Adlanmerini and Hauck2020). Loss of HDAC3 in macrophages protects mice from lethal exposure to LPS (Chi et al. Reference Chi, Chen and Xu2020; Nguyen et al. Reference Nguyen, Adlanmerini and Hauck2020). Additionally, HDAC3, independent of its classical nuclear histone deacetylation function, translocates to mitochondria during macrophage NLRP3 inflammasome activation (Fig. 4B). HDAC3 deacetylates the HADHA at the K303 site during fatty acid oxidation, reducing its catalytic activity. This, in turn, hampers macrophage fatty acid oxidation metabolism efficiency, ultimately promoting the maturation and secretion of IL-1β mediated by the NLRP3 inflammasome, exacerbating inflammatory responses, and inducing inflammatory damage to the organism (Chi et al. Reference Chi, Chen and Xu2020).

Posttranscriptional regulation

The protein expression of various signaling molecules of PRRs is extensively subject to transcriptional post-regulation, with a critical contribution from RBPs and m6A modification proteins. Luo et al. discovered that in LPS-induced sepsis, METTL3 facilitates m6A modification of Tlr4 mRNA in neutrophils, enhancing Tlr4 mRNA translation rate and inhibiting its degradation. This leads to elevated levels of TLR4 protein, ultimately promoting TLR4 signaling activation in neutrophils, exacerbating the outbreak of inflammation, and subsequently increasing mortality rates (Luo et al. Reference Luo, Liao and Zhang2023). RBP DDX5 interacts with METTL3 and METTL14 to form an m6A writing complex. This complex adds m6A to the transcripts of Tlr2 and Tlr4, promoting their decay through RNA degradation mediated by YTHDF2. As a result, the expression of TLR2/4 is reduced, balancing the inflammatory response induced by bacterial infection (Xu et al. Reference Xu, Liu and Zhi2024) (Fig. 5). In our previous studies, we found that YTHDF1, by recognizing the key factor m6A modification in TRLs and NLRs signaling, participates in innate immune responses (Zong et al. Reference Zong, Xiao and Shen2021c). Traf6, a crucial regulatory factor in TLRs and subsequent NF-κB signaling, is recognized by RBP DDX60 through its HELICc domain, interacting with Traf6 mRNA. DDX60 also utilizes its HELICc domain to interact with the P/Q/N domain of YTHDF1, recruiting YTHDF1. Subsequently, YTHDF1 recognizes the m6A of Traf6 mRNA through YTH domain, promoting Traf6 translation and its mediation of intestinal immune responses (Zong et al. Reference Zong, Xiao and Shen2021c) (Fig. 5). Additionally, both our lab and other researchers have discovered that YTHDF1 directly recognizes the m6A modification in macrophage Nlrp3 mRNA (Hao et al. Reference Hao, Lou and Hu2022; Zong et al. Reference Zong, Xiao and Jie2021b) (Fig. 5). This promotes its translation rate in polysomes, leading to NLRP3 inflammasome activation and, consequently, facilitating intestinal bacterial infection. Mice lacking YTHDF1 are protected from various detrimental effects of bacterial infections (Hao et al. Reference Hao, Lou and Hu2022; Zong et al. Reference Zong, Xiao and Jie2021b). Similarly, after viral infection, RBP DDX46 recruits ALKBH5, which, through the DEAD helicase domain of DDX46, removes the m6A modification from transcripts associated with antiviral responses such as Mavs, Traf3, and Traf6 (Zheng et al. Reference Zheng, Hou and Zhou2017). This inhibits their nuclear export, preventing their translation in the ribosome and suppressing IFN production, ultimately suppressing the antiviral innate immune response (Zheng et al. Reference Zheng, Hou and Zhou2017). In addition, miRNAs also participate in the regulation of posttranscriptional modifications of TLRs. For instance, in alveolar macrophages from patients with severe asthma, there is a significant reduction in the expression of TLR7, accompanied by a substantial increase in the expression of miR-150, miR-152, and miR-375. Further investigations have revealed that these three miRNAs collectively inhibit the expression of TLR7, leading to a reduction in IFN production and facilitating viral invasion (Diebold et al. Reference Diebold, Kaisho and Hemmi2004; Rupani et al. Reference Rupani, Martinez-Nunez and Dennison2016).

Figure 5. Epigenetic mechanisms mediating posttranscriptional regulation of PRRs. Notes: Bacterial infection activates the NF-κB-p65 signaling pathway through TLR4, leading to the transcription of Tlr4, Tlr2, Traf6, and nlrp3 genes. Subsequently, these Tlr4, Tlr2, Traf6, and nlrp3 RNAs are recognized by DDX60, which recruits METTL3 to promote their m6A modification. Under the influence of YTHDF1, this modification enhances their translation in ribosomes. This process subsequently triggers a positive feedback loop that regulates the expression of TLR4 and NLRP3.

Epigenetic modifications modulate the innate immune effector of IICs to balance the innate immune response

Pro-inflammatory cytokines

Epigenetic modifications play a crucial role in modulating the chromatin remodeling of IICs in response to innate immune responses. For instance, RelB induces facultative heterochromatin formation by directly interacting with G9a. Subsequently, heterochromatin protein and G9a form a complex at the Il-1β promoter, promoting Il-1β transcription (Chen et al. Reference Chen, El Gazzar and Yoza2009). Prolonged stimulation of macrophages with LPS increases the expression of miR-221 and miR-222, which, in turn, suppresses Brg1, an ATPase subunit of the SWI/SNF. This alteration leads to changes in the level or composition of the SWI/SNF complex, thereby inhibiting the transcription of STAT2-dependent pro-inflammatory cytokine genes (Seeley et al. Reference Seeley, Baker and Mohamed2018). Similarly, antisense IL-7 is a recently discovered lncRNA in humans and mice. Mechanistic studies reveal that lncRNA-IL-7-AS interacts with p300, regulating the level of histone acetylation in the Il-6 gene promoter region. Simultaneously, the complex formed by lncRNA-IL-7-AS and p300 participates in the regulation of SWI/SNF-mediated chromatin remodeling at the Il-6 gene promoter, promoting Il-6 transcription (Liu et al. Reference Liu, Lu and Zhu2019b) (Fig. 6A).

Figure 6. Epigenetic mechanisms mediating the transcription of innate immune factors. A. Lnc-IL7-AS and H3K27ac in the regulation of Il6 transcription. B. ASH11-mediated H3K4me regulation of Il6 and Tnf-α transcription. C. TET2 and HDAC2 in regulation of Il6 transcription via H3K27ac. D. Histone acetylation levels on AMPs gene loci correlate positively with AMP transcription. E. DNA methylation levels at AMPs promoters correlate negatively with AMP transcription.

Furthermore, histone methylation and acetylation are major factors in the transcription of pro-inflammatory cytokines in IICs. For example, Ash1l, through the SET domain’s H3K4 methyltransferase activity, induces H3K4 methylation at the Tnfaip3 promoter, enhancing the expression of the deubiquitinase A20. Ash1l promotes TRAF6 deubiquitination mediated by A20, inhibiting the NF-κB pathway and subsequent production of Il-6 and Tnf-α, protecting mice from sepsis (Fig. 6B). The histone methyltransferase SETD4 rapidly translocates from the cytoplasm to the nucleus upon LPS stimulation, positively regulating Il-6 and Tnf-α transcription in macrophages by directly activating H3K4 methylation at the gene promoters, independent of upstream regulatory factors such as p38, ERK, JNK, p65, and IκBα (Zhong et al. Reference Zhong, Ye and Mei2019). Additionally, histone deacetylation modification is a mechanism that inhibits the transcription of pro-inflammatory cytokines during the resolution of inflammation. For example, Tet2, independent of DNA methylation, inhibits Il-6 transcription by recruiting HDAC2. Compared to wild-type mice, Tet2-deficient mice are more susceptible to endotoxic shock and dextran sulfate sodium-induced colitis, leading to aggravated inflammation and IL-6 storm (Zhang et al. Reference Zhang, Zhao and Shen2015) (Fig. 6C). In addition, during the polarization process of porcine macrophages stimulated by LPS, the expression of DNTM3b is reduced, leading to a downregulation of the methylation level of the Tnf-α gene promoter, thereby promoting its transcription (Zhang et al. Reference Zhang, Li and Xiang2020). Similarly, porcine reproductive and respiratory syndrome virus infection in porcine macrophages inhibits the expression of FTO, resulting in an increase in m6A methylation levels. This, in turn, enhances the expression of IL-13 through the functional modulation of m6A modifications (Gong et al. Reference Gong, Liang and Wang2024).

In summary, these studies directly indicate that epigenetic modifications regulate the transcription of cytokines in IICs in response to pathogenic infections through chromatin remodeling, histone modifications, DNA and RNA methylation, and ncRNAs. However, it remains unclear whether the sustained development of IICs will reciprocally regulate epigenetic modifications, thus reversing the activation state of IICs and forming a feedback loop to activate and inhibit ILCs-mediated innate immune responses timely.

