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Identification of Philaster apodigitiformis in aquaculture and functional characterization of its β-PKA gene and expression analysis of infected Poecilia reticulata

Published online by Cambridge University Press:  12 February 2024

Chunyu Zhou
Affiliation:
Laboratory of Protozoology, Harbin Normal University, Harbin 150025, China
Lihui Liu
Affiliation:
Laboratory of Protozoology, Harbin Normal University, Harbin 150025, China
Mingyue Jiang
Affiliation:
Laboratory of Protozoology, Harbin Normal University, Harbin 150025, China
Li Wang
Affiliation:
Laboratory of Protozoology, Harbin Normal University, Harbin 150025, China
Xuming Pan*
Affiliation:
Laboratory of Protozoology, Harbin Normal University, Harbin 150025, China
*
Corresponding author: Xuming Pan; Email: [email protected]

Abstract

Cyclic adenosine monophosphate (cAMP)-dependent protein kinase A (PKA) is a distinctive member of the serine–threonine protein AGC kinase family and an effective kinase for cAMP signal transduction. In recent years, scuticociliate has caused a lot of losses in domestic fishery farming, therefore, we have carried out morphological and molecular biological studies. In this study, diseased guppies (Poecilia reticulata) were collected from an ornamental fish market, and scuticociliate Philaster apodigitiformis Miao et al., 2009 was isolated. In our prior transcriptome sequencing research, we discovered significant expression of the β-PKA gene in P. apodigitiformis during its infection process, leading us to speculate its involvement in pathogenesis. A complete sequence of the β-PKA gene was cloned, and quantified by quantitative reverse transcription-polymerase chain reaction to analyse or to evaluate the functional characteristics of the β-PKA gene. Morphological identification and phylogenetic analysis based on small subunit rRNA sequence, infection experiments and haematoxylin–eosin staining method were also carried out, in order to study the pathological characteristics and infection mechanism of scuticociliate. The present results showed that: (1) our results revealed that β-PKA is a crucial gene involved in P. apodigitiformis infection in guppies, and the findings provide valuable insights for future studies on scuticociliatosis; (2) we characterized a complete gene, β-PKA, that is generally expressed in parasitic organisms during infection stage and (3) the present study indicates that PKA plays a critical role in scuticociliate when infection occurs by controlling essential steps such as cell growth, development and regulating the activity of the sensory body structures and the irritability system.

Type
Research Article
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
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Ciliates which belong to the subclass Scuticociliatia are common in various ecosystems around the world (Thompson and Kaneshiro, Reference Thompson and Kaneshiro1968; Foissner and Wilbert, Reference Foissner and Wilbert1981; Cawthorn et al., Reference Cawthorn, Lynn, Despres, MacMillan, Maloney, Loughlin and Bayer1996; Lynn and Strüder-Kypke, Reference Lynn and Strüder-Kypke2005; Fan et al., Reference Fan, Hu, Al-Farraj S, Clamp and Song2011a, Reference Fan, Lin, Al-Rasheid, Al-Farraj, Warren and Song2011b). They have great species diversity and play different important roles in various ecosystems (Pan et al., Reference Pan, Bourland and Song2013a, Reference Pan, Gao, Liu, Fan, Warren and Song2013b; Castro et al., Reference Castro, Küppers, Schweikert, Harada and Paiva2014; Foissner et al., Reference Foissner, Jung, Filker, Rudolph and Stoeck2014). Many of them are pathogens of invertebrates and fish, which can cause widespread infection of animals in aquaculture, and even cause death in serious cases (Pérez-Uz and Song, Reference Pérez-Uz and Song1995; Song and Wilbert, Reference Song and Wilbert2002; Fan et al., Reference Fan, Miao, Al-Rasheid and Song2009, Reference Fan, Chen, Song, Al-Rasheid and Warren2010; Mallo et al., Reference Mallo, Lamas, Piazzon and Leiro2015).

Scuticociliatosis is caused by parasitic or concurrent parasitic ciliates (Noga, Reference Noga2010). It is responsible for serious economic losses in commercial fish farms worldwide. In northeastern China, freshwater fish farms are affected by frequent facultative parasitic scuticociliates. Previous studies show that protein kinase A (PKA) is a prominent member of the AGC kinase family. β-PKA controls a variety of cellular metabolism processes, including cell growth, gene expression and metabolism (Leroux et al., Reference Leroux, Schulze and Biondi2018; Kumar et al., Reference Kumar, Das, Sen, Abhishek, Shafi, Bamra, Kumar, Kumar, Kumar, Mukharjee, Dikhit, Pandey and Das2021). Therefore, β-PKA can play an important role in various infection and toxicological processes. However, there have been no studies on the role of the β-PKA gene in the process of infecting guppy fish by scuticociliate Philaster apodigitiformis Miao et al., Reference Miao, Wang, Li, Al-Rasheid and Song2009.

In this study, the occurrence of P. apodigitiformis outbreaks in Poecilia reticulata, alongside a molecular investigation of the β-PKA gene, revealed its pivotal role in P. apodigitiformis infection within P. reticulata. Identification of parasitic P. apodigitiformis by traditional morphological methods, haematoxylin–eosin staining and phylogenetic analyses based on the small subunit (SSU) rRNA gene and experimental infection methods were carried out to study its pathological characteristics and infection mechanism. In addition, the β-PKA gene of P. apodigitiformis was cloned, and its expression was validated by quantitative reverse transcription-polymerase chain reaction (qRT-PCR) after infestation.

