Figures
Abstract
The cystatin superfamily is comprised of cysteine proteinase inhibitors and encompasses at least 3 subfamilies: stefins, cystatins and kininogens. In this study, the platyhelminth cystatin superfamily was identified and grouped into stefin and cystatin subfamilies. The conserved domain of stefins (G, QxVxG) was observed in all members of platyhelminth stefins. The three characteristics of cystatins, the cystatin-like domain (G, QxVxG, PW), a signal peptide, and one or two conserved disulfide bonds, were observed in platyhelminths, with the exception of cestodes, which lacked the conserved disulfide bond. However, it is noteworthy that cestode cystatins had two tandem repeated domains, although the second tandem repeated domain did not contain a cystatin-like domain, which has not been previously reported. Tertiary structure analysis of Taenia solium cystatin, one of the cestode cystatins, demonstrated that the N-terminus of T. solium cystatin formed a five turn α-helix, a five stranded β-pleated sheet and a hydrophobic edge, similar to the structure of chicken cystatin. Although no conserved disulfide bond was found in T. solium cystatin, the models of T. solium cystatin and chicken cystatin corresponded at the site of the first disulfide bridge of the chicken cystatin. However, the two models were not similar regarding the location of the second disulfide bridge of chicken cystatin. These results showed that T. solium cystatin and chicken cystatin had similarities and differences, suggesting that the biochemistry of T. solium cystatin could be similar to chicken cystatin in its inhibitory function and that it may have further functional roles. The same results were obtained for other cestode cystatins. Phylogenetic analysis showed that cestode cystatins constituted an independent clade and implied that cestode cystatins should be considered to have formed a new clade during evolution.
Citation: Guo A (2015) Comparative Analysis of Cystatin Superfamily in Platyhelminths. PLoS ONE 10(4): e0124683. https://doi.org/10.1371/journal.pone.0124683
Academic Editor: Ulrike Gertrud Munderloh, University of Minnesota, UNITED STATES
Received: October 13, 2014; Accepted: March 17, 2015; Published: April 8, 2015
Copyright: © 2015 Aijiang Guo. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are contained within the paper.
Funding: The author received no specific funding for this work.
Competing interests: The author has declared that no competing interests exist.
Introduction
Chicken cystatin was first described by Barrett, who discovered that it inhibited various cysteine proteases. Subsequently, many similar molecules present in metazoans and plants have been identified [1–3]. The cystatin superfamily includes inhibitors of diverse C1 and C13 families of cysteine proteases [4]. These peptidases play key roles in physiological processes [5–8]. The cystatin superfamily can be assigned to three distinct protein families based on similarities in their amino acid sequences and 3D structures [9]. In this system, the cystatin superfamily is placed in the I25 family, which contains three subfamilies: I25A (type 1, stefins), I25B (type 2, cystatins) and I25C (type 3, kininogens) [10]. Stefins are unglycosylated proteins with an approximate molecular weight of 11 kDa and have no signal sequence or disulfide bonds. They are predominately intracellular and are involved in the regulation of endogenous proteins in cells. The cystatins are about 13–14 kDa in size and have a signal sequence and two carboxy-terminal disulfide bonds. They are usually exported from cells and participate in regulation of the exogenous proteins [4]. The kininogens are restricted to the vertebrates [11]. The cystatin superfamily features numerous important common characteristics, but the differences in molecular structure and distribution imply different routes of biosynthesis and a variety of physiological functions.
Recently, some studies have described the capacity of nematode cystatins to regulate not only the activity of parasite proteases but also that of host proteases [12]. Additionally, some studies have shown that nematode cystatins modulate host immune responses [13–16]. However, little is known about the cestode cystatin superfamily and trematode cystatin superfamily [17–19].
Cysteine proteases have been described in cestodes and trematodes [20–23]. The expression of cysteine proteases implies the presence of members of the cystatin family [5]. Early attempts to infer molecular phylogenies of the cystatin superfamily have been hampered by the unavailability of genomic sequences. With the rapid development of next-generation sequencing technology, and the availability of complete genome and transcriptome data from an increasing number of parasite species, it is now feasible to explore cystatin superfamily genomic organization, classification and phylogeny.
In the present study, the cystatin superfamily was characterized and explored for their phylogeny in nine flatworms including Schmidtea mediterranea, Schistosoma japonicum, Schistosoma mansoni, Echinococcus multilocularis, Echinococcus granulosus, Hymenolepis microstoma, T. solium, T. saginata and T. asiatica. With the advantage of having T. solium, T. saginata and T. asiatica genomic data and samples, their corresponding cystatin superfamily was cloned and analyzed, which may provide a comprehensive insight into its abundance, diversity and evolution in platyhelminths.
