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Vitamin D supplementation and immune-related markers: an update from nutrigenetic and nutrigenomic studies

Published online by Cambridge University Press:  12 October 2022

Anto Cordelia Tanislaus Antony Dhanapal
Affiliation:
Centre for Biomedical and Nutrition Research, Department of Chemical Science, Universiti Tunku Abdul Rahman, Kampar, Malaysia
Karani Santhanakrishnan Vimaleswaran*
Affiliation:
Hugh Sinclair Unit of Human Nutrition, Department of Food and Nutritional Sciences, University of Reading, Reading RG6 6DZ, UK The Institute for Food, Nutrition, and Health (IFNH), University of Reading, Reading, UK
*
*Corresponding author: Vimaleswaran Karani Santhanakrishnan, email [email protected]
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Abstract

Vitamin D is both a nutrient and a neurologic hormone that plays a critical role in modulating immune responses. While low levels of vitamin D are associated with increased susceptibility to infections and immune-related disorders, vitamin D supplementation has demonstrated immunomodulatory effects that can be protective against various diseases and infections. Vitamin D receptor is expressed in immune cells that have the ability to synthesise the active vitamin D metabolite. Thus, vitamin D acts in an autocrine manner in a local immunologic milieu in fighting against infections. Nutrigenetics and nutrigenomics are the new disciplines of nutritional science that explore the interaction between nutrients and genes using distinct approaches to decipher the mechanisms by which nutrients can influence disease development. Though molecular and observational studies have proved the immunomodulatory effects of vitamin D, only very few studies have documented the molecular insights of vitamin D supplementation. Until recently, researchers have investigated only a few selected genes involved in the vitamin D metabolic pathway that may influence the response to vitamin D supplementation and possibly disease risk. This review summarises the impact of vitamin D supplementation on immune markers from nutrigenetics and nutrigenomics perspective based on evidence collected through a structured search using PubMed, EMBASE, Science Direct and Web of Science. The research gaps and shortcomings from the existing data and future research direction of vitamin D supplementation on various immune-related disorders are discussed.

Type
Horizons in Nutritional Science
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), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

One billion people worldwide are estimated to have insufficient vitamin D levels mainly due to less exposure to sunlight and poor vitamin D dietary intake. Vitamin D3 is a secosteroid synthesised when 7-dehydrocholesterol is exposed to UV-B via a non-enzymatic reaction(Reference Yaqinuddin, Ambia and Alaujan1). The surge in the cases of COVID-19 with the evolution of different variants necessitates the need to treat and prevent disease escalation. Vitamin D is considered one of the inexpensive and low-risk molecules that elicit an immune-regulating response. Vitamin D obtained either endogenously or from the diet must be activated before eliciting a response(Reference Aranow, Kamen and Dall’Era2). Vitamin D3 exerts gene regulation after hydroxylation reaction by the enzyme 1-α-hydroxylase (CYP27B1) that forms 1α,25-dihydroxy vitamin D3 (1,25(OH)2D3), which is metabolically active and regulates many bodily functions, including the regulation of the immune system. The enzyme 24 hydroxylase (CYP24A1) further metabolises it to the inactive 1,24,25 OHD. The active 1,25(OH)2D3 is tightly regulated by a negative feedback mechanism to prevent excessive vitamin D signalling by inhibiting renal 1-α-hydroxylase and stimulating the 24-hydroxylase enzymes, thereby it helps to maintain the circulating levels of serum 25-hydroxyvitamin D (25OHD)(Reference Carsten3,Reference Bikle4) . In the intestine, it stimulates calcium reabsorption and promotes osteoblast differentiation in bone matrix. The active 1,25(OH)2D3 binds to the vitamin D receptor (VDR) to exert this effect, and this active hormone–VDR complex further dimerises with the retinoid X receptor and forms 1,25(OH)2D3-VDR-retinoid X receptor heterodimer that translocate to the nucleus. There it binds with vitamin D responsive elements at the promoter region and stimulate the expression of the vitamin D-responsive genes. In this way, it signals both innate (antigen and antimicrobial action) and adaptive immunity (T and B lymphocyte activity) and prevents infectious and autoimmune disorders(Reference Bikle and Bouillon5).

Several autoimmune diseases (multiple sclerosis; rheumatoid arthritis; type 1 diabetes; inflammatory bowel disease; systemic lupus erythematosus (SLE)) have been linked to vitamin D deficiency(Reference Grant, Baggerly and Lahore6) and suggested to be one of the reasons for increased vulnerability towards the recent coronavirus (COVID-19) outbreak, particularly among the elderly people(Reference Chun, Liu and Modlin7). Studies have shown that 10–25 μg of vitamin D supplementation per day offers modest protection against acute respiratory infections(Reference Vimaleswaran, Forouhi and Khunti8), and vitamin D supplementation could play an active part in reducing the synthesis of pro-inflammatory cytokines, amplifying the expression of anti-inflammatory cytokines and increasing the expression of antioxidant genes(Reference Jakovac9).

Nutrigenetics and nutrigenomics emerged as new disciplines only a few decades ago and aims to explore the nutrient–gene interactions using distinct approaches to study the mechanism through which diet can influence disease development(Reference Trujillo, Davis and Milner10,Reference Berry, Vimaleswaran and Whittaker11) . While nutrigenetics explores the coordination between the genetic make-up of an individual in response to diet, considering the underlying genetic polymorphisms, nutrigenomics examines nutrition-responsive genome activity(Reference Alathari, Sabta and Kalpana12,Reference Raqib and Cravioto13) . Though many observational studies have been reported on nutrigenetic and nutrigenomic facets of vitamin D, based on epigenome and transcriptome-wide interaction in in vitro human cell lines, to date, very few studies have documented the effect of vitamin D supplementation on gene expression and immune health in human samples.

Furthermore, vitamin D supplementation and its ramifications on immune markers have always been a subject of debate, with contradictory findings and study design flaws that impede conclusive findings. This can be attributed to poor choice of vitamin D metabolite, the dosage levels, inadequate vitamin D status, frequency of intervention and little or no impact observed with high-dose supplementation on healthy individuals. Hence, the current article aims to discuss the impact of vitamin D supplementation on immune function from a nutrigenetics and nutrigenomics perspective based on evidence from population-based randomised controlled trials and epidemiological studies. Also, the future directions of vitamin D supplementation–gene interaction on immune responses in optimising health and disease treatment are also discussed.

Data sources and search strategies

A scrupulous literature search was done using the electronic databases including PubMed, NCBI, EMBASE, Science Direct and Web of Science databases to extract all eligible articles from inception to March 2022. The investigation was not discriminated by the date of publication. Available clinical studies published in English that utilised human participants and examined the effect of interaction between vitamin D-related gene polymorphisms, vitamin D supplementation on immune-related outcomes (i.e. nutrigenetics) and the impact of vitamin D supplementation on the expression of immune-related genes were included in this review. There was no restriction on gender, age, ethnicity and study settings. All data were extracted and organised into tables that featured study design, sample population, intervention, control, duration of treatment, analysis and outcome of the study.

Search terms included variations of ‘vitamin D supplementation’, ‘immunity’, ‘inflammatory cytokines’, ‘vitamin D receptors’, ‘transcriptional regulation’, ‘adaptive immunity’, ‘innate immunity’, ‘transcriptional profiling’, ‘VDR gene polymorphisms’ combined with either ‘gene expression’ or ‘gene–diet interaction’. All the relevant keywords (MeSH/Entree terms) for these topics were pooled individually and searched in the databases. Later the individual searches were combined using the Boolean operator ‘AND’, and the integrated search was performed.

Summary of included studies

A total of forty unique articles (nutrigenetics-5; nutrigenomics-35) were identified that examined the effect of vitamin D supplementation on immune-related gene expression and investigated the interactions between vitamin D genes and vitamin D supplementation on immunity (Fig. 1). PubMed search yielded twenty-four relevant articles, whereas EMBASE retrieved ten, Science Direct yielded four, while Web of Science and Medline yielded one article each. Study participants included new-borns, children, adults, elderly people and pregnant women. Both healthy volunteers and patients with diseases were part of the study population.

Fig. 1. Flow diagram of the search strategy and selection of articles for the review.