Antimicrobial peptides

AMPs are a class of cationic host defense peptides that not only possess direct bactericidal properties but also enhance the functions of various IICs through immunomodulation, thereby resisting pathogenic infections (Fu et al. Reference Fu, Zong and Jin2023). Currently, research on the epigenetic regulation mechanisms of AMPs in IICs predominantly focuses on histone acetylation. For instance, HDACi has been confirmed as effective inducers of AMPs (Lyu et al. Reference Lyu, Deng and Zhang2023; Rodríguez-Carlos et al. Reference Rodríguez-Carlos, Jacobo-Delgado and Santos-Mena2021) (Fig. 6D). A groundbreaking study by Garcia et al. established a connection between histone acetylation, AMPs transcription, and intracellular bacterial infection. Infections by Bacillus thuringiensis in THP-1 macrophages resulted in the silencing of AMPs expression (Garcia-Garcia et al. Reference Garcia-Garcia, Barat and Trembley2009). Mechanistic investigations revealed that infection promoted the HDAC1 expression. Increased binding of HDAC1 to the AMPs gene promoter was observed, leading to a significant reduction in histone H3 acetylation in infected cells. This ultimately inhibited the open chromatin state and gene expression of AMPs. Overexpression of HDAC1 enhanced bacterial infectivity, while HDAC1 inhibition significantly reduced bacterial load (Garcia-Garcia et al. Reference Garcia-Garcia, Barat and Trembley2009). Further studies demonstrated that during bacterial infection, inhibition of HDAC promoted acetylation of the p65 K310 lysine residue by histone acetyltransferase p300, enhancing the expression of the hBD2 gene without a concomitant increase in inflammatory cytokines, thereby reinforcing antimicrobial immune modulation capabilities (Fischer et al. Reference Fischer, Sechet and Friedman2016).

Regarding the regulation of AMPs transcription by DNA methylation, research indicates that DNA methylation in the AMPs promoter region leads to transcriptional downregulation, increasing the host’s susceptibility to bacterial infections (Chen et al. Reference Chen, Qi and Qin2017a; Noh et al. Reference Noh, Lee and Seo2018; Wang et al. Reference Wang, Li and Yang2021) (Fig. 6D). In our previous investigation into the relationship between RNA m6A methylation and AMPs expression, we discovered an interaction between the TF FOXO6 and METTL3. This interaction triggered the transcription of GPR161 and its subsequent regulation of AMPs transcription, contributing to the resistance against Enterotoxigenic Escherichia coli-induced inflammatory responses (Zong et al. Reference Zong, Wang and Xiao2021a). However, the precise mechanisms of DNA methylation and RNA methylation in regulating AMPs transcription or posttranscriptional modifications remain to be studied.

Conclusion and prospects

A functional immune system relies on the precise and swift regulation of IICs in response to ever-changing signals within their ecological niches. This capability hinges upon the diverse functionality and high adaptability of these cells. Disruption of the plasticity of IICs can trigger innate immune dysregulation and excessive inflammatory responses, ultimately leading to the onset of immune-related diseases in the host. Epigenetic modifications play a pivotal role in maintaining the functionality and plasticity of IICs, as well as in the innate immune responses associated with infections and chronic inflammation. Current research primarily focuses on elucidating how epigenetics undergo reprogramming and how this reprogrammed epigenome, in turn, establishes functionally specific gene expression patterns in innate immunity. The establishment of comprehensive single-cell epigenomic and transcriptomic profiles of IICs, particularly during in vivo innate immune responses, at the single-cell and single-molecule levels through single-cell transcriptomics and single-cell epigenomic sequencing technologies, is poised to decode the epigenetic blueprint of innate immunity comprehensively. Targeting the regulation of epigenetic modifications in IICs is considered a promising strategy. Utilizing epigenetic inhibitors to remove disease-associated epigenetic modifications that contribute to altered gene expression patterns in the host, may aid in re-establishing immune homeostasis, pathogen clearance, and mitigating tissue inflammation. However, epigenetic inhibitors typically exert systemic effects when used in the human body, making it challenging to specifically target key subsets of IICs. Moreover, some epigenetic inhibitors used in clinical trials demonstrate broad effects lacking specificity for gene loci, potentially reactivating non-beneficial or silenced genomic sequences. Epigenetic drugs often exhibit inherent biological activity, thus necessitating researchers to rely on medicinal chemistry design to enhance compound selectivity and specificity, ensuring their safety by avoiding toxicity. This aspect holds particular importance, particularly in the context of recurrent infections or ailments marked by sustained inflammation, demanding prolonged therapeutic strategies. Additionally, the combination of different epigenetic inhibitors might augment the efficacy of each drug. For instance, the combined use of DNMTi and HDACi increased M2 polarization in lung tissues, ameliorating acute lung injury caused by sepsis. This suggests that combination therapy might be the most beneficial approach for treating particular pathological conditions; however, further investigation is imperative to substantiate this premise.

Important issues to be addressed in the future

  1. 1) It utilizes recently developed cell lineage tracing tools (Bowling et al. Reference Bowling, Sritharan and Osorio2020), investigating longitudinally and in multiple dimensions at the single-cell level, accurately characterizing the phenotypic plasticity and epigenome of IICs at each critical time point during lineage development and differentiation. This aims to identify the key TFs and epigenetic modifications defining the state of IICs and determine whether the plasticity of these cells could be extended through controlling epigenetic modifications to treat associated diseases.

  2. 2) The conservation of lncRNAs is relatively low, and their folding and structure heterogeneity presents significant challenges in related studies. Therefore, our current understanding of lncRNAs in regulating the fate and function of IICs still needs to be improved. Developing third-generation long-read RNA sequencing, ultra-high-resolution imaging techniques, and gene editing technologies offers new opportunities for studying lncRNAs. Leveraging machine learning to analyze vast datasets encompassing genomics, epigenomics, transcriptomics, proteomics, and phenomics of IICs can aid in identifying causal relationships and pathways. This approach may help discover crucial lncRNAs regulating IICs fate. With the continued advancement in the research of the biological functions and mechanisms of lncRNAs, targeted lncRNA therapies are poised to play a significant role in disease diagnosis, targeted treatment, and drug development.

  3. 3) How will integrative analysis of epigenomics and other omics data transform our understanding of the lineage development, differentiation, and activation of IICs? While comprehensive epigenomic and transcriptomic studies have been conducted at the macrophage subtype level, a method to demonstrate the total epigenetic modification rate in individual macrophages is yet to be established. If such an approach is developed, could it accurately predict macrophage development or polarization states? Moreover, can it explain the functional and phenotypic differences between early activated macrophage polarization for pathogen resistance and long-term activation leading to host damage? If this concept can be realized, doctors would only need to collect a few milliliters of a patient’s blood, isolate macrophages using biochemical instrumentation, and detect their overall epigenetic modification rate through appropriate methods. This would enable doctors to determine the state of immune activation in patients, greatly assisting in the targeted treatment of patients and reducing the misdiagnosis of clinical symptoms.

  4. 4) Achieving specific epigenetic modifications targeting particular subsets of IICs is a critical concern. Additionally, the combined use of different epigenetic inhibitors has shown improved efficacy. Can similar epigenetic drugs induce synergistic effects by acting on various subsets of IICs? However, these issues are of clinical significance and require not only researchers to conduct specific targeted experiments and safety studies in model organisms such as mice to provide a theoretical basis, but also for doctors to utilize these reliable results to conduct clinical trials on a large scale by recruiting patients for individual testing and analysis. This approach is necessary to address the questions above.

  5. 5) Can highly specific epigenetic inhibitors retain biological activity while reducing toxicity?

  6. 6) Can combining immunotherapy with epigenetic therapy lead to more effective treatment strategies?

  7. 7) Exploring additional epigenetic mechanisms such as chromatin condensation, DNA (hydroxy)methylation, and gaining deeper insights into the roles of enhancers and 3D chromatin architecture. These novel epigenetic mechanisms may pave a new path toward the treatment of specific, previously untreatable diseases.

Author contributions

JF conceived and wrote the review, YW provided the writing guidance.

Financial support

The project was supported by the Zhejiang Provincial Key R&D Program of China (2021C02008), the China Agriculture Research System of MOF and MARA (CARS-35).