Materials and methods

Ciliate isolation, cultivation and morphological identification

Diseased fish were selected from an ornamental fish market in Harbin, China, and immersed in sterilized water. Microscopic observation of the water after 1 day revealed the presence of ciliates, which indicated the presence of ciliates in the skin, mucus, gill surfaces and internal organs of the fish. The cells of P. apodigitiformis were isolated from infected live fish. A single ciliate was isolated under a dissecting microscope and cultured in sterile RM-9 medium in monoclonal form, maintained at 25°C. Additionally, a ciliate strain of P. apodigitiformis (ZCY-20220702) isolated and characterized from the protozoan cell bank of Harbin Normal University was used in the present study. Ciliates were identified by live and post-stained photographs.

Gene sequencing and phylogenetic analyses

A single cell of P. apodigitiformis from the clonal cultures (also established in sterile RM-9 culture medium in a sterile hood and maintained in Petri dishes) was isolated individually using a glass pipette and washed with distilled water. Genomic DNA was extracted from 5 cells using a DNeasy Blood & Tissue Kit (Qiagen, Hilden, Germany), following the manufacturer's instructions. The SSU rRNA gene was amplified with the primers 82F (5′-GAA ACT GCG AAT GGC TC-3′) and 18s-R (5′-TGA TCC TTC TGC AGG TTC ACC TAC-3′) (Medlin et al., Reference Medlin, Elwood, Stickel and Sogin1988). The typical amplification profile was programmed as follows: hold at 94°C for 5 min; 35 cycles of denaturation at 94°C for 1 min, annealing at 56°C for 2 min and extension at 72°C for 3 min; and a final hold at 72°C for 10 min. A purified PCR product was inserted into the pUCm-T vector and then sequenced. Bidirectional sequencing was performed at the Shanghai Sunny Biotechnology Company (Shanghai, China). The SSU rRNA gene sequences were compared with other related taxa sequences obtained from the GenBank database on NCBI using the MUSCLE package and were identified as P. apodigitiformis, and the newly sequenced SSU rRNA gene of the Harbin population differed from the sequences of previously isolated strains of Philaster species by 1–4 nucleotides. Resulting alignments were refined by trimming both ends using BioEdit 7.0.5.2 (Hall, Reference Hall1999). Bayesian inference (BI) analysis was carried out with MrBayes on XSEDE v3.2.6 (Ronquist and Huelsenbeck, Reference Ronquist and Huelsenbeck2003) on CIPRES Science Gateway (Miller et al., Reference Miller, Pfeiffer and Schwartz2010) using the GTR + I + G evolutionary model as the best-fit model selected by MrModeltest v.2 (Nylander, Reference Nylander2004) according to the Akaike information criterion (AIC), and the support value in BI is called ‘posterior probability’ (PP). A maximum-likelihood (ML) tree was constructed using RAxML-HPC2 v.8.2.10 (Stamatakis et al., Reference Stamatakis, Hoover and Rougemont2008) on the CIPRES Science Gateway (Miller et al., Reference Miller, Pfeiffer and Schwartz2010) with the optimal model GTR + I + G evolutionary model as the best model according to the AIC selected by the program Modeltest v.3.4 (Posada and Crandall, Reference Posada and Crandall1998). Node support came from 1000 bootstrap replicates. TreeView v.1.6.6 and MEGA v5 were used to visualize tree topologies.

Histopathology

To confirm the presence of the ciliates, organs and tissues including skin, gills, liver and skeletal muscle of diseased and healthy fish (control group) were isolated and fixed in Bouin's solution for 48 h and maintained in 70% alcohol for gross histopathological analysis. Fixed tissues of fish were sectioned to about 0.6 cm wide slices. Samples were dehydrated in an alcohol gradient, transferred to xylene, embedded in paraffin wax and sectioned at a thickness of 7 μm. Sections were then stained with haematoxylin–eosin and examined under a light microscope.

Experimental infection

In vivo infection experiments were conducted with P. reticulata. The average weight of P. reticulata individuals was 3 g and the average length was 4 cm. Fish (n = 140) were thoroughly examined to confirm that they were free of P. apodigitiformis or any other infective agent and cultured in indoor rectangular concrete tanks. The temperature of water was maintained at 25°C, and prior to the scratch, the infection group of fish were anaesthetized with MS-222. Infection by scratch was conducted in tanks containing 2 L of water, 20 fish per tank, in total 1 control and 3 repeats in experiment I, and 3 repeats in experiment II, respectively. For control (experiment II) and each infection groups, about 10 000 (20 mL × 500 ind. mL−1) cells of P. apodigitiformis were added to each tank. Control treatment in experiment I contained only fish, while control treatment in experiment II contained only P. apodigitiformis cells. In the cumulative infection study, the cumulative number of deaths was counted every day. Microscopic examination of wet mounts of skin, gills and internal organs was carried out 7 days post-infection for the cumulative infection study. The animal experiments were conducted following the Guide for the Care and Use of Laboratory Animals, and the protocol for which was approved by the Harbin Normal University.

RNA isolation, PCR amplification of the coding region of the PKA gene

Philaster apodigitiformis was cultured to a concentration of about 100 ind. mL−1. After enriched several times to obtain 100 μL of ciliate solution, RNA was extracted using a RNA Extraction Kit (TransGen Biotech, Beijing, China) according to the manufacturer's instructions, and the resulting RNA was reverse transcribed to cDNA using the Reverse Transcription Kit M-MLV reverse transcriptase (TaKaRa, China) according to the manufacturer's instructions. The β-PKA gene was amplified using PCR. PCR primers are listed in Table 1. PCR conditions were as follows: 3 min at 94°C, 2 cycles of 15 s at 95°C, 2 min at 52°C and 2 min at 72°C, 2 cycles of 15 s at 95°C, 2 min at 54°C and 2 min at 72°C, 35 cycles of 15 s at 95°C, 2 min at 58°C and 2 min at 72°C and 72°C for 10 min.