Vitamin D intervention and immune response – evidence from nutrigenetic studies

Genetic epidemiological studies link molecular insights with epidemiological data that have enthused researchers in the past decade. The variations in DNA sequence that commonly occur in populations are generally termed as ‘polymorphisms’ and can provide true biological effects(Reference Vimaleswaran, Power and Hyppönen14,Reference Alathari, Bodhini and Jayashri15) . Their plenitude presence at the human genome and high frequencies in the human population have targeted them to explore variations in common disease risks. Although studies have reported many polymorphisms to occur in the VDR gene(Reference Uitterlinden, Fang and van Meurs16), their influence on VDR protein function and signalling is still under research. Until recently, BsmI (rs1544410), ApaI (rs7975232) and TaqI (rs731236) polymorphisms at the 3’end of the VDR gene have been studied more frequently(Reference Vimaleswaran, Berry and Lu17Reference Mohseni, Amani and Hosseini19). The search yielded only five nutrigenetics studies with three of the five studies reported in the Middle East population and one each from South America and Europe (online Supplementary Table 1).

Based on the evidence from Iranian population, diabetic patients (n 140), with VDR FokI (rs2228570) ff genotype, showed a lower response to circulating 25OHD levels, serum high-sensitive CRP and IL6, when supplemented with 500 ml yogurt drink (doogh) fortified with 1000 µg vitamin D3 for 12 weeks, and no significant changes in the serum MMP-9, TNFα and IFNγ levels(Reference Shab-Bidar, Neyestani and Djazayery18). On the other hand, women with breast cancer (n 28) with TaqI TT/Tt, FokI Ff genotype were more responsive to vitamin D supplementation than those with the FokI FF/ff and TaqI tt genotypes(Reference Mohseni, Amani and Hosseini19) when supplemented with a high dose (50 000 µg of vitamin D weekly for eight weeks) and significantly increased the serum concentration of 25OHD and improved the total antioxidant capacity. Another study on breast cancer patients (N 214) with haplotype containing Cdx2 G FokI f, and BsmI b genotypes decreased the expression of MMP9 with a low dose (4000 µg of vitamin D3 per day for 12 weeks) of vitamin D3 supplementation(Reference Kazemian, Akbari and Moradi20).

In one study, vitamin D insufficient elderly Brazilian patients (n 40) with BsmI (rs1544410) BB/Bb genotype were more responsive to a vitamin D3 megadose (200 000 µg of vitamin D3) than the BsmI bb genotype and improved the circulating 25(OH)D, parathyroid hormone, ultra-sensitive-CRP and alpha-1-acid glycoprotein levels(Reference de Medeiros Cavalcante, Silva and Costa21). In the UK, a multicentre randomised controlled trial (n 20) on pulmonary TB and positive sputum smear patients, participants with the TaqI tt genotype of the TaqI VDR polymorphism had significantly faster sputum culture conversion and increased serum 25OHD concentrations compared with those with FokI genotype suggesting that those with TaqI tt genotype may derive clinical benefit through vitamin D supplementation(Reference Martineau, Timms and Bothamley22). Individual differences in response to vitamin D supplementation could be explained by epigenetic modifications and genetic diversity(Reference Cho, Myung and Cho23,Reference Vimaleswaran24) . The ability of the individual to transform vitamin D to its active metabolites and the interaction of vitamin D3 with its receptors could also possibly influence individual differences to vitamin D supplementation(Reference Bouillon25). Therefore, assessing the changes in epigenetic status and their respective expression of genes in immune cells may help to classify individuals as weak or strong responders to vitamin D supplementation. Unravelling the inter-relationships among gene, gene products and vitamin D are key to identifying the individuals who can be benefitted most from the vitamin D intervention strategies.

Nutrigenetic studies that probed the molecular insights of vitamin D supplementation were sparse. This creates a void in nutrigenetics research on vitamin D supplementation and immune responses with respect to study population (especially among the Asian and African nations), ethnicities, different disease states and limited longitudinal studies. This warrants for the attention of future researchers to address the missing gaps. The limitations seen were the relatively small number of SNP studied (< 30), which are not representative of a huge fraction of variation in the vitamin D pathway genes. More research is required to clearly understand the mechanism of how genetic variation and epigenetic events alter the requirements for vitamin D and their responses by expanding the metabolomics research through profiling the products of vitamin D metabolism using blood or urine samples. Also, a smaller sample size in these investigations resulted in lower study power, and a shorter supplementation duration is insufficient to conclude the outcomes of vitamin D3 supplementation trials. These factors must be considered while designing clinical trials in the future.

Vitamin D intervention and immune responses – evidence from nutrigenomic studies

Numerous studies and meta-analyses have highlighted the role of vitamin D in preventing disease risk and promoting longevity(Reference Cho, Myung and Cho23,Reference Bouillon25) . However, the beneficial outcomes of vitamin D supplementation have always been under speculation based on the reports from clinical trials that challenge the non-skeletal health benefits of vitamin D as well as the detrimental changes that accompany high-dose vitamin D supplementation on bone health. It has been hypothesised that epigenetic and individual genetic differences also interfere with response to supplementation(Reference Alathari, Bodhini and Jayashri15,Reference Shirvani, Kalajian and Song26) . Based on the evidence from thirty-five vitamin D supplementation trials that involved a nutrigenomics approach, 51 % of the studies were from the USA, followed by the Europe and the Middle East with 17 % each, respectively. Only 3 % of the studies were contributed each by Asia and Australia, respectively, while none were reported across African nations. This highlights the lack of diversity and shortfall in this research area especially among lower middle-income countries that calls for the attention and action by the researchers to undertake vitamin D supplementation trials.

The summary of findings is illustrated in Fig. 3 (online Supplementary Table 2 and Supplementary Fig. 1). Existing evidence is discussed under three main categories that appraise the outcomes of vitamin D supplementation on immune-related markers from a nutrigenomics perspective. These include (1) the vitamin D status (sufficiency/insufficiency /deficiency) based on the circulating levels of vitamin D3; (2) time and dose-dependent variation and (3) choice of vitamin D supplement (vitamin D2/D3 or combination with other food or drugs).

Fig. 2. Summary of vitamin D supplementation trials and immune health from nutrigenetics perspective across different geographic terrain, ethnicities and diseased and healthy states. VDR, vitamin D receptor; SNP, single nucleotide polymorphism; us-CRP, ultra-sensitive C-reactive protein; AGP-A, alpha-1-acid glycoprotein; Cdx2, caudal-type homeobox 2; MMP9, matrix metalloproteinase 9; TNFα, tumour necrosis factor alpha; TB, tuberculosis; OS, oxidative stress; TAC, total antioxidant capacity.

Fig. 3. Summary of vitamin D supplementation trials and outcomes on immune health from a nutrigenomics perspective. Vitamin D3, cholecalciferol; NS, not significant; CBMC, cord-blood mononuclear cells; PBMC, peripheral blood mononuclear cells; TLR2, toll like receptor 2; TLR9, toll-like receptor 9; ILT3, immunoglobulin-like transcript 3; Th1, type 1 T-helper cells; Th2, type 2 T-helper cells; S100A9, S100 calcium-binding protein A9; LCN2, lipocalin-2; DEFB4, Beta Defensin 4; RSAD2, Radical S-adenosyl methionine domain containing 2; LPS, lipopolysaccharide; VEGF, vascular endothelial growth factor; ALOX12, arachidonate 12-lipoxygenase; ISG15, interferon-stimulated gene 15; RSAD2, radical S-adenosyl methionine domain containing 2; FLG, filaggrin; CCL8-C-C, motif chemokine ligand 8; CXCL11, C-X-C motif chemokine ligand 11; RPTN, repetin; HIST1H2B, histone H2B type 1-B; JUN, Jun Proto-Oncogene; NFKB, nuclear factor kappa B; HSPA8, heat shock protein family A (Hsp70) member 8; EIF4A, eukaryotic translation initiation factor 4A1; PRS, prieto X-linked mental retardation syndrome; TRIM27, tripartite motif containing 27; CD83, cluster of differentiation 83; COPB2, COPI coat complex subunit beta 2; YRNA, non-coding ribonucleic acids; CETN3, centrin 3; LRRN3, leucine rich repeat neuronal 3; PLCγ1, phospholipase Cγ1; TGF-β1, transforming growth factor beta 1; HLA–A, human leukocyte antigen-A; HLA–C, human leukocyte antigen-C; IFN-γ, interferon gamma; PKC, protein kinase C; MAPK1, mitogen-activated protein kinase 1; Mtb, Mycobacterium tuberculosis.