References

Akhtar, J, Renaud, Y, Albrecht, S et al. (2021) m(6)A RNA methylation regulates promoter-proximal pausing of RNA polymerase II. Molecular Cell 81, .CrossRefGoogle ScholarPubMed
Alarcon, CR, Goodarzi, H, Lee, H et al. (2015) HNRNPA2B1 is a mediator of m(6)A-dependent nuclear RNA processing events. Cell 162, 12991308.CrossRefGoogle ScholarPubMed
Allis, CD and Jenuwein, T (2016) The molecular hallmarks of epigenetic control. Nature Reviews Genetics 17, 487500.CrossRefGoogle ScholarPubMed
Álvarez-Errico, D, Vento-Tormo, R, Sieweke, M et al. (2015) Epigenetic control of myeloid cell differentiation, identity and function. Nature Reviews Immunology 15, 717.CrossRefGoogle ScholarPubMed
Amatullah, H and Jeffrey, KL (2020) Epigenome-metabolome-microbiome axis in health and IBD. Current Opinion in Microbiology 56, 97108.CrossRefGoogle ScholarPubMed
Antignano, F, Braam, M, Hughes, MR et al. (2016) G9a regulates group 2 innate lymphoid cell development by repressing the group 3 innate lymphoid cell program. Journal of Experimental Medicine 213, 11531162.CrossRefGoogle Scholar
Ardouin, L, Luche, H, Chelbi, R et al. (2016) Broad and largely concordant molecular changes characterize tolerogenic and immunogenic dendritic cell maturation in thymus and periphery. Immunity 45, 305318.CrossRefGoogle ScholarPubMed
Arechederra, M, Daian, F, Yim, A et al. (2018) Hypermethylation of gene body CpG islands predicts high dosage of functional oncogenes in liver cancer. Nature Communications 9, .Google ScholarPubMed
Artis, D and Spits, H (2015) The biology of innate lymphoid cells. Nature 517, 293301.CrossRefGoogle ScholarPubMed
Atianand, MK, Hu, W, Satpathy, AT et al. (2016) A long noncoding RNA lincRNA-EPS acts as a transcriptional brake to restrain inflammation. Cell 165, 16721685.CrossRefGoogle ScholarPubMed
Austenaa, L, Barozzi, I, Chronowska, A et al. (2012) The histone methyltransferase Wbp7 controls macrophage function through GPI glycolipid anchor synthesis. Immunity 36, 572585.CrossRefGoogle ScholarPubMed
Bai, X, Wong, CC, Pan, Y et al. (2022) Loss of YTHDF1 in gastric tumors restores sensitivity to antitumor immunity by recruiting mature dendritic cells. The Journal for Immunotherapy of Cancer 10, .CrossRefGoogle ScholarPubMed
Bartel, DP (2009) MicroRNAs: Target recognition and regulatory functions. Cell 136, 215233.CrossRefGoogle ScholarPubMed
Becker, AM, Michael, DG, Satpathy, AT et al. (2012) IRF-8 extinguishes neutrophil production and promotes dendritic cell lineage commitment in both myeloid and lymphoid mouse progenitors. Blood 119, 20032012.CrossRefGoogle ScholarPubMed
Belz, GT and Nutt, SL (2012) Transcriptional programming of the dendritic cell network. Nature Reviews Immunology 12, 101113.CrossRefGoogle ScholarPubMed
Bernstein, BE, Kamal, M, Lindblad-Toh, K et al. (2005) Genomic maps and comparative analysis of histone modifications in human and mouse. Cell 120, 169181.CrossRefGoogle ScholarPubMed
Boe, DM, Hulsebus, HJ, Najarro, KM et al. (2022) Advanced age is associated with changes in alveolar macrophages and their responses to the stress of traumatic injury. Journal of Leukocyte Biology 112, 13711386.CrossRefGoogle Scholar
Bokar, JA, Shambaugh, ME, Polayes, D et al. (1997) Purification and cDNA cloning of the AdoMet-binding subunit of the human mRNA (N6-adenosine)-methyltransferase. RNA 3, 12331247.Google ScholarPubMed
Bonder, MJ, Luijk, R, Zhernakova, DV et al. (2017) Disease variants alter transcription factor levels and methylation of their binding sites. Nature Genetics 49, 131138.CrossRefGoogle ScholarPubMed
Boukhaled, GM, Cordeiro, B, Deblois, G et al. (2016) The transcriptional repressor polycomb group factor 6, PCGF6, negatively regulates dendritic cell activation and promotes quiescence. Cell Reports 16, 18291837.CrossRefGoogle ScholarPubMed
Boukhaled, GM, Corrado, M, Guak, H et al. (2019) Chromatin architecture as an essential determinant of dendritic cell function. Frontiers in Immunology 10, .CrossRefGoogle Scholar
Boulias, K and Greer, EL (2022) Means, mechanisms and consequences of adenine methylation in DNA. Nature Reviews Genetics 23, 411428.CrossRefGoogle ScholarPubMed
Boulias, K and Greer, EL (2023) Biological roles of adenine methylation in RNA. Nature Reviews Genetics 24, 143160.CrossRefGoogle ScholarPubMed
Bowling, S, Sritharan, D, Osorio, FG et al. (2020) An engineered CRISPR-Cas9 mouse line for simultaneous readout of lineage histories and gene expression profiles in single cells. Cell 181, .CrossRefGoogle ScholarPubMed
Brown, CJ, Ballabio, A, Rupert, JL et al. (1991) A gene from the region of the human X inactivation centre is expressed exclusively from the inactive X chromosome. Nature 349, 3844.CrossRefGoogle ScholarPubMed
Brubaker, SW, Bonham, KS, Zanoni, I et al. (2015) Innate immune pattern recognition: A cell biological perspective. Annual Review of Immunology 33, 257290.CrossRefGoogle ScholarPubMed
Cao, X (2016) Self-regulation and cross-regulation of pattern-recognition receptor signalling in health and disease. Nature Reviews Immunology 16, 3550.CrossRefGoogle ScholarPubMed
Carninci, P, Kasukawa, T, Katayama, S et al. (2005) The transcriptional landscape of the mammalian genome. Science 309, 15591563.CrossRefGoogle ScholarPubMed
Carpenter, S, Aiello, D, Atianand, MK et al. (2013) A long noncoding RNA mediates both activation and repression of immune response genes. Science 341, 789792.CrossRefGoogle ScholarPubMed
Castellanos-Rubio, A, Fernandez-Jimenez, N, Kratchmarov, R et al. (2016) A long noncoding RNA associated with susceptibility to celiac disease. Science 352, 9195.CrossRefGoogle ScholarPubMed
Cen, S, Li, J, Cai, Z et al. (2020) TRAF4 acts as a fate checkpoint to regulate the adipogenic differentiation of MSCs by activating PKM2. EBioMedicine 54, .CrossRefGoogle ScholarPubMed
Chauvistré, H and Seré, K (2020) Epigenetic aspects of DC development and differentiation. Molecular Immunology 128, 116124.CrossRefGoogle ScholarPubMed
Chen, B, Dragomir, MP, Yang, C et al. (2022) Targeting non-coding RNAs to overcome cancer therapy resistance. Signal Transduction and Targeted Therapy 7, .CrossRefGoogle ScholarPubMed
Chen, X, El Gazzar, M, Yoza, BK et al. (2009) The NF-kappaB factor RelB and histone H3 lysine methyltransferase G9a directly interact to generate epigenetic silencing in endotoxin tolerance. Journal of Biological Chemistry 284, 2785727865.CrossRefGoogle ScholarPubMed
Chen, X, He, Y, Zhu, Y et al. (2021b) linc-AAM facilitates gene expression contributing to macrophage activation and adaptive immune responses. Cell Reports 34, .CrossRefGoogle ScholarPubMed
Chen, X, Qi, G, Qin, M et al. (2017a) DNA methylation directly downregulates human cathelicidin antimicrobial peptide gene (CAMP) promoter activity. Oncotarget 8, 2794327952.CrossRefGoogle ScholarPubMed
Chen, YG, Satpathy, AT and Chang, HY (2017b) Gene regulation in the immune system by long noncoding RNAs. Nature Immunology 18, 962972.CrossRefGoogle ScholarPubMed
Chen, J, Xu, X, Li, Y et al. (2021a) Kdm6a suppresses the alternative activation of macrophages and impairs energy expenditure in obesity. Cell Death and Differentiation 28, 16881704.CrossRefGoogle ScholarPubMed
Chen, S, Yang, J, Wei, Y et al. (2020) Epigenetic regulation of macrophages: From homeostasis maintenance to host defense. Cellular and Molecular Immunology 17, 3649.CrossRefGoogle ScholarPubMed
Chi, Z, Chen, S, Xu, T et al. (2020) Histone deacetylase 3 couples mitochondria to drive IL-1β-dependent inflammation by configuring fatty acid oxidation. Molecular Cell 80, .CrossRefGoogle ScholarPubMed
Cichocki, F, Felices, M, McCullar, V et al. (2011) Cutting edge: MicroRNA-181 promotes human NK cell development by regulating Notch signaling. Journal of Immunology 187, 61716175.CrossRefGoogle ScholarPubMed
Comer, BS, Ba, M, Singer, CA et al. (2015) Epigenetic targets for novel therapies of lung diseases. Pharmacology and Therapeutics 147, 91110.CrossRefGoogle ScholarPubMed
Cong, B, Zhang, Q and Cao, X (2021) The function and regulation of TET2 in innate immunity and inflammation. Protein Cell 12, 165173.CrossRefGoogle ScholarPubMed
Daskalaki, MG, Tsatsanis, C and Kampranis, SC (2018) Histone methylation and acetylation in macrophages as a mechanism for regulation of inflammatory responses. Journal of Cellular Physiology 233, 64956507.CrossRefGoogle ScholarPubMed
Dekkers, KF, Neele, AE, Jukema, JW et al. (2019) Human monocyte-to-macrophage differentiation involves highly localized gain and loss of DNA methylation at transcription factor binding sites. Epigenetics Chromatin 12, .CrossRefGoogle ScholarPubMed
de la Rica, L, Rodríguez-Ubreva, J, García, M et al. (2013) PU.1 target genes undergo Tet2-coupled demethylation and DNMT3b-mediated methylation in monocyte-to-osteoclast differentiation. Genome Biology 14, .CrossRefGoogle ScholarPubMed
Desrosiers, R, Friderici, K and Rottman, F (1974) Identification of methylated nucleosides in messenger RNA from Novikoff hepatoma cells. Proceedings of the National Academy of Sciences of the USA 71, 39713975.CrossRefGoogle ScholarPubMed
Diebold, SS, Kaisho, T, Hemmi, H et al. (2004) Innate antiviral responses by means of TLR7-mediated recognition of single-stranded RNA. Science 303, 15291531.CrossRefGoogle ScholarPubMed
Djebali, S, Davis, CA, Merkel, A et al. (2012) Landscape of transcription in human cells. Nature 489, 101108.CrossRefGoogle ScholarPubMed
Domínguez-Andrés, J, Dos Santos, JC, Bekkering, S et al. (2023) Trained immunity: Adaptation within innate immune mechanisms. Physiological Reviews 103, 313346.CrossRefGoogle ScholarPubMed