Table 1. Primer sequence and their applications

cDNA synthesis and 5′, 3′ RACE

The extracted RNA was reverse transcribed using the 3′-Full RACE Core Set with PrimeScriptRTase (TaKaRa, China) according to the manufacturer's instructions. The β-PKA gene was amplified using PCR. PCR primers are listed in Table 1. PCR contained reactions I and II. In PCR I, the DNA double helix is denatured, usually accomplished by heating the sample to a high temperature (around 94–98°C), which results in the separation of the double-stranded DNA into 2 single strands. In PCR II, the DNA polymerase extends the primers by adding nucleotides to produce a new complementary strand of DNA, and this process results in the synthesis of 2 new strands of DNA, each complementary to one of the original DNA strands. PCR I was performed as follows: 94°C for 5 min, 40 cycles (94°C for 30 s, 55.7°C for 30 s and 72°C for 60 s), and 72°C for 5 min in a 25 μL PCR volume. PCR II was performed as follows: 94°C for 5 min, 40 cycles (94°C for 30 s, 59.1°C for 30 s and 72°C for 60 s), and 72°C for 5 min in a 25 μL PCR volume.

Gene expression analysis by qRT-PCR

qRT-PCR was performed as described in previous studies. Briefly, after RNA isolation and reverse transcription, an UltraSYBR mixture (Beijing ComWin Biotechnology Co., Ltd, Beijing, China) was used, with a CFX96 multicolour real-time PCR detection system (Bio-Rad Laboratories, USA). The temperature was first maintained at 95°C for 30 s, followed by 40 PCR cycles at 95°C (15 s) and 60°C (1 min) to obtain a melting curve from 60 to 95°C. qRT-PCR data were analysed using β-actin as an internal reference gene, as described in our previous study. The primers used to detect the expression of the β-PKA and 18S rRNA (internal reference gene) genes are shown in Table 1. The 2−ΔΔCT method was used to calculate the relative expression of each gene.

Secondary structure analysis of β-PKA gene

The structure of PKA protein was predicted using Alphafold v2.2.0, and the results after plotting graphs with PyMOL follows the analysis of Wang et al. (Reference Wang, Chen, Ge, Wang and Mu2022).

Results

Pathological features and infectivity

Pathogenicity/histopathology

On first inspection the guppies did not have any apparent gross signs of scuticociliate infection. Nonetheless, the parasite was observed in fresh-mount preparations on the skin, in the gills and in internal organs. The diseased fish showed varying degrees of lesions including skin, eyes, caudal fins, spleen and liver. There were bleeding spots and black or grey lesions randomly distributed on the body surface of diseased fish (Fig. 1B and C; Table 2). The black or grey lesions were necrotic areas containing P. apodigitiformis Miao et al., Reference Miao, Wang, Li, Al-Rasheid and Song2009. Lesions caused by P. apodigitiformis destroying the fish fins and the regular fish were intact (Fig. 1A) but broken to varying degrees in diseased fish (Fig. 1C and D). Gills of all diseased fish were shrivelled, dark and anaemic, and several had dark-red ulcerations. Some cells of P. apodigitiformis were detected in gaps among the gill filaments. All the fish were examined histologically by haematoxylin–eosin staining. As shown in Fig. 2, the skeletal muscle, liver, gill and spleen of the fish were damaged to varying degrees. Scrapings of these lesions revealed the presence of P. apodigitiformis.

Figure 1. Pathological alterations in Poecilia reticulata: (A) a healthy P. reticulata individual; (B) a conspicuous bleeding spot directly above the fish's head; (C) highlights evident of bleeding spots within the abdominal cavity and (D) a visibly fractured and forked tail fin.

Table 2. Characterization of different groups of guppies infected by P. apodigitiformis (unit: ind.)

Figure 2. Histological sections of P. reticulata stained with haematoxylin–eosin: (A) deformed and disordered arrangement of muscle tissue (arrowheads), (B) disordered arrangement of liver tissue (arrowheads), (C) shrunken and deformed spleen tissue (arrowheads) and (D, E) shrunken and cracked gill filaments (arrowheads). Scale bar = 200 μm.

Description of morphology of P. apodigitiformis

Size in vivo about 40–60 × 15–25 μm2 (Fig. 3A–D; Table 3). Body shape elongate and tapering slightly towards anterior (Fig. 3A–D; Table 3). No apical plate. Buccal field extending to about 30% of body length, with shallow depression. Pellicle smooth, with bar-shaped, very fine, short (2 μm long) extrusomes. Cytoplasm colourless to greyish, containing several food vacuoles and bar- or dumbbell-like crystals (Fig. 3B–D; Table 3). Single macronucleus centrally located, spherical to ovoid. One contractile vacuole positioned caudally. Somatic cilia densely arranged, approximately 5 μm long; 1 caudal cilium about 10 μm in length (Fig. 3A, arrowhead; Table 3). Movement with no special features, swimming moderately fast. Somatic kinetics composed of dikinetids, approximately 35 (Fig. 3E and F; Table 3). Membranelle 1 triangular, consisting of 7 rows of basal bodies; membranelle 2 containing about 20 rows; membranelle 3 short and containing 3 rows of basal bodies (Fig. 3E and F; Table 3). Paroral membrane terminating at anterior edge of membranelle 3. Scutica, with about 5–7 basal bodies, arranged in long line (Fig. 3E and F; Table 3). The SSU rRNA gene sequences of Harbin population of P. apodigitiformis has been deposited in the GenBank database with the accession number OR642804.