Influence of baseline vitamin D status on vitamin D supplementation outcomes in clinical disorders

Vitamin D deficiency impedes the health of women of all ages across the globe(Reference Aji, Erwinda and Rasyid27). Epidemiological studies focusing on the impact of vitamin D supplementation on gene expression among women are limited to establishing the role of vitamin D on gene expression and immune health. In the PASTURE study(Reference Rochat, Ege and Plabst28) (n 349), maternal vitamin D supplementation (Finland: 10 µg of vitamin D/day and France: a single parental dose of 2500 µg at seventh month of gestation) showed an increase in the gene expression levels of ILT3 and ILT4 in cord blood, which were the two hallmarks of tolerogenic dendritic cells that inhibit NF-kB activation. Similarly, in the VDAART study(Reference Hornsby, Pfeffer and Laranjo29), mothers supplemented with 4000 µg/d of vitamin D3 showed an increase in the levels of many pro-inflammatory cytokines (GM-CSF, IFN-γ, IL-1β, IL-6 and IL-8) and gene expression levels of TLR2 and TLR9 (Reference Hornsby, Pfeffer and Laranjo29) compared to the 400 µg/d group in the cord blood samples of neonates. The same study also reported that women with low vitamin D status developed preeclampsia in the early gestation stage compared with the vitamin D replete women(Reference Mirzakhani, Litonjua and McElrath30). These studies highlight that maternal vitamin D supplementation may induce an early tolerogenic immune response, boost the immune system of neonates and protect them from asthma-related morbidities. In addition, these studies highlight the importance of maternal vitamin D status that can influence transcriptional profiles that might contribute to fetal immune imprinting and offer protection against allergic sensitisation in early life(Reference Al-Garawi, Carey and Chhabra31).

Elderly women with vitamin D insufficient status (n 19) administered with 50 000 µg of vitamin D/biweekly for 5 weeks failed to improve the circulating levels of hCAP in vivo (Reference de Medeiros Cavalcante, Silva and Costa21), while similar dosage but longer supplementation duration (3 months) in 100 vitamin D-deficient Middle Eastern women downregulated pro-inflammatory pathways by altering TLR4/CD14 and IFN receptor levels and regulated NF-kB pathways that support an innate-modulated inhibition of adaptive immunity with increase in the vitamin D3 levels(Reference Martineau, Timms and Bothamley22). A pilot study in the USA on vitamin D deficient (n 4) and vitamin D insufficient or sufficient (n 4) subjects supplemented with 400 µgs (n 3) or 2000 µgs (n 5) of vitamin D3 daily for 2 months showed that even a slightest improvement in vitamin D status has a profound impact on the expression of genes, linked to over 160 pathways that modulate diseases associated with vitamin D deficiency(Reference Hossein-nezhad, Spira and Holick32). Vitamin D deficient/insufficient SLE patients in Malta (n 31) supplemented with 8000 µg of vitamin D daily for 8 weeks and 8000 µg daily for 4 weeks, respectively, showed improvement in SLE disease activity(Reference Magro, Saliba and Camilleri33) A lower dosage (4000 µg of vitamin D3 daily for 12 weeks) showed contradictory result in another group of vitamin D-deficient SLE patients (n 19)(Reference Aranow, Kamen and Dall’Era2) where vitamin D supplementation failed to reduce the IFN signature. It has been postulated that to suppress the expression of the IFN signature-related genes and to improve disease activity, it requires higher serum 25OHD levels that remain stable for a longer time. The possible mechanism could be that vitamin D supplements may help to reduce the release of pro-inflammatory cytokines, amplify the expression of anti-inflammatory genes and enhance the gene expression involved with the antioxidant system(Reference Shirvani-Farsani34). It has been shown that correction of vitamin D deficiency in SLE patients suppresses the expression of genes in the interferon pathway, resulting in an improvement in SLE disease activity(Reference Naghavi Gargari, Behmanesh and Shirvani Farsani35). Given the evidence that correcting circulating vitamin D levels may improve disease activity in short term, future studies should address the effect of long-term vitamin D supplementation for a better understanding on the clinical and immune-related outcomes.

Time and dose-dependent variation on vitamin D supplementation outcomes

The vitamin D requirement and optimum serum vitamin D levels to prevent disease are always a topic of scientific debate worldwide. The Institute of Medicine recommends a daily intake of 600 µg of vitamin D per day for children and adults of Canada and USA and 800 µg for older adults(36). Some organisations such as the Endocrine Society recommend a daily intake of 1500 to 2000 µg to meet the optimum serum levels of vitamin D. In contrary, intakes of 10 mcg (400 µg)/d are recommended by the UK government for its citizens aged 4 years and above(37). Vitamin D levels rise in response to increased vitamin D intake, in a nonlinear relationship(Reference Bouillon38). However, the amount of increase depends on the baseline serum levels and supplementation period.

ODIN Junior study on healthy white children aged 4–8 years (n 119) reported that a high-dose winter vitamin D3 supplementation of 20 µg/d maintained the ability to produce calprotectin (S100A9) and LPS-induced IL-8 in healthy children, while low dose (10 µg/d) did not have an impact on innate immune markers(Reference Hauger, Ritz and Mortensen39). In another study, a dose of 1000 µg/d oral cholecalciferol syrup significantly increased VDR mRNA expression in asthmatic Egyptian children (n 29)(Reference Ramadan, Sallam and Elsheikh40). In addition, regular intake of vitamin D supplements among the asthmatic patients increased the serum 25OHD followed by a decrease of VDR mRNA expression(Reference Ramadan, Sallam and Elsheikh40,Reference Vimaleswaran, Cavadino and Hyppönen41) which was also observed in cancer(Reference Choi, Yi and Lee42) and multiple sclerosis patients(Reference Shirvani-Farsani, Kakhki and Gargari43,Reference Gombash, Lee and Sawdai44) . The plausible reason for the increase in 25OHD followed by a reduced VDR expression could be that 25OHD arbitrates the binding of VDR-retinoid X receptor to the promoter sequence of CYP24A1 gene that degrades 25OHD as a negative feedback mechanism(Reference Sadeghi, Taheri and Sajjadi45). Children with atopic dermatitis (n 57) administered with 1000 µg/d (25 g/d) of vitamin D for three months showed an increase in the 25OHD values and a decrease in the expression of IL-2, IL-4, IL-6 and IFN-γ. This study showed that a dose of 1000 µg/d was sufficient to reduce atopic dermatitis severity in children and normalise Th1 and Th2 interleukin serum patterns, thus making it an effective treatment for atopic dermatitis(Reference Di Filippo, Scaparrotta and Rapino46).

A dose of 2000 µg of vitamin D3/day failed to express VDR, CYP19A1, PPARG, MCP 1 and ADIPOQ genes that are involved in pathways linking vitamin D status, adiposity and breast cancer risk in postmenopausal women of non-Hispanic origin(Reference Mason, Wang and Duggan47). Elderly population (Caucasians, n 305(Reference Berlanga-Taylor, Plant and Dahl48); Americans, n 30(Reference Pojednic, Ceglia and Lichtenstein49)) supplemented with 4000 µg daily for 12 and 16 weeks, respectively, neither had an effect on gene expression (IL-6 or TNF) nor on plasma concentrations of selected cytokines (IFN-γ, IL-10, IL-8, IL-6 and TNF)(Reference Pojednic, Ceglia and Lichtenstein49), while contradictory result was observed in a Columbian cohort where short-term supplementation (1·5 weeks) with the same dosage increased VDR and VDR target genes (CYP24A1 and CAMP) with a significant decrease in TLR and CAMP mRNA(Reference Giraldo, Cardona and Urcuqui-Inchima50). Meanwhile, a very high dose of 50 000 µg resulted in the expression of fifty-four differentially expressed genes in Middle Eastern women (n 100)(Reference Garand, Toufiq and Singh51) and upregulated IFN-α response, IFN-γ response in US population(Reference Ponda, Liang and Kim52). Same dosage administered to women of Hispanic/non-Hispanic whites/non-Hispanic blacks (n 20) found a marked decrease in interferon-stimulated gene 15 (ISG15), while no significant expression was seen with VDR, ALOX12, ISG15, RSAD2, IL8, FLG, CCL8, CXCL11, RPTN genes (Reference Anderson, Thurman and Chandra53). Same dose on relapsing and remitting multiple sclerosis patients (n 31)(Reference Shirvani-Farsani34) significantly upregulated TGF-β2 mRNA expression in the PBMC similar to those reported in other studies(Reference Hahn, Cook and Alexander54Reference Inoue, Aoi and Yamauchi56). Yet, some studies reported no significant effect of vitamin D supplementation in multiple sclerosis patients(Reference Gombash, Lee and Sawdai44,Reference Sadeghi, Taheri and Sajjadi45,Reference Muris, Smolders and Rolf57Reference Murdaca, Tonacci and Negrini59) showing mixed results.