Dominissini, D, Moshitch-Moshkovitz, S, Schwartz, S et al. (2012) Topology of the human and mouse m(6)A RNA methylomes revealed by m(6)A-seq. Nature 485, 201U284.CrossRefGoogle Scholar
Dong, L, Chen, C, Zhang, Y et al. (2021) The loss of RNA N6-adenosine methyltransferase Mettl14 in tumor-associated macrophages promotes CD8+ T cell dysfunction and tumor growth. Cancer Cell 39, .CrossRefGoogle Scholar
Dress, RJ, Wong, AYW and Ginhoux, F (2018) Homeostatic control of dendritic cell numbers and differentiation. Immunology and Cell Biology 96, 463476.CrossRefGoogle ScholarPubMed
Duan, Z, Zarebski, A, Montoya-Durango, D et al. (2005) Gfi1 coordinates epigenetic repression of p21Cip/WAF1 by recruitment of histone lysine methyltransferase G9a and histone deacetylase 1. Molecular and Cellular Biology 25, 1033810351.CrossRefGoogle ScholarPubMed
Du, J, Liao, W, Liu, W et al. (2020) N(6)-adenosine methylation of Socs1 mRNA is required to sustain the negative feedback control of macrophage activation. Developmental Cell 55, .CrossRefGoogle ScholarPubMed
Du, M, Yuan, L, Tan, X et al. (2017) The LPS-inducible lncRNA Mirt2 is a negative regulator of inflammation. Nature Communications 8, .CrossRefGoogle ScholarPubMed
Feng, X and He, C (2023) Mammalian DNA N(6)-methyladenosine: Challenges and new insights. Molecular Cell 83, 343351.CrossRefGoogle ScholarPubMed
Ferrè, F, Colantoni, A and Helmer-Citterich, M (2016) Revealing protein-lncRNA interaction. Briefings in Bioinformatics 17, 106116.CrossRefGoogle ScholarPubMed
Fischer, N, Sechet, E, Friedman, R et al. (2016) Histone deacetylase inhibition enhances antimicrobial peptide but not inflammatory cytokine expression upon bacterial challenge. Proceedings of the National Academy of Sciences of the USA 113, E29933001.Google Scholar
Förster, R, Davalos-Misslitz, AC and Rot, A (2008) CCR7 and its ligands: Balancing immunity and tolerance. Nature Reviews Immunology 8, 362371.CrossRefGoogle ScholarPubMed
Fraschilla, I, Amatullah, H and Jeffrey, KL (2022) One genome, many cell states: Epigenetic control of innate immunity. Current Opinion in Immunology 75, .CrossRefGoogle ScholarPubMed
Fu, J, Zong, X, Jin, M et al. (2023) Mechanisms and regulation of defensins in host defense. Signal Transduction and Targeted Therapy 8, .CrossRefGoogle ScholarPubMed
Gao, Y, Fang, P, Li, WJ et al. (2020a) LncRNA NEAT1 sponges miR-214 to regulate M2 macrophage polarization by regulation of B7-H3 in multiple myeloma. Molecular Immunology 117, 2028.CrossRefGoogle ScholarPubMed
Gao, Y, Vasic, R, Song, Y et al. (2020b) m(6)A modification prevents formation of endogenous double-stranded RNAs and deleterious innate immune responses during hematopoietic development. Immunity 52, .CrossRefGoogle ScholarPubMed
Garcia-Garcia, JC, Barat, NC, Trembley, SJ et al. (2009) Epigenetic silencing of host cell defense genes enhances intracellular survival of the rickettsial pathogen Anaplasma phagocytophilum. PLoS Pathogens 5, .CrossRefGoogle ScholarPubMed
Ginhoux, F and Jung, S (2014) Monocytes and macrophages: Developmental pathways and tissue homeostasis. Nature Reviews Immunology 14, 392404.CrossRefGoogle ScholarPubMed
Ginno, PA, Gaidatzis, D, Feldmann, A et al. (2020) A genome-scale map of DNA methylation turnover identifies site-specific dependencies of DNMT and TET activity. Nature Communications 11, .CrossRefGoogle ScholarPubMed
Gomez, JA, Wapinski, OL, Yang, YW et al. (2013) The NeST long ncRNA controls microbial susceptibility and epigenetic activation of the interferon-γ locus. Cell 152, 743754.CrossRefGoogle ScholarPubMed
Gong, X, Liang, Y, Wang, J et al. (2024) Highly pathogenic PRRSV upregulates IL-13 production through nonstructural protein 9–mediated inhibition of N6-methyladenosine demethylase FTO. Journal of Biological Chemistry 300, .CrossRefGoogle ScholarPubMed
Gordon, S and Taylor, PR (2005) Monocyte and macrophage heterogeneity. Nature Reviews Immunology 5, 953964.CrossRefGoogle ScholarPubMed
Guo, X, Liang, Y, Zhang, Y et al. (2015) Innate lymphoid cells control early colonization resistance against intestinal pathogens through ID2-dependent regulation of the microbiota. Immunity 42, 731743.CrossRefGoogle ScholarPubMed
Guo, Z, Wang, L, Liu, H et al. (2022) Innate immune memory in monocytes and macrophages: The potential therapeutic strategies for atherosclerosis. Cells 11, .CrossRefGoogle ScholarPubMed
Gu, X, Zhang, Y, Li, D et al. (2020) N6-methyladenosine demethylase FTO promotes M1 and M2 macrophage activation. Cellular Signalling 69, .CrossRefGoogle ScholarPubMed
Hachiya, R, Shiihashi, T, Shirakawa, I et al. (2016) The H3K9 methyltransferase Setdb1 regulates TLR4-mediated inflammatory responses in macrophages. Scientific Reports 6, .CrossRefGoogle ScholarPubMed
Han, P and Chang, CP (2015) Long non-coding RNA and chromatin remodeling. RNA Biology 12, 10941098.CrossRefGoogle ScholarPubMed
Han, H, Cortez, CC, Yang, X et al. (2011) DNA methylation directly silences genes with non-CpG island promoters and establishes a nucleosome occupied promoter. Human Molecular Genetics 20, 42994310.CrossRefGoogle ScholarPubMed
Han, X, Liu, L, Huang, S et al. (2023) RNA m(6)A methylation modulates airway inflammation in allergic asthma via PTX3-dependent macrophage homeostasis. Nature Communications 14, .CrossRefGoogle ScholarPubMed
Han, Y, Li, X, Zhou, Q et al. (2015) FTY720 abrogates collagen-induced arthritis by hindering dendritic cell migration to local lymph nodes. Journal of Immunology 195, 41264135.CrossRefGoogle ScholarPubMed
Hao, WY, Lou, Y, Hu, GY et al. (2022) RNA m6A reader YTHDF1 facilitates inflammation via enhancing NLRP3 translation. Biochemical and Biophysical Research Communications 616, 7681.CrossRefGoogle ScholarPubMed
Hardbower, DM, Asim, M, Luis, PB et al. (2017) Ornithine decarboxylase regulates M1 macrophage activation and mucosal inflammation via histone modifications. Proceedings of the National Academy of Sciences of the USA 114, E751e760.Google ScholarPubMed
Hoeksema, MA and de Winther, MP (2016) Epigenetic regulation of monocyte and macrophage function. Antioxidants and Redox Signaling 25, 758774.CrossRefGoogle ScholarPubMed
Holmes, TD, Pandey, RV, Helm, EY et al. (2021) The transcription factor Bcl11b promotes both canonical and adaptive NK cell differentiation. Science Immunology 6, .CrossRefGoogle ScholarPubMed
Hsu, PJ, Zhu, Y, Ma, H et al. (2017) Ythdc2 is an N(6)-methyladenosine binding protein that regulates mammalian spermatogenesis. Cell Research 27, 11151127.CrossRefGoogle Scholar
Huangfu, N, Zheng, W, Xu, Z et al. (2020) RBM4 regulates M1 macrophages polarization through targeting STAT1-mediated glycolysis. International Immunopharmacology 83, .CrossRefGoogle ScholarPubMed
Hu, L, Yu, Y, Shen, Y et al. (2023) Ythdf2 promotes pulmonary hypertension by suppressing Hmox1-dependent anti-inflammatory and antioxidant function in alveolar macrophages. Redox Biology 61, .CrossRefGoogle ScholarPubMed
Hu, J, Zhang, L, Liechty, C et al. (2020) Long noncoding RNA GAS5 regulates macrophage polarization and diabetic wound healing. Journal of Investigative Dermatology 140, 16291638.CrossRefGoogle ScholarPubMed
Ishii, M, Wen, H, Corsa, CA et al. (2009) Epigenetic regulation of the alternatively activated macrophage phenotype. Blood 114, 32443254.CrossRefGoogle ScholarPubMed
Jain, N, Shahal, T, Gabrieli, T et al. (2019) Global modulation in DNA epigenetics during pro-inflammatory macrophage activation. Epigenetics 14, 11831193.CrossRefGoogle ScholarPubMed
Jia, GF, Fu, Y, Zhao, X et al. (2011) N6-Methyladenosine in nuclear RNA is a major substrate of the obesity-associated FTO. Nature Chemical Biology 7, 885887.CrossRefGoogle Scholar
Jia, Y, Li, Z, Cai, W et al. (2018) SIRT1 regulates inflammation response of macrophages in sepsis mediated by long noncoding RNA. Biochimica et Biophysica Acta (BBA) - Molecular Basis of Disease 1864, 784792.CrossRefGoogle ScholarPubMed
Jones, PL, Veenstra, GJ, Wade, PA et al. (1998) Methylated DNA and MeCP2 recruit histone deacetylase to repress transcription. Nature Genetics 19, 187191.CrossRefGoogle ScholarPubMed
Kerscher, B, Barlow, JL, Rana, BM et al. (2019) BET bromodomain inhibitor iBET151 impedes human ILC2 activation and prevents experimental allergic lung inflammation. Frontiers in Immunology 10, .CrossRefGoogle ScholarPubMed
Kobayashi, M, Ohsugi, M, Sasako, T et al. (2018) The RNA methyltransferase complex of WTAP, METTL3, and METTL14 regulates mitotic clonal expansion in adipogenesis. Molecular and Cellular Biology 38, e0011618.CrossRefGoogle ScholarPubMed
Kong, Y, Cao, L, Deikus, G et al. (2022) Critical assessment of DNA adenine methylation in eukaryotes using quantitative deconvolution. Science 375, 515522.CrossRefGoogle ScholarPubMed
Krawczyk, M and Emerson, BM (2014) P50-associated COX-2 extragenic RNA (PACER) activates human COX-2 gene expression by occluding repressive NF-κB p50 complexes. Elife 2014, .Google Scholar
Kurotaki, D, Kawase, W, Sasaki, H et al. (2019) Epigenetic control of early dendritic cell lineage specification by the transcription factor IRF8 in mice. Blood 133, 18031813.CrossRefGoogle ScholarPubMed
Kuzelova, A, Dupacova, N, Antosova, B et al. (2023) Chromatin remodeling enzyme Snf2h is essential for retinal cell proliferation and photoreceptor maintenance. Cells 12, .CrossRefGoogle ScholarPubMed
Lau, CM, Adams, NM, Geary, CD et al. (2018) Epigenetic control of innate and adaptive immune memory. Nature Immunology 19, 963972.CrossRefGoogle ScholarPubMed