Materials and Methods
Annotated genomes of platyhelminth species
The annotated genomes of 6 platyhelminths are available for public study. Those of the trematodes S. japonicum and S. mansoni and the cestodes T. solium, E. multilocularis, E. granulosus and H. microstoma can be found at http://www.genedb.org/homepage. The genome of the planarian S. mediterranea is available at http://smedgd.neuro.utah.edu. Each genome was investigated using the word “cystatin” as the query parameter. The expressed sequence tags (ESTs) or RNA-Seq data of each species were searched for the details of their transcription. For full-scale analysis, the nr and EST databases of NCBI (http://blast.ncbi.nlm.nih.gov/) were also included in the searches.
Identification of cystatin superfamily in T. solium, T. saginata and T. asiatica
The unpublished genome sequences of T. saginata and T. asiatica were used for the identification of the cystatin family. A combined strategy was employed using both the motifs-based method and the sequence similarity-based method to search for proteins or molecules with conserved cystatin-like domains in the genomes of the two tapeworms. Putative members of the cystatin superfamily in T. saginata and T. asiatica were characterized using the TBlastN program, with the annotated T. solium cystatin superfamily gene sequences (TsM_000671000 and TsM_000687900) as query sequences, to search the two genome databases with the cut-off e-value of 10−5 [24]. In addition, corresponding amino acid sequences were analyzed by the MEROPS peptidase database (http://merops.sanger.ac.uk/) and those belonging to proteinase inhibitor I25 [25] were considered for the putative cystatin superfamily.
The DNA and cDNA samples of T. solium, T. saginata and T. asiatica are available in our lab [24, 26]. In order to investigate gene organizations of the cystatin superfamily in these three species, their corresponding putative cystatin superfamily genes were amplified using DNA or cDNA as templates, under the thermal cycling profile of 94°C for 5 min, 30 cycles of denaturation at 94°C for 40s, annealing at 55°C for 30s and extension at 72°C for 50s. The amplified fragments were cloned into pGEM-T Easy Vector (Promega, USA) and confirmed by DNA sequencing (Takara, China). The specific primers are shown in Table 1.
Analysis of amino acid sequences and 3D models of platyhelminth cystatin superfamily
Signal peptides were predicted using SignalP 4.0 (www.cbs.dtu.dk/services/SignalP/) [27]. Disulfide bonds and domain architecture were predicted using the DiANNA 1.1 web server [28, 29] and SMART (http://smart.embl-heidelberg.de) [30], respectively. The predicted 3D models of platyhelminth stefins and cystatins were constructed by the homology-modeling server SWISS-MODEL (http://swissmodel.expasy.org/) [31]. The templates for the models were auto-selected by servers (chicken cystatin, PDB ID: 1yvb.1.B; others using 4lzi.1.A as model) [32–36]. VMD was used to display the tertiary structures of cystatins.
Sequence alignment and phylogenetic analysis
Protein sequences were aligned using ClustalW2 [37] and manually checked. The optimal model of protein evolution was selected by ProtTest [38]. The phylogenetic tree of flatworm cystatin superfamily members was constructed by the Maximum Likelihood (ML) method of PhyML [39] and with the following conditions: JII+I+G and the reliability of each branch was assessed by performing 100 bootstrap replications.
Results and Discussion
Identification of cystatin superfamily in platyhelminths
Cystatin superfamily members were identified in platyhelminths and are shown in Table 2. One stefin and one cystatin were characterized in each of T. solium and T. saginata, whereas one cystatin and two stefins were found in the T. asiatica genome. The expression of the stefins and the cystatins in the above mentioned three species was then confirmed by PCR using their corresponding cDNA as template (Fig 1). Similarly, the putative cystatin superfamily members were also identified in other platyhelminth species (Table 2). A single stefin gene was identified in each of E. multilocularis, E. granulosus, S. japonicum, S. mansoni and S. mediterranea. In addition, a single cystatin gene was found in each genome of tree cestodes including E. multilocularis, E. granulosus and H. microstoma, while two cystatin genes were found in each of S. japonicum and S. mediterranea. Furthermore, three different spliced cystatin proteins were deduced from electronic annotation in S. mansoni (Smp_034420.1, Smp_034420.2 and Smp_034420.3) (Figs 2A and S2). According to analysis of the transcriptomic and genomic data, two ancestral lineages, stefins and cystatins, were present in numerous platyhelminths. This result was in agreement with studies in some eukaryotic species with two ancestral lineages [40], but in disagreement with the early proposition that stefins, cystatins and kininogens appear almost simultaneously [41].