A high or low dose of vitamin D supplementation did not have any impact on gene expression in type 1 diabetes mellitus patients irrespective of ethnicity. Moreover, vitamin D did not defend against the decline of β-cell function, and neither the insulin requirement nor the metabolic control improved after diabetes onset. These findings did not support the use of vitamin D to treat adult patients with type 1 diabetes(Reference Bizzarri, Pitocco and Napoli60Reference Wehr, Trummer and Giuliani62). However. long-term intervention (144–240 weeks) of 20000 µg weakly to pre-diabetes patients downregulated FPR2, CD52 IL1R2, GNG10 and folate FOLR3 and upregulated RPS26 in a Norwegian cohort (n 47)(Reference Pasing, Fenton and Jorde63) On the other hand, ulcerative colitis patients (n 90) in Iran administered with 300 000 µg intramuscular vitamin D decreased ESR and high-sensitivity CRP levels and increased the expression of LL37 supporting the beneficial role in UC patient(Reference Sharifi, Hosseinzadeh-Attar and Vahedi64). A multi-centre study in Japan(Reference Kondo, Kato and Kimura65) on chronic hepatitis C (CH-C) patients (n 18) found that cytokine IP-10 significantly decreased after 4 weeks of 1,25(OH)2D3 (1 µg/d) treatment and were able to repress the basal levels of the immune markers in the CH-C patients. This indicates that calcitriol could possibly stabilise the adaptive immune systems that were out of normal range in CH-C patients(Reference Kondo, Kato and Kimura65).

In HIV-infected patients, a high-dose cholecalciferol (25 000 µg weekly) increased CCR10 gene expression levels and reduced CCR4 expression level of skin-homing markers, while a low dose (800 µg/d) failed to produce any immunomodulatory effects(Reference Ponda, Liang and Kim52). In contrast, 7000 µg of vitamin D3 significantly increased CAMP expression after 52 weeks and promoted antibacterial immunity in HIV-positive adolescents and young adults (n 48)(Reference Gerke, Pezzulo and Tang66). Supplementing 1000 µg/d did not find any significant changes in alveolar macrophage gene expression in a study on healthy US adults (n 28)(Reference Vargas Buonfiglio, Cano and Pezzulo67), while it increased airway surface liquid antimicrobial activity and gene expression of cathelicidin antimicrobial peptide in the same population(Reference Vargas Buonfiglio, Cano and Pezzulo67).

The optimum dose of vitamin D supplementation to elicit a therapeutic effect has often been the subject of debate in the recent years. Vitamin D dietary guidelines suggest a minimum requirement of 600 µg/d to maximise muscle function and bone health(Reference Ross, Manson and Abrams68). However, achieving and maintaining the circulating 25OHD levels above 30 ng/ml require a minimum of 1500–2000 µg/d. Moreover, obesity and certain disease conditions demand more than the recommended dose to maintain the 25OHD levels(Reference Ross, Manson and Abrams68Reference Dimitrakopoulou and Tsilidis70). Studies have reported that individuals with normal or near-normal levels of 25OHD, who received vitamin D supplementation above the daily requirements, did not exhibit physiological benefits(Reference Bouillon38). In contrary, a high-dose vitamin D supplementation has been proved effective in many clinical conditions(Reference Heaney, Recker and Grote71Reference Armas, Hollis and Heaney73). To have a conclusive decision, more data are required to prove that higher dose have better implications and the outcome of vitamin D supplementation depends on the baseline vitamin D levels and post-supplementation status. One of the important caveats in vitamin D supplementation is the risk that accompanies excessive vitamin D substitution, which may cause renal failure and cardiac arrest due to hypercalcemia. The upper tolerable intake limit in adults is set at 4000 µg/d (100 µg/d)(Reference Bouillon74), beyond which there seems to be no additional health benefit(37). Hence, while implementing high-dose vitamin D supplementation, these health impacts should also be given due consideration especially among kidney and heart patients.

Choice of vitamin D supplementation influences expression of immune markers

Although vitamin D2 (ergocalciferol) and vitamin D3 (cholecalciferol) are structurally similar (but not identical), their functional equivalence in effecting human health has been subjected to argument in recent years with conflicting evidence reported in the literature(Reference Holick, Biancuzzo and Chen75). A study published in 2017(Reference Tripkovic, Wilson and Hart72) states that vitamin D3 increased the serum 25OHD levels compared with vitamin D2. In addition, the study proved that a 12-week intervention of vitamin D2 decreased the circulating levels of serum 1,25(OH)2D3 compared with the placebo. This decline in 1,25(OH)2D3 has been noted in several other intervention trials supplemented with vitamin D2(Reference Armas, Hollis and Heaney73,Reference Logan, Gray and Peddie76) . Many studies have also reported the beneficial effect of vitamin D3 in multi-ethnic population(Reference Heaney, Recker and Grote71,Reference Tripkovic, Wilson and Hart72,Reference Tjellesen, Hummer and Christiansen77Reference Lehmann, Hirche and Stangl79) . The findings from the vitamin D2–D3 study revealed that only 13 % of down-regulated differentially expressed genes (102 of 774) were identical between the vitamin D2 and D3 treatment groups in contrast to 28 % (216 of 774) and 59 % (456 of 774) uniquely down-regulated by vitamin D2 and vitamin D3. In addition, the vitamin D3 supplemented group showed enhanced expression of genes involved in the interferon α response, which plays a critical part in combating bacterial and viral infections. Vitamin D2 supplemented group showed the opposite effect with no stimulatory effect of genes linked to interferon activity(Reference Durrant, Bucca and Hesketh80). However, given that the study population was restricted to only white European ethnicity, these findings cannot be generalised.

Apart from vitamin D2 and D3, certain studies also explored the synergistic effect of vitamin D supplementation together with food or a combination of drugs on immune response. One such study (n 30)(Reference Jamilian, Samimi and Mirhosseini81) reported that co-supplementation of vitamin D and n-3 fatty acid (50 000 µg vitamin D/2 weeks + 2000 mg/d n-3 fatty acid from fish oil) significantly downregulated interleukin-1 and upregulated vascular endothelial growth factor (VEGF) supporting the anti-inflammatory and immunomodulatory activities of combined supplementation. Another study in a Bangladeshi population (n 15) found that oral vitamin D supplement (5000 µg vitamin D3 for eight days) co-supplemented with 500 mg phenyl butyrate produced a synergistic effect in inducing LL-37 and caused intracellular death of Mycobacterium tuberculosis (Mtb) by the macrophages(Reference Mily, Rekha and Kamal82). This suggests it as a potential application in treating tuberculosis. However, further studies with a larger sample size are required to confirm the antimicrobial effect of vitamin D supplementation on lung infections.

Crohn’s disease patients (n 9) in Denmark, supplemented with vitamin D (30 μg vitamin D3 daily for 1 year) along with 1200 mg Ca daily, reduced activation-induced VDR up-regulation in CD4 + T cells(Reference Bendix, Dige and Deleuran83). Another study on subjects (n 10) with modestly increased risk of colorectal cancer supplemented with westernised diet and 1,25(OH)2D3 (0·5 μg/d) for four weeks, significantly upregulated genes that modulate immune response and inflammation pathways(Reference Protiva, Pendyala and Nelson84). Hence, future research can consider co-supplementation trials to further explore the synergistic effect of vitamin D with other drugs for better immunomodulatory effects.