Lauterbach, MA, Hanke, JE, Serefidou, M et al. (2019) Toll-like receptor signaling rewires macrophage metabolism and promotes histone acetylation via ATP-citrate lyase. Immunity 51, .CrossRefGoogle ScholarPubMed
Lee, J, Zhou, YJ, Ma, W et al. (2017) Lineage specification of human dendritic cells is marked by IRF8 expression in hematopoietic stem cells and multipotent progenitors. Nature Immunology 18, 877888.CrossRefGoogle ScholarPubMed
Li, Z, Chao, TC, Chang, KY et al. (2014b) The long noncoding RNA THRIL regulates TNFα expression through its interaction with hnRNPL. Proceedings of the National Academy of Sciences of the USA 111, 10021007.CrossRefGoogle Scholar
Li, Y, Li, J, Yu, Q et al. (2023) METTL14 regulates microglia/macrophage polarization and NLRP3 inflammasome activation after ischemic stroke by the KAT3B-STING axis. Neurobiology of Disease 185, .CrossRefGoogle ScholarPubMed
Lin, Q, Chauvistré, H, Costa, IG et al. (2015) Epigenetic program and transcription factor circuitry of dendritic cell development. Nucleic Acids Research 43, 96809693.Google ScholarPubMed
Liotti, A, Ferrara, AL, Loffredo, S et al. (2022) Epigenetics: An opportunity to shape innate and adaptive immune responses. Immunology 167, 451470.CrossRefGoogle ScholarPubMed
Li, ML, Su, XM, Ren, Y et al. (2020a) HDAC8 inhibitor attenuates airway responses to antigen stimulus through synchronously suppressing galectin-3 expression and reducing macrophage-2 polarization. Respiratory Research 21, .CrossRefGoogle ScholarPubMed
Liu, J, Dou, X, Chen, C et al. (2020) N (6)-methyladenosine of chromosome-associated regulatory RNA regulates chromatin state and transcription. Science 367, 580586.CrossRefGoogle ScholarPubMed
Liu, N, He, J, Fan, D et al. (2022) Circular RNA circTmem241 drives group III innate lymphoid cell differentiation via initiation of Elk3 transcription. Nature Communications 13, .Google ScholarPubMed
Liu, Y, Liu, Z, Tang, H et al. (2019c) The N6-methyladenosine (m6A)-forming enzyme METTL3 facilitates M1 macrophage polarization through the methylation of STAT1 mRNA. American Journal of Physiology-Cell Physiology 317, C762C775.CrossRefGoogle ScholarPubMed
Liu, B, Liu, N, Zhu, X et al. (2021) Circular RNA circZbtb20 maintains ILC3 homeostasis and function via Alkbh5-dependent m(6)A demethylation of Nr4a1 mRNA. Cellular and Molecular Immunology 18, 14121424.CrossRefGoogle ScholarPubMed
Liu, X, Lu, Y, Zhu, J et al. (2019b) A long noncoding RNA, antisense IL-7, promotes inflammatory gene transcription through facilitating histone acetylation and switch/sucrose nonfermentable chromatin remodeling. Journal of Immunology 203, 15481559.CrossRefGoogle ScholarPubMed
Liu, B, Ye, B, Yang, L et al. (2017) Long noncoding RNA lncKdm2b is required for ILC3 maintenance by initiation of Zfp292 expression. Nature Immunology 18, 499508.CrossRefGoogle ScholarPubMed
Liu, J, Zhang, X, Chen, K et al. (2019a) CCR7 chemokine receptor-inducible lnc-Dpf3 restrains dendritic cell migration by inhibiting HIF-1α-mediated glycolysis. Immunity 50, .CrossRefGoogle ScholarPubMed
Liu, Y, Zhang, Q, Ding, Y et al. (2015) Histone lysine methyltransferase Ezh1 promotes TLR-triggered inflammatory cytokine production by suppressing Tollip. Journal of Immunology 194, 28382846.CrossRefGoogle ScholarPubMed
Li, D and Wu, M (2021) Pattern recognition receptors in health and diseases. Transduction and Targeted Therapy 6, .Google ScholarPubMed
Li, X, Wu, Z, Fu, X et al. (2014a) lncRNAs: Insights into their function and mechanics in underlying disorders. Mutation Research - Reviews in Mutation Research 762, 121.CrossRefGoogle ScholarPubMed
Li, Y, Xia, L, Tan, K et al. (2020c) N(6)-Methyladenosine co-transcriptionally directs the demethylation of histone H3K9me2. Nature Genetics 52, 870877.CrossRefGoogle ScholarPubMed
Li, Z, Xu, Q, Huangfu, N et al. (2022b) Mettl3 promotes oxLDL-mediated inflammation through activating STAT1 signaling. Journal of Clinical Laboratory Analysis 36, .Google ScholarPubMed
Li, X, Ye, Y, Peng, K et al. (2022a) Histones: The critical players in innate immunity. Frontiers in Immunology 13, .Google ScholarPubMed
Li, X, Zhang, Y, Pei, W et al. (2020b) LncRNA Dnmt3aos regulates Dnmt3a expression leading to aberrant DNA methylation in macrophage polarization. FASEB Journal 34, 50775091.CrossRefGoogle ScholarPubMed
Locati, M, Curtale, G and Mantovani, A (2020) Diversity, mechanisms, and significance of macrophage plasticity. Annual Review of Pathology 15, 123147.CrossRefGoogle ScholarPubMed
Luo, S, Liao, C, Zhang, L et al. (2023) METTL3-mediated m6A mRNA methylation regulates neutrophil activation through targeting TLR4 signaling. Cell Reports 42, .CrossRefGoogle ScholarPubMed
Lutz, PE, Chay, MA, Pacis, A et al. (2021) Non-CG methylation and multiple histone profiles associate child abuse with immune and small GTPase dysregulation. Nature Communications 12, .CrossRefGoogle ScholarPubMed
Lyko, F (2018) The DNA methyltransferase family: A versatile toolkit for epigenetic regulation. Nature Reviews Genetics 19, 8192.CrossRefGoogle Scholar
Lyu, W, Deng, Z and Zhang, G (2023) High-throughput screening for epigenetic compounds that induce human β-defensin 1 synthesis. Antibiotics 12, .CrossRefGoogle ScholarPubMed
Martins, R, Carlos, AR, Braza, F et al. (2019) Disease tolerance as an inherent component of immunity. Annual Review of Immunology 37, 405437.CrossRefGoogle Scholar
Ma, D, Zhou, X, Wang, Y et al. (2022) Changes in the small noncoding RNAome during M1 and M2 macrophage polarization. Frontiers in Immunology 13, .Google ScholarPubMed
McErlean, P, Bell, CG, Hewitt, RJ et al. (2021) DNA methylome alterations are associated with airway macrophage differentiation and phenotype during lung fibrosis. American Journal of Respiratory and Critical Care Medicine 204, 954966.CrossRefGoogle ScholarPubMed
Meyer, KD, Patil, DP, Zhou, J et al. (2015) 5′ UTR m(6)A promotes cap-independent translation. Cell 163, 9991010.CrossRefGoogle ScholarPubMed
Meyer, KD, Saletore, Y, Zumbo, P et al. (2012) Comprehensive analysis of mRNA methylation reveals enrichment in 3′ UTRs and near stop codons. Cell 149, 16351646.CrossRefGoogle ScholarPubMed
Michieletto, MF, Tello-Cajiao, JJ, Mowel, WK et al. (2023) Multiscale 3D genome organization underlies ILC2 ontogenesis and allergic airway inflammation. Nature Immunology 24, 4254.CrossRefGoogle ScholarPubMed
Mittelstaedt, NN, Becker, AL, de Freitas, DN et al. (2021) DNA methylation and immune memory response. Cells 10, .CrossRefGoogle ScholarPubMed
Mowel, WK, McCright, SJ, Kotzin, JJ et al. (2017) Group 1 innate lymphoid cell lineage identity is determined by a cis-regulatory element marked by a long non-coding RNA. Immunity 47, .CrossRefGoogle ScholarPubMed
Nandakumar, V, Chou, Y, Zang, L et al. (2013) Epigenetic control of natural killer cell maturation by histone H2A deubiquitinase, MYSM1. Proceedings of the National Academy of Sciences of the USA 110, E3927E3936.Google ScholarPubMed
Narlikar, GJ, Sundaramoorthy, R and Owen-Hughes, T (2013) Mechanisms and functions of ATP-dependent chromatin-remodeling enzymes. Cell 154, 490503.CrossRefGoogle ScholarPubMed
Nguyen, HCB, Adlanmerini, M, Hauck, AK et al. (2020) Dichotomous engagement of HDAC3 activity governs inflammatory responses. Nature 584, 286290.CrossRefGoogle ScholarPubMed
Niu, L, Lou, F, Sun, Y et al. (2020) A micropeptide encoded by lncRNA MIR155HG suppresses autoimmune inflammation via modulating antigen presentation. Science Advances 6, .CrossRefGoogle ScholarPubMed
Noh, YH, Lee, J, Seo, SJ et al. (2018) Promoter DNA methylation contributes to human β-defensin-1 deficiency in atopic dermatitis. Animal Cells and Systems 22, 172177.CrossRefGoogle ScholarPubMed
Ohl, L, Mohaupt, M, Czeloth, N et al. (2004) CCR7 governs skin dendritic cell migration under inflammatory and steady-state conditions. Immunity 21, 279288.CrossRefGoogle ScholarPubMed
Pacis, A, Mailhot-Léonard, F, Tailleux, L et al. (2019) Gene activation precedes DNA demethylation in response to infection in human dendritic cells. Proceedings of the National Academy of Sciences of the USA 116, 69386943.CrossRefGoogle ScholarPubMed
Pacis, A, Tailleux, L, Morin, AM et al. (2015) Bacterial infection remodels the DNA methylation landscape of human dendritic cells. Genome Research 25, 18011811.CrossRefGoogle ScholarPubMed
Pan, X-S, Li, B-W, Wang, L-L et al. (2023) Kupffer cell pyroptosis mediated by METTL3 contributes to the progression of alcoholic steatohepatitis. FASEB Journal 37, .CrossRefGoogle Scholar
Patel, U, Rajasingh, S, Samanta, S et al. (2017) Macrophage polarization in response to epigenetic modifiers during infection and inflammation. Drug Discovery Today 22, 186193.CrossRefGoogle ScholarPubMed
Patil, DP, Chen, CK, Pickering, BF et al. (2016) m(6)A RNA methylation promotes XIST-mediated transcriptional repression. Nature 537, .CrossRefGoogle ScholarPubMed
Paul, F and Amit, I (2014) Plasticity in the transcriptional and epigenetic circuits regulating dendritic cell lineage specification and function. Current Opinion in Immunology 30, 18.CrossRefGoogle ScholarPubMed
Pei, W, Zhang, Y, Li, X et al. (2020) LncRNA AK085865 depletion ameliorates asthmatic airway inflammation by modulating macrophage polarization. International Immunopharmacology 83, .CrossRefGoogle ScholarPubMed
Peng, K, Biao, C, Zhao, YY et al. (2023) Long non-coding RNA MM2P suppresses M1-polarized macrophages-mediated excessive inflammation to prevent sodium taurocholate-induced acute pancreatitis by blocking SHP2-mediated STAT3 dephosphorylation. Clinical and Experimental Medicine 23, 35893603.CrossRefGoogle ScholarPubMed