DNA and cDNAs of the three species were used as templates to amplify cystatin superfamily. The PCR products of cystatins are shown on the left of the DL2000 molecular marker, and stefins are shown on the right.
The domain was aligned using ClustalW and adjusted manually. (A) The three parts of the papain binding domain (G, QXVXG, PW) are displayed. Signal peptides and disulfide bridges are shown. The N-terminal amino acid extention of Tas_stefin2 is shaded pale grey. The number of amino acids of each protein is shown at last of sequence. (B) The tandem repeated domain of cestode cystatins is shown. The first amino acid and the last amino acid in the tandem repeated domain is numbered outside of them.
Interestingly, analysis of the gene structures of the platyhelminth cystatin superfamily showed that cestode cystatins were intronless (Table 2), which was further confirmed in T. solium, T. saginata and T. asiatica by PCR and sequencing (Fig 1 and Table 2). These results were remarkably different from those of other platyhelminths, which had at least one intron (Table 2). Additionally, the intron position and length in each of the cestode stefins were identical, except for T. asiatica stefin2 (Table 2). Gene organizations for the three parasite stefins were also confirmed through PCR and sequencing (Fig 1 and Table 2).
Analysis of amino acid sequences of cystatin superfamily in platyhelminths
Cystatins and stefins have one conserved domain that is important for their inhibition of papain-like cysteine proteases [5]. A signal peptide and two characteristic intra-chain disulfide bonds are present in cystatins, which are secreted proteins with 120 amino acid residues, but are absent in stefins with approximately 100 amino acid residues [5].
Compared with a human stefin, the reference for the type 1 subfamily [33], platyhelminth stefins have similar catalytic sites (G, QXVXG) (Fig 2A, also see S1 Fig for a complete list). The size of platyhelminth stefins ranged from 93 to 98 amino acids that are commonly found in mammalian stefins. The exception was T. asiatica stefin2, which contains 121 amino acids (Fig 2A). Compared with other platyhelminth stefins, T. asiatica stefin2 had a 25 amino acid extension at the N-terminus (Fig 2A, also see S1 Fig for a complete list) which was not a signal peptide. Comparisons of amino acid sequences of T. asiatica stefin1 with T. solium stefin and T. saginata stefins showed 95.9% and 79.6% homology, respectively. The C-terminal sequence of T. asiatica stefin2 revealed 82.1% and 98.9% homology with the T. solium stefin and T. saginata stefin, respectively. Large gene families often include both secreted and non-secreted members [42]. It was proposed that T. asiatica stefin2 with an N-terminal extension was a secreted protein. It has been reported that Fasciola gigantica stefin can be secreted [17, 18]. The present study does not provide evidence that T. asiatica stefin2 is a secreted protein and it remains to be investigated in future experiments.
Analysis of the amino acid sequences showed that platyhelminth and nematode cystatins had a signal peptide, except for S. japonicum cystatin1 (Fig 2A). Like chicken cystatin, whose crystallographic structure was the first to be resolved [32], platyhelminth cystatins had three conserved catalytic sites (G, QxVxG, and PW) in the domain that bind and inhibit proteases of the papain family (Fig 2A). The important role of conserved PW residues as part of the proteinase-binding site in the second hairpin loop has been confirmed previously [43, 44]. However, a Gly (G) occurred in place of Trp (W) in S. japonicum cystatin1, whereas a D residue occurred in place of a P residue in H. microstoma cystatin. More interestingly, PW residues were absent in S. mediterranea cystatin1 and S. mansoni cystatin1 (Fig 2A).
Notably, only one member of the cystatin superfamily, cystatin, was identified in H. microstoma and its key activity site had changed from PW residues to DW residues (Fig 2A), suggesting lack of catalytic activity. This raised a question of how H. microstoma inhibits various cysteine proteases. Previous studies have shown that stefins are primarily intracellular, while cystatins are found primarily in body fluids [40]. In plants, most cystatins gain function as inhibitors of both endogenous and exogenous cysteine proteases [40]. Additionally, there are numerous examples of loss of one or both lineages of cystatins and stefins, for example in Apicomplexa and Fungi [40]. A number of these pathogens have horizontally acquired bacterial chagasins for regulation of proteolysis [45]. It is speculated that the H. microstoma may inhibit various proteases either through its cystatin, which gains function as an inhibitor of both endogenous and exogenous cysteine proteases, like some plant cystatins, or horizontally acquiring the host’s cystatin superfamily, as in fungi [40].