Nutrigenetics and nutrigenomics of vitamin D supplementation – translating evidence to practice

To date, the role of vitamin D in immune health has extended far beyond its function in bone health both in terms of basic research on gene expression as well as human trials. Though evidence has shown the effect of vitamin D on immune-related gene expression, deducing the mechanistic pathways linking vitamin D and disease is still under investigation. The current epidemiological findings can only be used to improve the vitamin D levels or correct vitamin D insufficiency. There is scarcity in quality data representing wider coverage of population, larger sample size and longitudinal studies to translate data into disease prevention and practice. This will require well-designed human trials suitable to the target population, novel and appropriate experimental approaches involving nutrigenetics, nutrigenomics and nutriepigenetics and breakthrough technologies in the vitamin D research. It is imperative to identify genetic factors that predispose the vitamin D insufficient/deficient individuals to a suboptimal vitamin D status and must be considered in future research undertakings. Investigation of the common genetic variants in vitamin D-related genes is important to distinguish population at risk for vitamin D deficiency. Furthermore, it may also enhance our understanding on heritable component of circulating vitamin D levels and its association with several diseases. Therefore, screening individuals with a high genetic risk of vitamin D deficiency may offer preventive application of personalised nutritional guidelines to foster individual vitamin D status, and thereby improve vitamin D status of the population.

Prioritising steps to intensify research on vitamin D–gene interactions and immune health

In the milieu of limited data and competing demands to address the vitamin D–gene interactions on immune health, the evidence for the highly compelling mechanistic role of vitamin D in signalling immune system is deemed essential. Addressing the methodological challenges and uncertainties connected with vitamin D intervention should be given top priority to build sustainable nutrition solutions in the future. While developed countries are advancing towards personalised nutrition using nutritional genomics approach, it remains under explored in most of the middle-income and lower middle-income countries. Affordability to the high throughput analysis, lack of trained and skilled personnel in this newly emerged discipline, equality and ethical concerns impede research concerning this area. Cost-effective analysis, strengthening knowledge and skills in conducting nutrigenetics and nutrigenomics research, appropriate clinical designs for vitamin D intervention and wider coverage of multi-ethnic population may help to narrow down the research gaps and strengthen evidence for decision making. With over 1000 genes that are directly or indirectly regulated by 1,25OHD(Reference Wang, Vélez de-la-Paz and Zhai85), future research should henceforth focus on documenting more polymorphisms across different genes regulated by 1,25OHD to establish the functional consequences of the genetic variations. Substantial progress in this field would help to deepen our understanding of variability with respect to vitamin D endocrine system and may serve as an important health application in assessing disease risk and predicting response-to-treatment.

Another promising area is exploring the therapeutic effect of vitamin D supplementation on COVID-19 patients and documenting their immunologic response and disease outcomes. Even though observational studies support vitamin D supplementation in reducing the odds of getting respiratory tract infections, especially among vitamin D-deficient and insufficient groups, reports from randomised trials have shown mixed results that have further escalated the controversial discussion pertaining to COVID-19 and immune function. Though it is postulated that genetic susceptibility may have an impact on COVID-19 outcomes(Reference Alshahawey, Raslan and Sabri86), it is quite uncertain as to what degree these genetic factors may affect the highly affected groups despite existing genetic predisposition models and host genetic determinants(Reference Goyal, Reshetnyak and Khan87). By far, most of the vitamin D supplementation trials, both completed and ongoing in COVID-19 patients, have been used to assess the efficacy of supplementation in reducing the risk and severity of symptoms, and none of them have explored gene polymorphisms and genetic predisposition regarding COVID-19 which demand more studies in this area.

Key findings and limitations

The findings from the scientific evidence highlight some of the key factors that need attention and action in implementing nutrigenetics and nutrigenomics approach to vitamin D supplementation in immune health. The following are the salient findings:

  1. 1. Vitamin D supplementation has demonstrated multiple immunomodulating actions, and recent studies have focussed more on establishing the physiological connection of vitamin D-mediated immunity that has direct influence on gene regulation.

  2. 2. It is evident that vitamin D supports the capability of macrophages to mature and reduces expression of inflammatory cytokines and chemokines at large that exemplifies the action of vitamin D in eliminating pathogens parallel to suppressing the potential damage caused by prolonged infection.

  3. 3. Vitamin D deficiency is widespread in the European population and North America, particularly among the elderly, which can be attributed to more than one factor, such as skin type/decreased dermal production, less sun exposure and reduced food intake rich in vitamin D3.

  4. 4. The immune-modulating function of genetic variants depend on the bioavailability of vitamin D. SNP can influence vitamin D levels, such as those in the GC gene that codes for the vitamin D-binding protein, which is linked to differential levels of circulating vitamin D. For instance, the rs7041 ‘C’ allele in GC, which is predominant in Caucasians, is linked to lower plasma 25OHD and elevated levels of vitamin D-binding protein in Europeans.

The limitations seen from the scientific reports are:

  1. 1. More than 50 % of nutrigenetic and nutrigenomic studies were performed among Caucasians and the whites and mainly those from the USA and other developed countries in Europe. Only a few studies were performed in Asian and African populations.

  2. 2. Lack of evidence on the replicability of vitamin D–genotype interactions on immune health in multiple ethnic groups.

  3. 3. Genetic makeup, seasonal variations, vitamin D status, physiologic and disease state, dosage levels, short-term intervention and small sample size are setbacks in drawing conclusions, and the findings cannot be extrapolated to the population at large.

  4. 4. The studies presented show mixed and controversial results that underpin the need for well-designed clinical trials to deduce the nutrigenetics and nutrigenomics aspects and strengthen data, especially in ‘omics research’ to redirect the focus on individual treatment rather than on population groups.

  5. 5. Movement control orders and the multitude of deaths due to COVID-19 halted research on COVID-19 patients and associations between vitamin D supplementation on immune markers to a greater extent.

However, translation of this nutrigenetics and nutrigenomics evidence into recommendations based on genotype is only feasible when the impact of genotype clearly overpowers the effect of lifestyle factors. Evidence-based research is the only stratagem that promises all data generated from nutrigenetics and nutrigenomics studies in relation to vitamin D supplementation are scrutinised before implementing personalised nutrition strategies (Fig. 4).

Fig. 4. Drawing conclusions based on evidence and future directions.

Conclusion and future guidance

The evidence presented above reiterates the mechanistic role of vitamin D in regulating the immune system. Though it is highly compelling, large-scale randomised controlled trials are deemed necessary to confirm whether maintaining vitamin D sufficiency can help reduce the incidence of infections and autoimmune diseases and their severity. Studies have shown contradicting results with the ‘dose-dependent’ effect that was observed for gene expression with some results suggesting ‘the higher the dose, the more genes were affected’, while some did not show any significant gene expression with higher dosage. Further evidence from literature clearly states that even a slightest improvement in vitamin D status will have a profound impact on gene expression that execute biological functions in greater than 160 pathways associated with vitamin D deficiency. Hence, more research is required to provide definitive answer.

This review also identified novel techniques in the analysis of vitamin D signalling through next-generation sequencing technologies in primary cells, such as PBMC, that helped generate a voluminous amount of data to understand the vitamin D-triggered epigenome and transcriptome target-specific cellular systems. According to the EMBASE, PubMed, Science Direct and other databases, the US and the UK account for the highest contribution with respect to vitamin D supplementation trials on the immune response from a nutrigenetic and nutrigenomics perspectives, while it remains underexplored in Asian, African and Latin American population. The present review warrants more convincing evidence about vitamin D supplementation, gene expression and immune response, which remains uncertain. We see this as the future dimension in this area, but we are still far from recommending vitamin D for specific treatment. In conclusion, scientific and technological advances in the field of Nutrigenomics and Nutrigenetics in the state of the immune system are of prime importance to promote optimal health, which might offer greater capacity to prevent infectious diseases and overpower them with lesser complications.

Acknowledgements

Prof. Karani S. Vimaleswaran acknowledges support from the British Nutrition Foundation and the Medical Research Council (grant # H5457400). Thanks to Dr Mudili Sivaprasad for his support in conducting the literature review.

None.

Conceived and designed the study: KSV. Data collection and organisation: KSV and ACTAD: wrote the first draft of the manuscript: ACTAD; contributed to the writing and critical review of manuscript: KSV. All authors contributed to and approved the final version of the manuscript.