Pradeepa, MM, Grimes, GR, Kumar, Y et al. (2016) Histone H3 globular domain acetylation identifies a new class of enhancers. Nature Genetics 48, 681686.CrossRefGoogle ScholarPubMed
Qi, S, Li, Y, Dai, Z et al. (2019) Uhrf1-mediated Tnf-α gene methylation controls proinflammatory macrophages in experimental colitis resembling inflammatory bowel disease. Journal of Immunology 203, 30453053.CrossRefGoogle ScholarPubMed
Qin, Y, Li, B, Arumugam, S et al. (2021b) m(6)A mRNA methylation-directed myeloid cell activation controls progression of NAFLD and obesity. Cell Reports 37, .CrossRefGoogle ScholarPubMed
Qin, W, Scicluna, BP and van der Poll, T (2021a) The role of host cell DNA methylation in the immune response to bacterial infection. Frontiers in Immunology 12, .CrossRefGoogle ScholarPubMed
Qi, X, Wang, H, Xia, L et al. (2021) miR-30b-5p releases HMGB1 via UBE2D2/KAT2B/HMGB1 pathway to promote pro-inflammatory polarization and recruitment of macrophages. Atherosclerosis 324, 3845.CrossRefGoogle ScholarPubMed
Ranzani, V, Rossetti, G, Panzeri, I et al. (2015) The long intergenic noncoding RNA landscape of human lymphocytes highlights the regulation of T cell differentiation by linc-MAF-4. Nature Immunology 16, 318325.CrossRefGoogle Scholar
Riquelme-Barrios, S, Pereira-Montecinos, C, Valiente-Echeverria, F et al. (2018) Emerging roles of N-6-methyladenosine on HIV-1 RNA metabolism and viral replication. Frontiers in Microbiology 8, .Google Scholar
Rodríguez-Carlos, A, Jacobo-Delgado, YM, Santos-Mena, AO et al. (2021) Modulation of cathelicidin and defensins by histone deacetylase inhibitors: A potential treatment for multi-drug resistant infectious diseases. Peptides 140, .CrossRefGoogle ScholarPubMed
Rodríguez-Ubreva, J, Ciudad, L, Gómez-Cabrero, D et al. (2012) Pre-B cell to macrophage transdifferentiation without significant promoter DNA methylation changes. Nucleic Acids Research 40, 19541968.CrossRefGoogle ScholarPubMed
Roquilly, A, Mintern, JD and Villadangos, JA (2022) Spatiotemporal adaptations of macrophage and dendritic cell development and function. Annual Review of Immunology 40, 525557.CrossRefGoogle Scholar
Rupani, H, Martinez-Nunez, RT, Dennison, P et al. (2016) Toll-like receptor 7 is reduced in severe asthma and linked to an altered MicroRNA profile. American Journal of Respiratory and Critical Care Medicine 194, 2637.CrossRefGoogle Scholar
Saeed, S, Quintin, J, Kerstens, HH et al. (2014) Epigenetic programming of monocyte-to-macrophage differentiation and trained innate immunity. Science 345, .CrossRefGoogle ScholarPubMed
Sakai, M, Troutman, TD, Seidman, JS et al. (2019) Liver-derived signals sequentially reprogram myeloid enhancers to initiate and maintain Kupffer cell identity. Immunity 51, .CrossRefGoogle ScholarPubMed
Schenk, A, Bloch, W and Zimmer, P (2016) Natural killer cells – An epigenetic perspective of development and regulation. International Journal of Molecular Sciences 17, .CrossRefGoogle ScholarPubMed
Schmidl, C, Delacher, M, Huehn, J et al. (2018) Epigenetic mechanisms regulating T-cell responses. Journal of Allergy and Clinical Immunology 142, 728743.CrossRefGoogle ScholarPubMed
Scholler, E, Weichmann, F, Treiber, T et al. (2018) Interactions, localization, and phosphorylation of the m(6)A generating METTL3-METTL14-WTAP complex. RNA 24, 499512.CrossRefGoogle Scholar
Schübeler, D (2015) Function and information content of DNA methylation. Nature 517, 321326.CrossRefGoogle ScholarPubMed
Schwartz, S, Mumbach, MR, Jovanovic, M et al. (2014) Perturbation of m6A writers reveals two distinct classes of mRNA methylation at internal and 5′ sites. Cell Reports 8, 284296.CrossRefGoogle ScholarPubMed
Seeley, JJ, Baker, RG, Mohamed, G et al. (2018) Induction of innate immune memory via microRNA targeting of chromatin remodelling factors. Nature 559, 114119.CrossRefGoogle ScholarPubMed
Sendinc, E and Shi, Y (2023) RNA m6A methylation across the transcriptome. Molecular Cell 83, 428441.CrossRefGoogle ScholarPubMed
Shi, Y, Li, J, Chen, H et al. (2022) Pharmacologic inhibition of histone deacetylase 6 prevents the progression of chlorhexidine gluconate-induced peritoneal fibrosis by blockade of M2 macrophage polarization. Frontiers in Immunology 13, .Google ScholarPubMed
Shi, H, Wang, X, Lu, Z et al. (2017) YTHDF3 facilitates translation and decay of N(6)-methyladenosine-modified RNA. Cell Research 27, 315328.CrossRefGoogle Scholar
Sica, A and Mantovani, A (2012) Macrophage plasticity and polarization: In vivo veritas. Journal of Clinical Investigation 122, 787795.CrossRefGoogle ScholarPubMed
Skvortsova, K, Iovino, N and Bogdanović, O (2018) Functions and mechanisms of epigenetic inheritance in animals. Nature Reviews Molecular Cell Biology 19, 774790.CrossRefGoogle ScholarPubMed
Søndergaard, JN, Poghosyan, S, Hontelez, S et al. (2015) DC-SCRIPT regulates IL-10 production in human dendritic cells by modulating NF-κBp65 activation. Journal of Immunology 195, 14981505.CrossRefGoogle Scholar
Spooner, CJ, Lesch, J, Yan, D et al. (2013) Specification of type 2 innate lymphocytes by the transcriptional determinant Gfi1. Nature Immunology 14, 12291236.CrossRefGoogle ScholarPubMed
Statello, L, Guo, CJ, Chen, LL et al. (2021) Gene regulation by long non-coding RNAs and its biological functions. Nature Reviews Molecular Cell Biology 22, 96118.CrossRefGoogle Scholar
Steinman, RM and Idoyaga, J (2010) Features of the dendritic cell lineage. Immunological Reviews 234, 517.CrossRefGoogle ScholarPubMed
Summers, AR, Fischer, MA, Stengel, KR et al. (2013) HDAC3 is essential for DNA replication in hematopoietic progenitor cells. Journal of Clinical Investigation 123, 31123123.CrossRefGoogle ScholarPubMed
Sun, Y, Chin, YE, Weisiger, E et al. (2009) Cutting edge: Negative regulation of dendritic cells through acetylation of the nonhistone protein STAT-3. Journal of Immunology 182, 58995903.CrossRefGoogle ScholarPubMed
Tan, J, Chen, F, Wang, J et al. (2024) ALKBH5 promotes the development of lung adenocarcinoma by regulating the polarization of M2 macrophages through CDCA4. Gene 895, .CrossRefGoogle ScholarPubMed
Tang, J, Wang, X, Xiao, D et al. (2023) The chromatin-associated RNAs in gene regulation and cancer. Molecular Cancer 22, .CrossRefGoogle ScholarPubMed
Tikhanovich, I, Zhao, J, Bridges, B et al. (2017) Arginine methylation regulates c-Myc-dependent transcription by altering promoter recruitment of the acetyltransferase p300. Journal of Biological Chemistry 292, 1333313344.CrossRefGoogle ScholarPubMed
Toki, S, Goleniewska, K, Reiss, S et al. (2016) The histone deacetylase inhibitor trichostatin A suppresses murine innate allergic inflammation by blocking group 2 innate lymphoid cell (ILC2) activation. Thorax 71, 633645.CrossRefGoogle ScholarPubMed
Tong, J, Wang, X, Liu, Y et al. (2021) Pooled CRISPR screening identifies m(6)A as a positive regulator of macrophage activation. Science Advances 7, .CrossRefGoogle ScholarPubMed
Tsioumpekou, M, Krijgsman, D, Leusen, JHW et al. (2023) The role of cytokines in neutrophil development, tissue homing, function and plasticity in health and disease. Cells 12, .CrossRefGoogle ScholarPubMed
Ulvmar, MH, Werth, K, Braun, A et al. (2014) The atypical chemokine receptor CCRL1 shapes functional CCL21 gradients in lymph nodes. Nature Immunology 15, 623630.CrossRefGoogle ScholarPubMed
Vento-Tormo, R, Company, C, Rodríguez-Ubreva, J et al. (2016) IL-4 orchestrates STAT6-mediated DNA demethylation leading to dendritic cell differentiation. Genome Biology 17, .CrossRefGoogle ScholarPubMed
Victor, AR, Weigel, C, Scoville, SD et al. (2018) Epigenetic and posttranscriptional regulation of CD16 expression during human NK cell development. Journal of Immunology 200, 565572.CrossRefGoogle ScholarPubMed
Wang, X, Cao, Q, Yu, L et al. (2016) Epigenetic regulation of macrophage polarization and inflammation by DNA methylation in obesity. JCI Insight 1, .CrossRefGoogle ScholarPubMed
Wang, X, Ding, Y, Li, R et al. (2023) N(6)-methyladenosine of Spi2a attenuates inflammation and sepsis-associated myocardial dysfunction in mice. Nature Communications 14, .Google ScholarPubMed
Wang, H, Hu, X, Huang, M et al. (2019) Mettl3-mediated mRNA m(6)A methylation promotes dendritic cell activation. Nature Communications 10, .Google ScholarPubMed
Wang, G, Li, Y, Yang, G et al. (2021) Cathelicidin antimicrobial peptide (CAMP) gene promoter methylation induces chondrocyte apoptosis. Human Genomics 15, .CrossRefGoogle ScholarPubMed
Wang, X, Lu, ZK, Gomez, A et al. (2014b) N-6-methyladenosine-dependent regulation of messenger RNA stability. Nature 505, 117120.CrossRefGoogle Scholar
Wang, P, Xue, Y, Han, Y et al. (2014a) The STAT3-binding long noncoding RNA lnc-DC controls human dendritic cell differentiation. Science 344, 310313.CrossRefGoogle ScholarPubMed
Wang, P, Xu, J, Wang, Y et al. (2017) An interferon-independent lncRNA promotes viral replication by modulating cellular metabolism. Science 358, 10511055.CrossRefGoogle ScholarPubMed
Wang, X, Zhao, BS, Roundtree, IA et al. (2015) N-6-methyladenosine modulates messenger RNA translation efficiency. Cell 161, 13881399.CrossRefGoogle ScholarPubMed
Won, H, Nandakumar, V, Yates, P et al. (2014) Epigenetic control of dendritic cell development and fate determination of common myeloid progenitor by Mysm1. Blood 124, 26472656.CrossRefGoogle ScholarPubMed
Worbs, T, Hammerschmidt, SI and Förster, R (2017) Dendritic cell migration in health and disease. Nature Reviews Immunology 17, 3048.CrossRefGoogle ScholarPubMed