Figure 3. Morphology and infraciliature of Philaster apodigitiformis Miao et al., Reference Miao, Wang, Li, Al-Rasheid and Song2009: (A–D) ventral views of different individuals in vivo and (E, F) infraciliature. Scale bars: 15 μm.

Table 3. Morphometric characterization of Philaster apodigitiformis

CV, coefficient of variation (%); M, median; Max, maximum; Mean, arithmetic mean; Min, minimum; n, number of specimens; s.d., standard deviation.

Data from stained specimens.

Phylogenetic positions of P. apodigitiformis

The ML and BI trees have almost identical topologies, therefore only the ML tree is shown (Fig. 4). Figure 4 shows that the Harbin population of P. apodigitiformis groups with P. apodigitiformis FJ648350 with full support and the clade of which then groups with Philaster sp. with full support.

Figure 4. ML tree inferred from the SSU rRNA gene sequences, showing the positions of P. apodigitiformis (in bold). Numbers at nodes represent the bootstrap values of ML out of 1000 replicates and the PP of BI. Fully supported (100%/1.00) branches are marked with solid circles. The scale bar corresponds to 5 substitutions per 100 nucleotide positions.

Experimental infection

Following Crosbie et al. (Reference Crosbie, Bridle, Cadoret and Nowak2012) and Ravindran et al. (Reference Ravindran, Raveendran and Irudayarajan2022), we used Koch's postulates to evaluate the hazards of ciliated infected fish, that is: (1) the same parasite can be discovered in every infected fish but not in the healthy individual, (2) isolate such parasite from the host and establish a pure culture in the medium, (3) the same disease will repeat itself by inoculating a healthy and sensitive host with a pure culture of this parasite and (4) the parasite can be isolated and cultured from the host, where the same disease is tested.

We designed experiment I to verify that P. apodigitiformis was the parasite that causes disease and experiment II to investigate expression of β-PKA of P. apodigitiformis during infection (Fig. 5). In the infection experiments I and II, fish infected with P. apodigitiformis stayed upside down with mouth opening, hardly breathing, secreting a lot of mucus and exhibiting blackness of the body. Six repeat groups of scratched fish infected with P. apodigitiformis randomly showed black or grey skin lesions, and the infected fish had uniformly different degrees of ulceration, in addition to the obvious increase in mucus on the surface of the fish. These symptoms are very similar to those of the natural forms of the disease. The fish in the experimental group began to die 1 by 1 since the first day, and until the 9th day, all individuals (n = 20) had died. The number of P. apodigitiformis in the experimental group was significantly increased compared to the control group in all cases.

Figure 5. Details of the experimental set-up.

Sequence analysis of PKA gene

The full-length cDNA of PKA is 957 bp, including an open reading frame (ORF) of 588 bp, which encodes a polypeptide (PKA) consisting of 196 amino acids with a predicted molecular weight of 22.97 kDa (Fig. 6A). In total, 369 bp were obtained by 5′-RACE amplification, whereas 24 bp by 3′-RACE amplification. Using BLAST analysis and comparison of sequences available in the NCBI database, it was confirmed that the novel nucleotide sequence belonged to β-PKA. The full-length cDNA sequence of β-PKA spanned 957 bp, of which the ORF spanned 588 bp, the 5′-untranslated region (UTR) 369 bp and the 3′-UTR 24 bp. In addition, the poly (A) tail of the 3′-UTR sequence composed of 12 nitrogenous bases.

Figure 6. (A) Full-length gene and amino acid sequences of PKA of P. apodigitiformis and (B) predicted 3-dimensional conformational map of PKA gene protein. The lowercase letters in the figure represent the UTR region, the uppercase letters are the coding region gene sequences and the separate uppercase letter represents the translated amino acid.

Secondary structure analysis of β-PKA gene

As shown in Fig. 6B, it is found that the secondary structure of PKA protein is mainly α-helix, containing a small amount of β-fold structure (20–23, 26–30), and the secondary structure is consistent with the usual characteristics of kinases. In terms of primary sequence, according to the annotation of homologous proteins in the UniProt protein structure database (https://www.uniprot.org/uniprotkb/I7MM26/entry#family_and_domains), the PKA proteins belong to the protein kinase structural domain, and the C-terminal amino acids 145–196 belong to the AGC-kinase C-terminal structural domain, which is essential for the development of kinase function.

Phylogenetic analysis of PKA protein

ML and BI trees showed nearly identical topologies, therefore only the ML tree is shown in Fig. 7. Branchiostoma floridae was used as outgroup. We have acquired nearly all available sequences of the PKA protein to present a comprehensive overview of PKA protein for parasites. Several parasitic ciliates (P. apodigitiformis, Tetrahymena thermophila and Paramecium tetraurelia) group together with strong support, the group of which then clusters with other parasites, e.g. Hydroides elegans, Plasmodium falciparum, Schistosoma haematobium, Trypanosoma brucei brucei and Trypanosoma cruzi with high support values (Fig. 7). Notably, parasitic ciliates divide into 2 groups, 1 contains P. apodigitiformis, T. thermophila and P. tetraurelia; the other includes T. thermophila and Ichthyophthirius multifiliis. In specific branches, particular sequences (indicated by question marks) fail to cluster with closely related ones. This occurrence might stem from misidentification or the potential that they are paralogous sequences. Consequently, we opted to remove these questionable sequences during the alignment process, thereby ensuring that the number of taxa in the alignment matches that of the tree.