The authors declare no conflicts of interest.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114522002392

References

Yaqinuddin, A, Ambia, AR & Alaujan, RA (2022) Immunomodulatory effects of vitamin D and vitamin C to improve immunity in COVID-19 patients. J Heal Allied Sci NU 12, 16.Google Scholar
Aranow, C, Kamen, DL, Dall’Era, M, et al. (2015) Randomized, double-blind, placebo-controlled trial of the effect of vitamin D3 on the interferon signature in patients with systemic lupus erythematosus. Arthritis Rheumatol 67, 18481857.CrossRefGoogle ScholarPubMed
Carsten, C (2014) Genome-wide (over)view on the actions of vitamin D. Front Physiol 5, 167.Google Scholar
Bikle, D (2009) Nonclassic actions of vitamin D. J Clin Endocrinol Metab 94, 2634.CrossRefGoogle ScholarPubMed
Bikle, DD & Bouillon, R (2018) Vitamin D and bone and beyond. Bone Reports 9, 120121.CrossRefGoogle ScholarPubMed
Grant, WB, Baggerly, CA & Lahore, H (2020) Reply: ‘Vitamin D supplementation in influenza and COVID-19 infections. Comment on: evidence that vitamin D supplementation could reduce risk of influenza and COVID-19 infections and deaths nutrients. Nutrients 12, 988.CrossRefGoogle ScholarPubMed
Chun, RF, Liu, PT, Modlin, RL, et al. (2014) Impact of vitamin D on immune function: lessons learned from genome-wide analysis. Front Physiol 5, 151.CrossRefGoogle ScholarPubMed
Vimaleswaran, KS, Forouhi, NG & Khunti, K (2021) Vitamin D and covid-19. BMJ 327, n544.CrossRefGoogle Scholar
Jakovac, H (2020) COVID-19 and vitamin D—is there a link and an opportunity for intervention? Am J Physiol Metab 318, E589E589.Google Scholar
Trujillo, E, Davis, C & Milner, J (2006) Nutrigenomics, proteomics, metabolomics, and the practice of dietetics. J Am Diet Assoc 106, 403413.CrossRefGoogle ScholarPubMed
Berry, DJ, Vimaleswaran, KS, Whittaker, JC, et al. (2012) Evaluation of genetic markers as instruments for Mendelian randomization studies on vitamin D. PLoS One 7, e37465.CrossRefGoogle ScholarPubMed
Alathari, BE, Sabta, AA, Kalpana, CA, et al. (2020) Vitamin D pathway-related gene polymorphisms and their association with metabolic diseases: a literature review. J Diabetes Metab Disord 19, 17011729.CrossRefGoogle ScholarPubMed
Raqib, R & Cravioto, A (2009) Nutrition, immunology, and genetics: future perspectives. Nutr Rev 67, S227S236.CrossRefGoogle ScholarPubMed
Vimaleswaran, KS, Power, C & Hyppönen, E (2014) Interaction between vitamin D receptor gene polymorphisms and 25-hydroxyvitamin D concentrations on metabolic and cardiovascular disease outcomes. Diabetes Metab 40, 386389.CrossRefGoogle ScholarPubMed
Alathari, BE, Bodhini, D, Jayashri, R, et al. (2020) A nutrigenetic approach to investigate the relationship between metabolic traits and vitamin D status in an Asian Indian population. Nutrients 12, 1357.CrossRefGoogle Scholar
Uitterlinden, AG, Fang, Y, van Meurs, JBJ, et al. (2004) Genetics and biology of vitamin D receptor polymorphisms. Gene 338, 143156.CrossRefGoogle ScholarPubMed
Vimaleswaran, KS, Berry, DJ, Lu, C, et al. (2013) Causal relationship between obesity and vitamin D status: bi-directional Mendelian randomization analysis of multiple cohorts. PLoS Med 10, e1001383.CrossRefGoogle ScholarPubMed
Shab-Bidar, S, Neyestani, TR & Djazayery, A (2015) The interactive effect of improvement of vitamin D status and VDR FokI variants on oxidative stress in type 2 diabetic subjects: a randomized controlled trial. Eur J Clin Nutr 69, 216222.CrossRefGoogle ScholarPubMed
Mohseni, H, Amani, R, Hosseini, SA, et al. (2019) Genetic variations in VDR could modulate the efficacy of vitamin D3 supplementation on inflammatory markers and total antioxidant capacity among breast cancer women: a randomized double blind controlled trial. Asian Pac J Cancer Prev 20, 20652072.CrossRefGoogle ScholarPubMed
Kazemian, E, Akbari, ME, Moradi, N, et al. (2019) Vitamin D receptor genetic variation and cancer biomarkers among breast cancer patients supplemented with vitamin D3: a single-arm non-randomized before and after trial. Nutrients 11, 1264.CrossRefGoogle ScholarPubMed
de Medeiros Cavalcante, IG, Silva, AS, Costa, MJ, et al. (2015) Effect of vitamin D3 supplementation and influence of BsmI polymorphism of the VDR gene of the inflammatory profile and oxidative stress in elderly women with vitamin D insufficiency. Exp Gerontol 66, 1016.CrossRefGoogle ScholarPubMed
Martineau, AR, Timms, PM, Bothamley, GH, et al. (2011) High-dose vitamin D3 during intensive-phase antimicrobial treatment of pulmonary tuberculosis: a double-blind randomised controlled trial. Lancet 377, 242250.CrossRefGoogle ScholarPubMed
Cho, H, Myung, S-K & Cho, H-E (2022) Efficacy of vitamin D supplements in treatment of acute respiratory infection: a meta-analysis for randomized controlled trials. Nutrients 14, 1144.CrossRefGoogle ScholarPubMed
Vimaleswaran, KS (2021) GeNuIne (gene–nutrient interactions) collaboration: towards implementing multi-ethnic population-based nutrigenetic studies of vitamin B12 and D deficiencies and metabolic diseases. Proc Nutr Soc 80, 435445.CrossRefGoogle Scholar
Bouillon, R (2017) Optimal vitamin D supplementation strategies. Endocrine 56, 225226.CrossRefGoogle ScholarPubMed
Shirvani, A, Kalajian, TA, Song, A, et al. (2019) Disassociation of Vitamin D’s calcemic activity and non-calcemic genomic activity and individual responsiveness: a randomized controlled double-blind clinical trial. Sci Rep 9, 17685.CrossRefGoogle ScholarPubMed
Aji, AS, Erwinda, E, Rasyid, R, et al. (2020) A genetic approach to study the relationship between maternal Vitamin D status and newborn anthropometry measurements: the Vitamin D pregnant mother (VDPM) cohort study. J Diabetes Metab Disord 19, 91103.CrossRefGoogle Scholar
Rochat, MK, Ege, MJ, Plabst, D, et al. (2009) Maternal vitamin D intake during pregnancy increases gene expression of ILT3 and ILT4 in cord blood. Clin Exp Allergy 40, 786794.CrossRefGoogle ScholarPubMed
Hornsby, E, Pfeffer, PE, Laranjo, N, et al. (2018) Vitamin D supplementation during pregnancy: effect on the neonatal immune system in a randomized controlled trial. J Allergy Clin Immunol 141, 269278.e1.CrossRefGoogle ScholarPubMed
Mirzakhani, H, Litonjua, AA, McElrath, TF, et al. (2016) Early pregnancy vitamin D status and risk of preeclampsia. J Clin Invest 126, 47024715.CrossRefGoogle ScholarPubMed
Al-Garawi, A, Carey, VJ, Chhabra, D, et al. (2016) The role of vitamin D in the transcriptional program of human pregnancy. PLoS One 11, e0163832.CrossRefGoogle ScholarPubMed
Hossein-nezhad, A, Spira, A & Holick, MF (2013) Influence of vitamin D status and vitamin D3 supplementation on genome wide expression of white blood cells: a randomized double-blind clinical trial. PLoS One 8, e58725.CrossRefGoogle ScholarPubMed
Magro, R, Saliba, C, Camilleri, L, et al. (2021) Vitamin D supplementation in systemic lupus erythematosus: relationship to disease activity, fatigue and the interferon signature gene expression. BMC Rheumatol 5, 53.CrossRefGoogle ScholarPubMed
Shirvani-Farsani, Z (2015) Vitamin D levels in multiple sclerosis patients: association with TGF-β2, TGF-βRI, and TGF-βRII expression. Life Sci 134, 6367.CrossRefGoogle ScholarPubMed
Naghavi Gargari, B, Behmanesh, M, Shirvani Farsani, Z, et al. (2015) Vitamin D supplementation up-regulates IL-6 and IL-17A gene expression in multiple sclerosis patients. Int Immunopharmacol 28, 414419.CrossRefGoogle ScholarPubMed
Institute of Medicine (US) Committee to Review Dietary Reference Intakes for Vitamin D (2010) Dietary Reference Intakes for Calcium and Vitamin D. Washington, DC: National Academies Press (US).Google Scholar
Scientific Advisory Committee on Nutrition (SCAN) (July 2016) Vitamin D and Health. https://www.gov.uk/government/groups/scientific-advisory-committee-on-nutrition (accessed November 2021).Google Scholar
Bouillon, R (2020) Safety of high-dose vitamin D supplementation. J Clin Endocrinol Metab 105, 12901291.CrossRefGoogle ScholarPubMed
Hauger, H, Ritz, C, Mortensen, C, et al. (2019) Winter cholecalciferol supplementation at 55°N has little effect on markers of innate immune defense in healthy children aged 4–8 years: a secondary analysis from a randomized controlled trial. Eur J Nutr 58, 14531462.CrossRefGoogle Scholar
Ramadan, A, Sallam, SF, Elsheikh, MS, et al. (2019) VDR gene expression in asthmatic children patients in relation to vitamin D status and supplementation. Gene Rep 15, 100387.CrossRefGoogle Scholar
Vimaleswaran, KS, Cavadino, A & Hyppönen, E (2012) Evidence for a genetic interaction in allergy-related responsiveness to vitamin D deficiency. Allergy 67, 10331040.CrossRefGoogle ScholarPubMed
Choi, JY, Yi, JW, Lee, JH, et al. (2017) VDR mRNA overexpression is associated with worse prognostic factors in papillary thyroid carcinoma. Endocr Connect 6, 172178.CrossRefGoogle ScholarPubMed
Shirvani-Farsani, Z, Kakhki, MP, Gargari, BN, et al. (2017) The expression of VDR mRNA but not NF-κB surprisingly decreased after vitamin D treatment in multiple sclerosis patients. Neurosci Lett 653, 258263.CrossRefGoogle Scholar
Gombash, SE, Lee, PW, Sawdai, E, et al. (2022) Vitamin D as a risk factor for multiple sclerosis: immunoregulatory or neuroprotective? Front Neurol 13, 796933.CrossRefGoogle ScholarPubMed
Sadeghi, H, Taheri, M, Sajjadi, E, et al. (2017) Vdr And Cyp24a1 expression analysis in Iranian relapsing-remitting multiple sclerosis patients. CELL J 19, 352360.Google ScholarPubMed