Wu, H and Zhang, Y (2011) Mechanisms and functions of Tet protein-mediated 5-methylcytosine oxidation. Genes and Development 25, 24362452.CrossRefGoogle ScholarPubMed
Xiao, Y, Zhao, C, Tai, Y et al. (2023) STING mediates hepatocyte pyroptosis in liver fibrosis by epigenetically activating the NLRP3 inflammasome. Redox Biology 62, .CrossRefGoogle ScholarPubMed
Xiao, CL, Zhu, S, He, M et al. (2018) N(6)-methyladenine DNA modification in the human genome. Molecular Cell 71, .CrossRefGoogle ScholarPubMed
Xin, J, Li, J, Feng, Y et al. (2017) Downregulation of long noncoding RNA HOTAIRM1 promotes monocyte/dendritic cell differentiation through competitively binding to endogenous miR-3960. Oncotargets and Therapy 10, 13071315.CrossRefGoogle ScholarPubMed
Xu, W, He, C, Kaye, EG et al. (2022b) Dynamic control of chromatin-associated m(6)A methylation regulates nascent RNA synthesis. Molecular Cell 82, .CrossRefGoogle ScholarPubMed
Xu, W, Li, J, He, C et al. (2021) METTL3 regulates heterochromatin in mouse embryonic stem cells. Nature 591, 317321.CrossRefGoogle ScholarPubMed
Xu, H, Li, Z, Kuo, CC et al. (2023) A lncRNA identifies Irf8 enhancer element in negative feedback control of dendritic cell differentiation. Elife 12, .CrossRefGoogle ScholarPubMed
Xu, J, Liu, LY, Zhi, FJ et al. (2024) DDX5 inhibits inflammation by modulating m6A levels of TLR2/4 transcripts during bacterial infection. EMBO Reports 25(2), 770795.CrossRefGoogle ScholarPubMed
Xu, C, Wang, X, Liu, K et al. (2014) Structural basis for selective binding of m6A RNA by the YTHDC1 YTH domain. Nature Chemical Biology 10, 927929.CrossRefGoogle ScholarPubMed
Xu, -J-J, Zhu, L, Li, H-D et al. (2022a) DNMT3a-mediated methylation of PSTPIP2 enhances inflammation in alcohol-induced liver injury via regulating STAT1 and NF-κB pathway. Pharmacological Research 177, .CrossRefGoogle ScholarPubMed
Yagi, R, Zhong, C, Northrup, DL et al. (2014) The transcription factor GATA3 is critical for the development of all IL-7Rα-expressing innate lymphoid cells. Immunity 40, 378388.CrossRefGoogle ScholarPubMed
Yang, L, Jia, R, Ge, T et al. (2022) Extrachromosomal circular DNA: Biogenesis, structure, functions and diseases. Signal Transduction and Targeted Therapy 7, .CrossRefGoogle ScholarPubMed
Yang, X, Wang, X, Liu, D et al. (2014) Epigenetic regulation of macrophage polarization by DNA methyltransferase 3b. Molecular Endocrinology 28, 565574.CrossRefGoogle ScholarPubMed
Yang, Q, Wei, J, Zhong, L et al. (2015) Cross talk between histone deacetylase 4 and STAT6 in the transcriptional regulation of arginase 1 during mouse dendritic cell differentiation. Molecular and Cellular Biology 35, 6375.CrossRefGoogle ScholarPubMed
Yang, J, Xu, J, Wang, W et al. (2023) Epigenetic regulation in the tumor microenvironment: Molecular mechanisms and therapeutic targets. Signal Transduction and Targeted Therapy 8, .CrossRefGoogle ScholarPubMed
Yan, B, Xie, S, Liu, Z et al. (2014) HDAC6 deacetylase activity is critical for lipopolysaccharide-induced activation of macrophages. PLoS One 9, .CrossRefGoogle ScholarPubMed
Yao, QJ, Sang, LN, Lin, MH et al. (2018) Mettl3-Mettl14 methyltransferase complex regulates the quiescence of adult hematopoietic stem cells. Cell Research 28, 952954.CrossRefGoogle ScholarPubMed
Yin, R, Chang, J, Li, Y et al. (2022) Differential m6A RNA landscapes across hematopoiesis reveal a role for IGF2BP2 in preserving hematopoietic stem cell function. Cell Stem Cell 29, .CrossRefGoogle ScholarPubMed
Yin, Y, Morgunova, E, Jolma, A et al. (2017) Impact of cytosine methylation on DNA binding specificities of human transcription factors. Science 356, .CrossRefGoogle ScholarPubMed
Yuan, J, Zhu, Q, Zhang, X et al. (2022) Ezh2 competes with p53 to license lncRNA Neat1 transcription for inflammasome activation. Cell Death and Differentiation 29, 20092023.CrossRefGoogle ScholarPubMed
Yu, JT, Hu, XW, Chen, HY et al. (2021) DNA methylation of FTO promotes renal inflammation by enhancing m(6)A of PPAR-α in alcohol-induced kidney injury. Pharmacological Research 163, .CrossRefGoogle ScholarPubMed
Yu, J, Qiu, Y, Yang, J et al. (2016) DNMT1-PPARγ pathway in macrophages regulates chronic inflammation and atherosclerosis development in mice. Scientific Reports 6, .Google ScholarPubMed
Zhang, Y and Cao, X (2016) Long noncoding RNAs in innate immunity. Cellular and Molecular Immunology 13, 138147.CrossRefGoogle ScholarPubMed
Zhang, Q and Cao, X (2021) Epigenetic remodeling in innate immunity and inflammation. Annual Review of Immunology 39, 279311.CrossRefGoogle ScholarPubMed
Zhang, Y, Gao, Y, Jiang, Y et al. (2023a) Histone demethylase KDM5B licenses macrophage-mediated inflammatory responses by repressing Nfkbia transcription. Cell Death and Differentiation 30, 12791292.CrossRefGoogle ScholarPubMed
Zhang, X, He, D, Xiang, Y et al. (2022) DYSF promotes monocyte activation in atherosclerotic cardiovascular disease as a DNA methylation-driven gene. Translational Research 247, 1938.CrossRefGoogle ScholarPubMed
Zhang, Y, Li, H, Xiang, X et al. (2020) Identification of DNMT3B2 as the predominant isoform of DNMT3B in porcine alveolar macrophages and its involvement in LPS-stimulated TNF-α expression. Genes 11, .CrossRefGoogle Scholar
Zhang, Y, Wu, T, He, Z et al. (2023b) Regulation of pDC fate determination by histone deacetylase 3. Elife 12, .CrossRefGoogle ScholarPubMed
Zhang, Y, Zhang, W, Zhao, J et al. (2023c) m6A RNA modification regulates innate lymphoid cell responses in a lineage-specific manner. Nature Immunology 24, 12561264.CrossRefGoogle Scholar
Zhang, Q, Zhao, K, Shen, Q et al. (2015) Tet2 is required to resolve inflammation by recruiting Hdac2 to specifically repress IL-6. Nature 525, 389393.CrossRefGoogle ScholarPubMed
Zhao, Z, Su, Z, Liang, P et al. (2020) USP38 couples histone ubiquitination and methylation via KDM5B to resolve inflammation. Advanced Science 7, .Google ScholarPubMed
Zheng, GQ, Dahl, JA, Niu, YM et al. (2013) ALKBH5 is a mammalian RNA demethylase that impacts RNA metabolism and mouse fertility. Molecular Cell 49, 1829.CrossRefGoogle ScholarPubMed
Zheng, Q, Hou, J, Zhou, Y et al. (2017) The RNA helicase DDX46 inhibits innate immunity by entrapping m(6)A-demethylated antiviral transcripts in the nucleus. Nature Immunology 18, 10941103.CrossRefGoogle ScholarPubMed
Zheng, Y, Li, Y, Ran, X et al. (2022) Mettl14 mediates the inflammatory response of macrophages in atherosclerosis through the NF-κB/IL-6 signaling pathway. Cellular and Molecular Life Sciences 79, .CrossRefGoogle ScholarPubMed
Zhong, Y, Huang, T, Huang, J et al. (2023) The HDAC10 instructs macrophage M2 program via deacetylation of STAT3 and promotes allergic airway inflammation. Theranostics 13, 35683581.CrossRefGoogle ScholarPubMed
Zhong, C, Tao, B, Yang, F et al. (2021) Histone demethylase JMJD1C promotes the polarization of M1 macrophages to prevent glioma by upregulating miR-302a. Clinical and Translational Medicine 11, .CrossRefGoogle ScholarPubMed
Zhong, Y, Ye, P, Mei, Z et al. (2019) The novel methyltransferase SETD4 regulates TLR agonist-induced expression of cytokines through methylation of lysine 4 at histone 3 in macrophages. Molecular Immunology 114, 179188.CrossRefGoogle ScholarPubMed
Zhou, X, Chen, H, Shi, Y et al. (2023) Histone deacetylase 8 inhibition prevents the progression of peritoneal fibrosis by counteracting the epithelial-mesenchymal transition and blockade of M2 macrophage polarization. Frontiers in Immunology 14, .Google ScholarPubMed
Zhou, W, Wang, X, Chang, J et al. (2022) The molecular structure and biological functions of RNA methylation, with special emphasis on the roles of RNA methylation in autoimmune diseases. Critical Reviews in Clinical Laboratory Sciences 59, 203218.CrossRefGoogle ScholarPubMed
Zhou, D, Yang, K, Chen, L et al. (2017) Promising landscape for regulating macrophage polarization: Epigenetic viewpoint. Oncotarget 8, 5769357706.CrossRefGoogle ScholarPubMed
Zong, X, Wang, H, Xiao, X et al. (2021a) Enterotoxigenic Escherichia coli infection promotes enteric defensin expression via FOXO6-METTL3-m(6)A-GPR161 signalling axis. RNA Biology 18, 576586.CrossRefGoogle ScholarPubMed
Zong, X, Xiao, X, Jie, F et al. (2021b) YTHDF1 promotes NLRP3 translation to induce intestinal epithelial cell inflammatory injury during endotoxic shock. Science China Life Sciences 64, 19881991.CrossRefGoogle ScholarPubMed
Zong, X, Xiao, X, Shen, B et al. (2021c) The N6-methyladenosine RNA-binding protein YTHDF1 modulates the translation of TRAF6 to mediate the intestinal immune response. Nucleic Acids Research 49, 55375552.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Introduction to epigenetics. Notes: RNA methylation. RNA is transcribed from DNA and subsequently undergoes reversible methylation modifications catalyzed by METTL3/METTL14/WTAP and FTO/ALKBH5. RNA containing m6A modifications is recognized by reader proteins, mediating diverse biological functions. DNA methylation. Methylation modifications are written by the DNMTs family on gene promoters, enhancers, and gene bodies. These methylation modifications influence neighboring genes’ transcription or chromatin’s openness. ncRNAs. lncRNAs and miRNAs are transcribed from DNA. lncRNAs, classified according to their transcriptional sites, influence gene transcription, chromatin accessibility, and mRNA stability through various mechanisms. miRNAs primarily affect mRNA cleavage and translation. Histone modifications and 3D chromatin structure.