Figure 7. (A) Multiple alignments of amino acid sequences of PKA gene from different species and (B) ML tree inferred from PKA gene protein showing the systematic position of P. apodigitiformis (in bold). Bootstrap values above 50 for the ML (1000 replicates) and/or BI (1000 replicates) are given at the individual nodes. Scale bar corresponds to 10 substitutions per 100 nucleotide positions.

PKA gene expression in P. apodigitiformis

For control and each infection groups, about 10 000 cells were added. During infection, the PKA mRNA level in the P. apodigitiformis increased significantly, compared with the non-infection (control) group (P < 0.05, Fig. 8).

Figure 8. Relative expression profile of PKA gene mRNA was determined by qRT-PCR for non-infection and infection groups. Data relative to mRNA levels were normalized by β-actin and presented as the mean ± s.e.m.

Discussion

Comments on morphology and systematic position of P. apodigitiformis

The most important criteria for species identification and separation in the genus Philaster are oral membranelles 1–3, ratio of the length between body and oral field and the number of somatic kinetics (Miao et al., Reference Miao, Wang, Li, Al-Rasheid and Song2009). Harbin population of P. apodigitiformis only differs from the population described by having a smaller body size (40–60 μm × 15–25 μm vs 60–90 μm × 30–40 μm). Harbin population of P. apodigitiformis groups with P. apodigitiformis FJ648350 with full support, which supports the morphological identification of this species (Fig. 4).

Pathological features of P. apodigitiformis

Histopathological studies of scuticociliatosis have been carried out and reported in detail many times, especially in fish (Jin et al., Reference Jin, Harikrishnan, Moon, Kim, Kim, Balasundaram, Azad I and Heo2000; Iglesias et al., Reference Iglesias, Paramá, Alvarez, Leiro, Fernández and Sanmartín2001; Harikrishnan et al., Reference Harikrishnan, Balasundaram and Heo2010, Reference Harikrishnan, Jin, Kim, Balasundaram and Heo2012). The most obvious feature of the diseased fish is that the lesion area becomes white, slightly swollen and soft to touch, and this feature is more obvious in young fish. In adult fish, the whitish area eventually becomes congested and ulcerated. In addition to the skin, fins and muscles on the surface of the fish's body, scuticociliate can also invade the abdominal cavity, heart, brain and other internal organs and tissues (Kim et al., Reference Kim, Alker, Shuster, Quirolo and Harvell2006). In contrast to tetrahymenosis, scuticociliatosis occurs mostly in marine aquaculture (e.g. Stichopus japonicus, Scophthalmus maximus and Brachyura) and does not have a wider range of hosts (e.g. slugs, chick embryos, dragonflies, helgramites, roaches, cockroaches and caterpillars) (Li et al., Reference Li, Warren, Zhang, Pan and Pan2021). In addition to this, scuticociliates mainly affects marine fish and P. apodigitiformis affects freshwater fish (Lom and Dyková, Reference Lom and Dyková1992; Thilakaratne et al., Reference Thilakaratne, Rajapaksha, Hewakopara, Rajapakse and Faizal2003; Imai et al., Reference Imai, Tsurimaki, Goto, Wakita and Hatai2009; Harikrishnan et al., Reference Harikrishnan, Balasundaram and Heo2010). In our study, we confirmed that scuticociliate could also affect freshwater fish, e.g. guppy.

The results of the survival rate test indicated that P. apodigitiformis was the direct cause of death of guppy, and Philaster species is an opportunistic invader that is potentially harmful to aquaculture. Philaster species can undergo mass reproduction under suitable conditions. In the initial stage of the infection test, the density of the ciliates was 5 ind. mL−1 (10 000 cells added into 2 L water) in each group. In the later stage, the densities of the Philaster species in the infection groups reached ca. 5000 ind. mL−1. To reduce these issues in fish cultures, it would be beneficial to change a significant amount of water during the initial stage of infection, remove dead fish and minimize any mechanical damage to the fish.

Analysis of PKA gene and PKA protein in P. apodigitiformis

The PKA gene has been reported in previous studies to have the ability to participate as a second messenger and to help Plasmodium invade the host cell (Flueck et al., Reference Flueck, Drought, Jones, Patel, Perrin, Walker, Nofal, Snijders, Blackman and Baker2019; Patel et al., Reference Patel, Perrin, Flynn, Bisson, Withers-Martinez, Treeck, Flueck, Nicastro, Martin, Ramos, Gilberger, Snijders, Blackman and Baker2019; Kumar et al., Reference Kumar, Das, Sen, Abhishek, Shafi, Bamra, Kumar, Kumar, Kumar, Mukharjee, Dikhit, Pandey and Das2021). In the previous study, we found a significant upregulation of the expression level of β-PKA gene by the transcriptome analysis after the pre-infestation of P. apodigitiformis on ornamental fish. In the present study, we cloned the complete sequence of PKA gene in P. apodigitiformis, and measured its expression by qRT-PCR.

The PKA pathway is one of the most versatile and best studied signalling pathways in eukaryotic cells (Søberg et al., Reference Søberg, Moen, Steen Skålhegg and Laerdahl2017). Previous studies confirmed that protein kinases exerted major regulatory effects in eukaryotic signalling events, and PKA was a regulatory protein that plays a crucial role in signal transduction and signalling pathways (Eisenhardt et al., Reference Eisenhardt, Fiala, Braun, Rosenboom, Kress, Ebert and Menzel2001; Fischer et al., Reference Fischer, Djoha, Büttner and Zipfel2003). The present study indicates that the cyclic adenosine monophosphate-dependent protein kinase plays a critical role in controlling essential steps such as ciliates’ growth, development and regulating the activity of the sensory body structures and the irritability system of parasitic scuticociliates.