Di Filippo, P, Scaparrotta, A, Rapino, D, et al. (2015) Vitamin D supplementation modulates the immune system and improves atopic dermatitis in children. Int Arch Allergy Immunol 166, 9196.CrossRefGoogle ScholarPubMed
Mason, C, Wang, L, Duggan, C, et al. (2017) Gene expression in breast and adipose tissue after 12 months of weight loss and vitamin D supplementation in postmenopausal women. NPJ Breast Cancer 3, 15.CrossRefGoogle ScholarPubMed
Berlanga-Taylor, AJ, Plant, K, Dahl, A, et al. (2018) Genomic response to vitamin D supplementation in the setting of a randomized, placebo-controlled trial. EBioMedicine 31, 133142.CrossRefGoogle ScholarPubMed
Pojednic, RM, Ceglia, L, Lichtenstein, AH, et al. (2015) Vitamin D receptor protein is associated with interleukin-6 in human skeletal muscle. Endocrine 49, 512520.CrossRefGoogle ScholarPubMed
Giraldo, DM, Cardona, A & Urcuqui-Inchima, S (2018) High-dose of vitamin D supplement is associated with reduced susceptibility of monocyte-derived macrophages to dengue virus infection and pro-inflammatory cytokine production: an exploratory study. Clin Chim Acta 478, 140151.CrossRefGoogle ScholarPubMed
Garand, M, Toufiq, M, Singh, P, et al. (2021) Immunomodulatory effects of vitamin D supplementation in a deficient population. Int J Mol Sci 22, 5041.CrossRefGoogle Scholar
Ponda, MP, Liang, Y, Kim, J, et al. (2017) A randomized clinical trial in vitamin D-deficient adults comparing replenishment with oral vitamin D3 with narrow-band UV type. Am J Clin Nutr 105, 12301238.CrossRefGoogle ScholarPubMed
Anderson, SM, Thurman, AR, Chandra, N, et al. (2020) Vitamin D status impacts genital mucosal immunity and markers of HIV-1 susceptibility in women. Nutrients 12, 3176.CrossRefGoogle ScholarPubMed
Hahn, J, Cook, NR, Alexander, EK, et al. (2022) Vitamin D and marine n-3 fatty acid supplementation and incident autoimmune disease: VITAL randomized controlled trial. BMJ 376, e066452.CrossRefGoogle ScholarPubMed
Aoi, N, Inoue, K, Chikanishi, T, et al. (2012) 1α, 25-Dihydroxyvitamin D3 modulates the hair-inductive capacity of dermal papilla cells: therapeutic potential for hair regeneration. Stem Cells Transl Med 1, 615626.CrossRefGoogle ScholarPubMed
Inoue, K, Aoi, N, Yamauchi, Y, et al. (2009) TGF-beta is specifically expressed in human dermal papilla cells and modulates hair folliculogenesis. J Cell Mol Med 13, 46434656.CrossRefGoogle ScholarPubMed
Muris, A-H, Smolders, J, Rolf, L, et al. (2016) Immune regulatory effects of high dose vitamin D3 supplementation in a randomized controlled trial in relapsing remitting multiple sclerosis patients receiving IFNβ; the SOLARIUM study. J Neuroimmunol 300, 4756.CrossRefGoogle Scholar
Hupperts, R, Smolders, J, Vieth, R, et al. (2019) Randomized trial of daily high-dose vitamin D3 in patients with RRMS receiving subcutaneous interferon β-1a. Neurology 93, e1906e1916.Google ScholarPubMed
Murdaca, G, Tonacci, A, Negrini, S, et al. (2019) Emerging role of vitamin D in autoimmune diseases: an update on evidence and therapeutic implications. Autoimmun Rev 18, 102350.CrossRefGoogle ScholarPubMed
Bizzarri, C, Pitocco, D, Napoli, N, et al. (2010) No protective effect of calcitriol on β-Cell function in recent-onset type 1 diabetes. Diabetes Care 33, 19621963.CrossRefGoogle ScholarPubMed
Walter, M, Kaupper, T, Adler, K, et al. (2010) No effect of the 1α,25-dihydroxyvitamin D3 on β-cell residual function and insulin requirement in adults with new-onset type 1 diabetes. Diabetes Care 33, 14431448.CrossRefGoogle ScholarPubMed
Wehr, E, Trummer, O, Giuliani, A, et al. (2011) Vitamin D-associated polymorphisms are related to insulin resistance and vi-tamin D deficiency in polycystic ovary syndrome. Eur J Endocrinol 164, 741.CrossRefGoogle Scholar
Pasing, Y, Fenton, CG, Jorde, R, et al. (2017) Changes in the human transcriptome upon vitamin D supplementation. J Steroid Biochem Mol Biol 173, 9399.CrossRefGoogle ScholarPubMed
Sharifi, A, Hosseinzadeh-Attar, M, Vahedi, H, et al. (2016) A randomized controlled trial on the effect of vitamin D3 on inflammation and cathelicidin gene expression in ulcerative colitis patients. Saudi J Gastroenterol 22, 316.Google ScholarPubMed
Kondo, Y, Kato, T, Kimura, O, et al. (2013) 1(OH) vitamin D3 supplementation improves the sensitivity of the immune-response during Peg-IFN/RBV therapy in chronic hepatitis C patients-case controlled trial. PLoS One 8, e63672.CrossRefGoogle ScholarPubMed
Gerke, AK, Pezzulo, AA, Tang, F, et al. (2014) Effects of vitamin D supplementation on alveolar macrophage gene expression: preliminary results of a randomized, controlled trial. Multidiscip Respir Med 9, 18.CrossRefGoogle ScholarPubMed
Vargas Buonfiglio, LG, Cano, M, Pezzulo, AA, et al. (2017) Effect of vitamin D3 on the antimicrobial activity of human airway surface liquid: preliminary results of a randomised placebo-controlled double-blind trial. BMJ Open Respir Res 4, e000211.CrossRefGoogle ScholarPubMed
Ross, AC, Manson, JE, Abrams, SA, et al. (2011) The 2011 report on dietary reference intakes for calcium and vitamin D from the Institute of Medicine: what clinicians need to know. J Clin Endocrinol Metab 96, 5358.CrossRefGoogle ScholarPubMed
Isgin-Atici, K, Alathari, BE, Turan-Demirci, B, et al. (2022) Interaction between dietary fat intake and metabolic genetic risk score on 25-hydroxyvitamin d concentrations in a Turkish adult population. Nutrients 14, 382.CrossRefGoogle Scholar
Dimitrakopoulou, VI, Tsilidis, KK, et al. (2017) Circulating vitamin D concentration and risk of seven cancers: mendelian randomisation study. BMJ 359, j4761.CrossRefGoogle ScholarPubMed
Heaney, RP, Recker, RR, Grote, J, et al. (2011) Vitamin D3 is more potent than vitamin D2 in humans. J Clin Endocrinol Metab 96, E447E452.CrossRefGoogle ScholarPubMed
Tripkovic, L, Wilson, LR, Hart, K, et al. (2017) Daily supplementation with 15 μg vitamin D2 compared with vitamin D3 to increase wintertime 25-hydroxyvitamin D status in healthy South Asian and white European women: a 12-week randomized, placebo-controlled food-fortification trial. Am J Clin Nutr 106, 481490.CrossRefGoogle Scholar
Armas, LAG, Hollis, BW & Heaney, RP (2004) Vitamin D2 is much less effective than vitamin D3 in humans. J Clin Endocrinol Metab 89, 53875391.CrossRefGoogle ScholarPubMed
Bouillon, R (2017) Comparative analysis of nutritional guidelines for vitamin D. Nat Rev Endocrinol 13, 466479.CrossRefGoogle ScholarPubMed
Holick, MF, Biancuzzo, RM, Chen, TC, et al. (2008) Vitamin D2 is as effective as vitamin D3 in maintaining circulating concentrations of 25-hydroxyvitamin D. J Clin Endocrinol Metab 93, 677681.CrossRefGoogle ScholarPubMed
Logan, VF, Gray, AR, Peddie, MC, et al. (2013) Long-term vitamin D3 supplementation is more effective than vitamin D2 in maintaining serum 25-hydroxyvitamin D status over the winter months. Br J Nutr 109, 10821088.CrossRefGoogle ScholarPubMed
Tjellesen, L, Hummer, L, Christiansen, C, et al. (1986) Serum concentration of vitamin D metabolites during treatment with vitamin D2 and D3 in normal premenopausal women. Bone Miner 1, 407413.Google ScholarPubMed
Trang, HM, Cole, DEC, Rubin, LA, et al. (1998) Evidence that vitamin D3 increases serum 25-hydroxyvitamin D more efficiently than does vitamin D2. Am J Clin Nutr 68, 854858.CrossRefGoogle ScholarPubMed
Lehmann, U, Hirche, F, Stangl, GI, et al. (2013) Bioavailability of vitamin D2 and D3 in healthy volunteers, a randomized placebo-controlled trial. J Clin Endocrinol Metab 98, 43394345.CrossRefGoogle ScholarPubMed
Durrant, LR, Bucca, G, Hesketh, A, et al. (2022) Vitamins D2 and D3 have overlapping but different effects on the human immune system revealed through analysis of the blood transcriptome. Front Immunol 13, 790444.CrossRefGoogle ScholarPubMed
Jamilian, M, Samimi, M, Mirhosseini, N, et al. (2018) The influences of vitamin D and n-3 co-supplementation on clinical, metabolic and genetic parameters in women with polycystic ovary syndrome. J Affect Disord 238, 3238.CrossRefGoogle Scholar
Mily, A, Rekha, RS, Kamal, SMM, et al. (2013) Oral intake of phenylbutyrate with or without vitamin D3upregulates the cathelicidin LL-37 in human macrophages: a dose finding study for treatment of tuberculosis. BMC Pulm Med 13, 23.CrossRefGoogle ScholarPubMed
Bendix, M, Dige, A, Deleuran, B, et al. (2015) Flow cytometry detection of vitamin D receptor changes during vitamin D treatment in Crohn’s disease. Clin Exp Immunol 181, 1928.CrossRefGoogle ScholarPubMed
Protiva, P, Pendyala, S, Nelson, C, et al. (2016) Calcium and 1,25-dihydroxyvitamin D3 modulate genes of immune and inflammatory pathways in the human colon: a human crossover trial. Am J Clin Nutr 103, 12241231.CrossRefGoogle Scholar
Wang, D, Vélez de-la-Paz, OI, Zhai, JX, et al. (2013) Serum 25-hydroxyvitamin D and breast cancer risk: a meta-analysis of prospective studies. Tumor Biol 34, 35093517.CrossRefGoogle Scholar
Alshahawey, M, Raslan, M & Sabri, N (2020) Sex-mediated effects of ACE2 and TMPRSS2 on the incidence and severity of COVID-19; the need for genetic implementation. Curr Res Transl Med 68, 149150.CrossRefGoogle ScholarPubMed
Goyal, P, Reshetnyak, E, Khan, S, et al. (2021) Clinical Characteristics and Outcomes of Adults With a History of Heart Failure Hospitalized for COVID-19. Circ Hear Fail 14, e008354.Google ScholarPubMed
Figure 0