Three different spliced cystatin proteins were deduced from electronic annotation in S. mansoni (S2 Fig). However, only S. mansoni cystatin2 contained all the characteristics of type 2 (cystatin-like doman, signal peptide and one or two conserved disulfide bonds) (Fig 2A). Similarly, S. mediterranea cystatin2 had all the characteristics of cystatins, but cystatin1 was lacking a PW activity site (Fig 2A). These results suggest that cystatins may have a functional divergence in S. mansoni and S. mediterranea. However, their functions have not been elucidated.
It was interesting to note that the size of cystatins in cestodes ranged from 274 to 295 amino acids (Table 2), substantially larger than those found in other species with 120 amino acid residues. Cestode cystatins exhibited a long sequence at the 3’ end after the conserved PW residues motif (Fig 2B, also see S2 Fig for a complete list). Searching for similarities within the amino acid sequences of each cestode cystatin revealed the presence of two tandem repeated domains (Fig 2B). However, the second tandem repeated domain did not contain a cystatin-like domain (G, QXVXG, PW). The mammalian kininogens are molecules with a high molecular weight containing multiple cystatin-type domains, which belong to members of family 3 of the cystatin superfamily [46]. Cystatin with multiple cystatin-like domains has also been reported in F. hepatica [47]. Cestode cystatins with one conserved domain did not belong to multi-domain cystatins, although they had two tandem repeated domains. The previously proposed evolutionary model hypothesized that the multi-domain cystatins originated from their stepwise evolution [48]. However, a new model of the evolution of the multi-domain cystatins considered domain duplication as a major mechanism for their origin [40]. The second tandem repeated domain throughout cestode cystatins may have originated from the cystatin domain, in the same manner as multi-domain cystatins.
There are two or three cystatin-like proteins in each planarian, nematode and trematode species (Table 2). However, there was only one cystatin protein with two tandem repeated domains in each cestode species. The results suggest that the repeated domain may have special functions. Additionally, mammals have many more copies of cystatin genes than do platyhelminths. For example, humans contain 17 members, suggesting gene expansions of the cystatin superfamily.
The other typical characteristic of cystatins is that they possess one or two conserved disulfide bridges. The analysis of cystatins in vertebrates, trematodes, nematodes, and planarians demonstrated that they had one or two conserved disulfide bonds (Fig 2A). However, the putative disulfide bonds in cestode cystatins were not conserved (Fig 2A, also see S1 Table for a complete list), like basal metazoans and plant cystatins [40]. This result indicates that structure of cestode cystatins is quite complex and is not consistent with previous evolutionary studies, which proposed that the disulfide bridges have been conserved in all cystatins [41]. It is well known that disulfide bonds have roles in the structure, stability and biological function of some proteins. Therefore, it is reasonable to believe that the putative disulfide bonds in cestode cystatins (S1 Table) may be related to their structure, stability and biological function, although they were not conserved.
Above results of comparison of amino acid sequences of cystatin superfamily revealed that the cystatin sequences were poorly conserved in platyhelminth species, except for the conserved cystatin-like domain (S2 Fig). However, the members of stefins were better conserved among these species (S1 Fig), a finding which was consistent with previous reporting [40].
Phylogenetic analysis of platyhelminth cystatin superfamily
The phylogenetic tree of the platyhelminth cystatin superfamily was constructed and is shown in Fig 3A. Although S. japonicum cystatin1 was annotated to have a cystatin-like domain, no signal peptide and cystatin-like domain was predicted using SMART. Thus, it was discarded when the tree was constructed. For S. mansoni, one of three splicing forms of cystatin, with an intact cystatin-like domain was chosen to construct the tree. The phylogenetic analysis clearly showed that the members of platyhelminth cystatin superfamily were divided into two independent groups, the stefin and cystatin subfamilies. The stefins in trematodes, nematodes and cestodes branched together in a clade discrete from the planarian one. All platyhelminth species had a single copy for the stefin except for T. asiatica with two stefins (stefin1 and stefin2). All stefin genes in T. solium, T. saginata and T. asiatica (cestodes) were confirmed by PCR using their respective cDNA as template (Fig 1). The results showed that two stefin genes, stefin 1 and stefin 2, were really expressed in T. asiatica (Table 2) and provided evidence to rule out the possibility of incorrect genome assembly. The phylogenetic analysis showed that T. asiatica stefin1 was closely related to T. solium stefin, and T. asiatica stefin2 to T. saginata stefin. The results of the genomic organization and the phylogenetic analysis supported the idea that T. asiatica stefin2 may have arisen during evolution before the separation of these cestode parasites.