Figure 1

Table 1. Epigenomic techniques

Figure 2

Figure 2. The role of epigenetic modification in lineage development of macrophages. A. The role of H3K27ac and H3K4me3 in guiding monocyte-to-macrophage differentiation. B. Increased DNA methylation during monocyte-to-macrophage differentiation promotes the binding of TFs and active histone elements to relevant differentiation genes. C. Epigenetic patterns during pre-B cell-to-macrophage differentiation. D. Epigenetic characteristics and mechanisms underlying the differentiation of newly settled hepatic macrophages.

Figure 3

Figure 3. Epigenetic modifications and macrophage polarization. Notes: DNMT1- and DNMT3b-mediated DNA methylation favors M1 macrophage polarization, whereas DNMTS inhibitors-induced DNA demethylation typically promotes M2 macrophage polarization. HDAC3-mediated histone deacetylation commonly enhances M1 macrophage polarization, whereas HDAC1 and HDAC10-mediated histone deacetylation typically favors M2 macrophage polarization. SETDB1-mediated H3K9 methylation and KDM5B-mediated H3K4 methylation often promote M1 macrophage polarization, while JMJD3 and KDM6A-mediated H3K27 demethylation typically favors M2 macrophage polarization. METTL3/METTL14 and YTHDF1-mediated RNA m6A modification contributes to M1 macrophage polarization. Lnc-AAM, LncRNA-GAS5, and LncRNA-CCL2 enhance M1 macrophage polarization, while LncRNA-Dnmt3aos, LncRNA-AK085865, and LncRNA-NEAT1 promote M2 macrophage polarization.

Figure 4

Figure 4. Epigenetic mechanisms mediating PRRs transcription signaling. A. Bacterial infection activates TLR4, leading to the MyD88/TRIF-dependent pathway that promotes glucose metabolism and the production of CoA. This, in turn, regulates histone acetylation modifications, enhancing the transcription of immune response genes. B. The interplay between the pattern recognition receptor NLRP3 and epigenetic modifications.

Figure 5

Figure 5. Epigenetic mechanisms mediating posttranscriptional regulation of PRRs. Notes: Bacterial infection activates the NF-κB-p65 signaling pathway through TLR4, leading to the transcription of Tlr4, Tlr2, Traf6, and nlrp3 genes. Subsequently, these Tlr4, Tlr2, Traf6, and nlrp3 RNAs are recognized by DDX60, which recruits METTL3 to promote their m6A modification. Under the influence of YTHDF1, this modification enhances their translation in ribosomes. This process subsequently triggers a positive feedback loop that regulates the expression of TLR4 and NLRP3.

Figure 6

Figure 6. Epigenetic mechanisms mediating the transcription of innate immune factors. A. Lnc-IL7-AS and H3K27ac in the regulation of Il6 transcription. B. ASH11-mediated H3K4me regulation of Il6 and Tnf-α transcription. C. TET2 and HDAC2 in regulation of Il6 transcription via H3K27ac. D. Histone acetylation levels on AMPs gene loci correlate positively with AMP transcription. E. DNA methylation levels at AMPs promoters correlate negatively with AMP transcription.