Fig. 1. Flow diagram of the search strategy and selection of articles for the review.

Figure 1

Fig. 2. Summary of vitamin D supplementation trials and immune health from nutrigenetics perspective across different geographic terrain, ethnicities and diseased and healthy states. VDR, vitamin D receptor; SNP, single nucleotide polymorphism; us-CRP, ultra-sensitive C-reactive protein; AGP-A, alpha-1-acid glycoprotein; Cdx2, caudal-type homeobox 2; MMP9, matrix metalloproteinase 9; TNFα, tumour necrosis factor alpha; TB, tuberculosis; OS, oxidative stress; TAC, total antioxidant capacity.

Figure 2

Fig. 3. Summary of vitamin D supplementation trials and outcomes on immune health from a nutrigenomics perspective. Vitamin D3, cholecalciferol; NS, not significant; CBMC, cord-blood mononuclear cells; PBMC, peripheral blood mononuclear cells; TLR2, toll like receptor 2; TLR9, toll-like receptor 9; ILT3, immunoglobulin-like transcript 3; Th1, type 1 T-helper cells; Th2, type 2 T-helper cells; S100A9, S100 calcium-binding protein A9; LCN2, lipocalin-2; DEFB4, Beta Defensin 4; RSAD2, Radical S-adenosyl methionine domain containing 2; LPS, lipopolysaccharide; VEGF, vascular endothelial growth factor; ALOX12, arachidonate 12-lipoxygenase; ISG15, interferon-stimulated gene 15; RSAD2, radical S-adenosyl methionine domain containing 2; FLG, filaggrin; CCL8-C-C, motif chemokine ligand 8; CXCL11, C-X-C motif chemokine ligand 11; RPTN, repetin; HIST1H2B, histone H2B type 1-B; JUN, Jun Proto-Oncogene; NFKB, nuclear factor kappa B; HSPA8, heat shock protein family A (Hsp70) member 8; EIF4A, eukaryotic translation initiation factor 4A1; PRS, prieto X-linked mental retardation syndrome; TRIM27, tripartite motif containing 27; CD83, cluster of differentiation 83; COPB2, COPI coat complex subunit beta 2; YRNA, non-coding ribonucleic acids; CETN3, centrin 3; LRRN3, leucine rich repeat neuronal 3; PLCγ1, phospholipase Cγ1; TGF-β1, transforming growth factor beta 1; HLA–A, human leukocyte antigen-A; HLA–C, human leukocyte antigen-C; IFN-γ, interferon gamma; PKC, protein kinase C; MAPK1, mitogen-activated protein kinase 1; Mtb, Mycobacterium tuberculosis.

Figure 3

Fig. 4. Drawing conclusions based on evidence and future directions.

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