Thus, in order to verify the role of the β-PKA gene in P. apodigitiformis during infection, we cloned and expressed the complete sequence of PKA gene. A 957 bp sequence was obtained, and the ORF encoded 196 amino acid residues. Moreover, the identified amino acid sequence encoded by the PKA gene of P. apodigitiformis was highly similar to those of other species, e.g. H. elegans, P. falciparum, S. haematobium, T. brucei brucei and T. cruzi (Fig. 7B). In addition, analysis of the predicted tertiary structure of the protein revealed that PKA protein mainly contained α-helix and a small amount of β-fold structure (20–23, 26–30). The secondary structure is consistent with the usual characteristics of kinases, which indicates that the β-PKA gene is relatively stable, conserved and showed high homologous. Meanwhile, our results show that the expression level of PKA gene is significantly increased during infection. The present study suggests that PKA can be used to explore in greater depth the capabilities exerted during infection.

Author's contribution

Chunyu Zhou: conceptualization, methodology and writing – original draft. Lihui Liu and Mingyue Jiang: data curation, visualization and investigation. Li Wang: supervision. Xuming Pan: writing – reviewing and editing.

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Financial support

This work was supported by the Natural Science Foundation of China (project number: 31970498).

Competing interest

None.

Ethical standards

The animal experiments were conducted following the Guide for the Care and Use of Laboratory Animals; the protocol for which was approved by the Harbin Normal University.

References

Castro, LA, Küppers, GC, Schweikert, M, Harada, ML and Paiva, T (2014) Ciliates from eutrophized water in the northern Brazil and morphology of Cristigera hammeri Wilbert, 1986 (Ciliophora, Scuticociliatia). European Journal of Protistology 50, 122133.CrossRefGoogle ScholarPubMed
Cawthorn, RJ, Lynn, DH, Despres, B, MacMillan, R, Maloney, R, Loughlin, M and Bayer, R (1996) Description of Anophryoides haemophila n. sp. (Scuticociliatida: Orchitophryidae), a pathogen of American lobsters Homarus americanus. Diseases of Aquatic Organisms 24, 143148.CrossRefGoogle Scholar
Crosbie, PB, Bridle, AR, Cadoret, K and Nowak, BF (2012) In vitro cultured Neoparamoeba perurans causes amoebic gill disease in Atlantic salmon and fulfils Koch's postulates. International Journal for Parasitology 42, 511515.CrossRefGoogle ScholarPubMed
Eisenhardt, D, Fiala, A, Braun, P, Rosenboom, H, Kress, H, Ebert, PR and Menzel, R (2001) Cloning of a catalytic subunit of cAMP-dependent protein kinase from the honeybee (Apis mellifera) and its localization in the brain. Insect Molecular Biology 10, 173181.CrossRefGoogle ScholarPubMed
Fan, X, Miao, M, Al-Rasheid, KA and Song, W (2009) A new genus of marine scuticociliate (Protozoa, Ciliophora) from northern China, with a brief note on its phylogenetic position inferred from small subunit ribosomal DNA sequence data. The Journal of Eukaryotic Microbiology 56, 577582.CrossRefGoogle ScholarPubMed
Fan, X, Chen, X, Song, W, Al-Rasheid, KA and Warren, A (2010) Two new marine scuticociliates, Sathrophilus planus n. sp. and Pseudoplatynematum dengi n. sp., with improved definition of Pseudoplatynematum (Ciliophora, Oligohymenophora). European Journal of Protistology 46, 212220.CrossRefGoogle Scholar
Fan, X, Hu, X, Al-Farraj S, A, Clamp, JC and Song, W (2011a) Morphological description of three marine ciliates (Ciliophora, Scuticociliatia), with establishment of a new genus and two new species. European Journal of Protistology 47, 186196.CrossRefGoogle ScholarPubMed
Fan, X, Lin, X, Al-Rasheid, K, Al-Farraj, SA, Warren, A and Song, W (2011b) The diversity of scuticociliates (Protozoa, Ciliophora): a report on eight marine forms found in coastal waters of China, with a description of one new species. Acta Protozoologica 50, 219234.Google Scholar
Fischer, P, Djoha, S, Büttner, DW and Zipfel, PF (2003) Isolation and characterization of the regulatory subunit of cAMP-dependent protein kinase from the filarial parasite Onchocerca volvulus. Molecular & Biochemical Parasitology 128, 3342.CrossRefGoogle ScholarPubMed
Flueck, C, Drought, LG, Jones, A, Patel, A, Perrin, AJ, Walker, EM, Nofal, SD, Snijders, AP, Blackman, MJ and Baker, DA (2019) Phosphodiesterase beta is the master regulator of cAMP signalling during malaria parasite invasion. PLoS Biology 17, e3000154.CrossRefGoogle ScholarPubMed
Foissner, W and Wilbert, N (1981) A comparative study of the infraciliature and silverline system of the fresh water scuticociliates Pseudocohnilembus putrinus (Kahl, 1928) nov. comb., P. pusillus (Quennerstedt, 1869) nov. comb., and the marine form P. marinus Thompson, 1966. Journal of Protozoology 28, 291297.CrossRefGoogle Scholar
Foissner, W, Jung, JH, Filker, S, Rudolph, J and Stoeck, T (2014) Morphology, ontogenesis and molecular phylogeny of Platynematum salinarum nov. spec., a new scuticociliate (Ciliophora, Scuticociliatia) from a solar saltern. European Journal of Protistology 50, 174184.CrossRefGoogle Scholar
Hall, TA (1999) BioEdit: a user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symposium Series 41, 9598.Google Scholar
Harikrishnan, R, Balasundaram, C and Heo, MS (2010) Scuticociliatosis and its recent prophylactic measures in aquaculture with special reference to South Korea Taxonomy, diversity and diagnosis of scuticociliatosis: part I control strategies of scuticociliatosis: part II. Fish & Shellfish Immunology 29, 1531.CrossRefGoogle ScholarPubMed
Harikrishnan, R, Jin, CN, Kim, JS, Balasundaram, C and Heo, MS (2012) Philasterides dicentrarchi, a histophagous ciliate causing scuticociliatosis in olive flounder, Philasterides dicentrarchi – histopathology investigations. Experimental Parasitology 130, 239245.CrossRefGoogle ScholarPubMed
Iglesias, R, Paramá, A, Alvarez, MF, Leiro, J, Fernández, J and Sanmartín, ML (2001) Philasterides dicentrarchi (Ciliophora, Scuticociliatida) as the causative agent of scuticociliatosis in farmed turbot Scophthalmus maximus in Galicia (NW Spain). Diseases of Aquatic Organisms 46, 4755.CrossRefGoogle ScholarPubMed
Imai, S, Tsurimaki, S, Goto, E, Wakita, K and Hatai, K (2009) Tetrahymena infection in guppy, Poecilia reticulata. Fish Pathology 35, 6772.CrossRefGoogle Scholar
Jin, CN, Harikrishnan, R, Moon, YG, Kim, MC, Kim, JS, Balasundaram, C, Azad I, S and Heo, MS (2000) Histopathological changes of Korea cultured olive flounder, Paralichthys olivaceus due to scuticociliatosis caused by histophagous scuticociliate, Philasterides dicentrarachi. Veterinary Parasitology 161, 292301.CrossRefGoogle Scholar
Kim, K, Alker, AP, Shuster, K, Quirolo, C and Harvell, CD (2006) Longitudinal study of aspergillosis in sea fan corals. Diseases of Aquatic Organisms 69, 9599. https://doi.org/10.3354/dao069095CrossRefGoogle ScholarPubMed
Kumar, M, Das, S, Sen, A, Abhishek, K, Shafi, MT, Bamra, T, Kumar, A, Kumar, V, Kumar, A, Mukharjee, R, Dikhit, R, Pandey, K and Das, P (2021) Oxidant activated soluble adenylate cyclase of Leishmania donovani regulates the cAMP-PKA signaling axis for its intra-macrophage survival during infection. Journal of Cellular Biochemistry 122, 14131427.CrossRefGoogle ScholarPubMed
Leroux, AE, Schulze, JO and Biondi, RM (2018) AGC kinases, mechanisms of regulation and innovative drug development. Seminars in Cancer Biology 48, 117.CrossRefGoogle ScholarPubMed
Li, W, Warren, A, Zhang, S, Pan, M and Pan, X (2021) Identification and infection mechanism of Tetrahymena vorax affecting the goldfish Carassius auratus. Aquaculture 539, 736643.CrossRefGoogle Scholar
Lom, J and Dyková, I (1992) Protozoan parasites of fishes. Developments in Aquaculture and Fisheries Science 26, 1315. doi:10.2307/3283600.Google Scholar
Lynn, DH and Strüder-Kypke, M (2005) Scuticociliate endosymbionts of echinoids (phylum Echinodermata): phylogenetic relationships among species in the genera Entodiscus, Plagiopyliella, Thyrophylax, and Entorhipidium (phylum Ciliophora). The Journal of Parasitology 91, 11901199.CrossRefGoogle ScholarPubMed
Mallo, N, Lamas, J, Piazzon, C and Leiro, JM (2015) Presence of a plant-like proton-translocating pyrophosphatase in a scuticociliate parasite and its role as a possible drug target. Parasitology 142, 449462.CrossRefGoogle Scholar
Medlin, L, Elwood, HJ, Stickel, S and Sogin, ML (1988) The characterization of enzymatically amplified eukaryotic 16S-like rRNA-coding regions. Gene 71, 491499.CrossRefGoogle ScholarPubMed
Miao, M, Wang, Y, Li, L, Al-Rasheid, KAS and Song, W (2009) Molecular phylogeny of the scuticociliate Philaster (Protozoa, Ciliophora) based on SSU rRNA gene sequences information, with description of a new species P. apodigitiformis sp. n. Systematics and Biodiversity 7, 381388.CrossRefGoogle Scholar
Miller, M, Pfeiffer, W and Schwartz, T (2010) Creating the CIPRES Science Gateway for inference of large phylogenetic trees. In Proceedings of the Gateway Computing Environments Workshop (GCE), 14 November. New Orleans, LA. pp. 1–8.CrossRefGoogle Scholar
Noga, EJ (2010) Fish Disease: Diagnosis and Treatment. New Jersey, USA: Wiley-Blackwell.CrossRefGoogle Scholar
Nylander, JAA (2004) Mrmodeltest v2. Program distributed by the author. Available at http://www.abc.se/nylander/mrmodeltest2/mrmodeltest2.htmlGoogle Scholar
Pan, X, Bourland, WA and Song, W (2013a) Protargol synthesis: an in-house protocol. The Journal of Eukaryotic Microbiology 60, 609614.CrossRefGoogle ScholarPubMed
Pan, X, Gao, F, Liu, W, Fan, X, Warren, A and Song, W (2013b) Morphology and SSU rRNA gene sequences of three Frontonia species, including a description of F. subtropica spec. nov. (Ciliophora, Peniculida). European Journal of Protistology 49, 6777.CrossRefGoogle ScholarPubMed
Patel, A, Perrin, AJ, Flynn, HR, Bisson, C, Withers-Martinez, C, Treeck, M, Flueck, C, Nicastro, G, Martin, SR, Ramos, A, Gilberger, TW, Snijders, AP, Blackman, MJ and Baker, DA (2019) Cyclic AMP signalling controls key components of malaria parasite host cell invasion machinery. PLoS Biology 17, e3000264.CrossRefGoogle ScholarPubMed
Pérez-Uz, B and Song, W (1995) Uronema gallicum sp. n. [Protozoa: Ciliophora] a new marine scuticociliate from the coastal area of calais. Acta Protozoologica 34, 143149.Google Scholar
Posada, D and Crandall, KA (1998) Modeltest: testing the model of DNA substitution. Bioinformatics (Oxford, England) 14, 817818.Google ScholarPubMed
Ravindran, C, Raveendran, HP and Irudayarajan, L (2022) Ciliated protozoan occurrence and association in the pathogenesis of coral disease. Microbial Pathogenesis 162, 105211.CrossRefGoogle ScholarPubMed
Ronquist, F and Huelsenbeck, J (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics (Oxford, England) 19, 15721574.Google ScholarPubMed
Søberg, K, Moen, LV, Steen Skålhegg, B and Laerdahl, JK (2017). Evolution of the cAMP-dependent protein kinase (PKA) catalytic subunit isoforms. PLoS ONE 12, e0181091.CrossRefGoogle ScholarPubMed
Song, W and Wilbert, N (2002) Reinvestigations of three ‘well-known’ marine scuticociliates: Uronemella filificum (Kahl, 1931) nov. gen. nov. comb. Pseud cohnilembus hargisi Evans & Thompson, 1964 and Cyclidium citrullus Cohn 1865, with description of the new genus Uronemella (Protozoa, Ciliophora, Scuticociliatida). Zoologischer Anzeiger – A Journal of Comparative Zoology 241, 317331.CrossRefGoogle Scholar
Stamatakis, A, Hoover, P and Rougemont, J (2008) A rapid bootstrap algorithm for the RAxML web servers. Systematic Biology 57, 758771.CrossRefGoogle ScholarPubMed
Thilakaratne, ID, Rajapaksha, G, Hewakopara, A, Rajapakse, RP and Faizal, AC (2003) Parasitic infections in freshwater ornamental fish in Sri Lanka. Diseases of Aquatic Organisms 54, 157162.CrossRefGoogle ScholarPubMed
Thompson, JC and Kaneshiro, ES (1968) Redescriptions of Uronema filificum and U. elegans. Journal of Protozoology 15, 141144.CrossRefGoogle Scholar
Wang, J, Chen, X, Ge, X, Wang, Z and Mu, W (2022) Molecular cloning, characterization and expression analysis of p53 from high latitude fish Phoxinus lagowskii and its response to hypoxia. Fish Physiology and Biochemistry 48, 631644.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Primer sequence and their applications

Figure 1

Figure 1. Pathological alterations in Poecilia reticulata: (A) a healthy P. reticulata individual; (B) a conspicuous bleeding spot directly above the fish's head; (C) highlights evident of bleeding spots within the abdominal cavity and (D) a visibly fractured and forked tail fin.

Figure 2

Table 2. Characterization of different groups of guppies infected by P. apodigitiformis (unit: ind.)

Figure 3

Figure 2. Histological sections of P. reticulata stained with haematoxylin–eosin: (A) deformed and disordered arrangement of muscle tissue (arrowheads), (B) disordered arrangement of liver tissue (arrowheads), (C) shrunken and deformed spleen tissue (arrowheads) and (D, E) shrunken and cracked gill filaments (arrowheads). Scale bar = 200 μm.

Figure 4

Figure 3. Morphology and infraciliature of Philaster apodigitiformis Miao et al., 2009: (A–D) ventral views of different individuals in vivo and (E, F) infraciliature. Scale bars: 15 μm.

Figure 5

Table 3. Morphometric characterization of Philaster apodigitiformis

Figure 6

Figure 4. ML tree inferred from the SSU rRNA gene sequences, showing the positions of P. apodigitiformis (in bold). Numbers at nodes represent the bootstrap values of ML out of 1000 replicates and the PP of BI. Fully supported (100%/1.00) branches are marked with solid circles. The scale bar corresponds to 5 substitutions per 100 nucleotide positions.

Figure 7

Figure 5. Details of the experimental set-up.

Figure 8

Figure 6. (A) Full-length gene and amino acid sequences of PKA of P. apodigitiformis and (B) predicted 3-dimensional conformational map of PKA gene protein. The lowercase letters in the figure represent the UTR region, the uppercase letters are the coding region gene sequences and the separate uppercase letter represents the translated amino acid.

Figure 9

Figure 7. (A) Multiple alignments of amino acid sequences of PKA gene from different species and (B) ML tree inferred from PKA gene protein showing the systematic position of P. apodigitiformis (in bold). Bootstrap values above 50 for the ML (1000 replicates) and/or BI (1000 replicates) are given at the individual nodes. Scale bar corresponds to 10 substitutions per 100 nucleotide positions.

Figure 10

Figure 8. Relative expression profile of PKA gene mRNA was determined by qRT-PCR for non-infection and infection groups. Data relative to mRNA levels were normalized by β-actin and presented as the mean ± s.e.m.