(A) Phylogenetic tree derived from the alignment of complete predicted proteins sequences. Nodes with confidence values greater than 60% are indicated based on maximum likelihood (ML). Subfamilies are indicated at the right. (B) The fragment from Gly (G) to Cys (C) or Pro-Trp (PW) residue represent predicted cystatin-like domain. The RPT represent tandem repeated domains. Disulfide bonds between conserved cysteines are denoted. The typical motifs for Stefin (human stefin A) and cystatin (chicken cystatin) subfamily members are represented on top and below, respectively. The first three letters: (Egr) E. granulosus; (Emu) E. multilocularis; (Sja) S. japonicum; (Sma) S. mansoni; (Sme) S. mediterranea; (Tas) T. asiatica; (Tsa) T. saginata; (Tso) T. solium; (Hmi) H. microstoma; (Cel) C. Elegans.
Phylogenetic analysis revealed that Schistosoma and planarian cystatins belong to the same group and a putative gene duplication event may have occurred before or at the common ancestor of the planarian. It was noteworthy that a single copy of cystatin in each cestode species with two tandem repeated domains but no conserved disulfide bonds constituted an independent clade (Fig 3A and 3B). The diverse groups of proteins that are homologous to chicken cystatins have had their evolution schemes constructed in previous studies [40, 41]. However, the cystatin structures with two tandem repeated domains and without conserved disulfide bonds, like the cestode cystatins described in this study, have not been previously reported. The results presented here imply that the cestode cystatins may be considered a new subfamily.
Tertiary structure of T. solium cystatin showed some differences with chicken cystatin
Cestode cystatins with two tandem repeated domains and without conserved disulfide bonds have not been reported previously. It is intriguing to explore whether they have similar structural features to chicken cystatin. The crystal structure of chicken cystatin consists mainly of a five string α-helix and a five-stranded β-pleated sheet [1]. N-terminal Gly residue, QXVXG residues sited at the first β-hairpin loop and Pro-Trp residues sited at the second β-hairpin loop forming a hydrophobic edge to penetrate into the active site cleft of papins have been discussed in detail [43, 44, 49, 50]. The 3D structure of chicken cystatin [32] and T. solium cystatin are shown in Fig 4A and 4B, respectively. Although the structure of the extra C-terminal repeat domain of T. solium cystatin was difficult to predict, a superimposed diagram of 3D models for T. solium cystatin and chicken cystatin indicates that their papain inhibitory loop (G, QXVXG, PW) almost overlaps (Fig 4C). Although no conserved disulfide bond was found in T.solium cystatin, the models of T.solium cystatin and chicken cystatin corresponded at the site of the first disulfide bridge of the chicken cystatin, which may be explained by other kinds of bonds, such as a hydrogen bond. The two models were different regarding the location of the second disulfide bridge of chicken cystatin (Fig 4D). The same results were also obtained for other cestode cystatins (S3 Fig). These results showed that the models of cestode cystatins and chicken cystatin had both similarities and differences, suggesting that the biochemistry of cestode cystatins could be similar to chicken cystatin in its inhibitory function and they may have additional functional roles. This result is in disagreement with a recent study that has suggested it was not possible to identify cystatin homologs in E. granulosus, H. microstoma and T. solium [19]. In addition, excepting cestode cystatins, all predicted models of platyhelminth stefins and cystatins exhibited the similar conserved α-helix and β-pleat and the functional hydrophobic edge features that find in the human stefin [33, 51] and chicken cystatin models [32], respectively (not shown). Previous studies have shown that the structure of the plant inhibitor oryzacystatin possesses the same cystatin fold as animal cystatin, which has the ability to inhibit cysteine proteinase [52]. These results suggest that the biochemistry of the platyhelminth cystatin superfamily could be similar to chicken cystatin and human stefin in its inhibitory function, and it is possible that cestode cystatins may have further, as yet undefined, functional roles.
The 3D structures for chicken cystain (A) and T. solium cystatin (B) are shown. The cystatin models of chicken and T. solium are superimposed in (C). The opposite side of the (C) map are enlarged and shown in (D).
In this study, the cystatin superfamily was identified in platyhelminths using extensive genomic data, and divided into stefin and cystatin subfamilies. It had many important characteristics in common with the mammalian cystatin superfamily, except for cestode cystatins, which had two tandem repeated domains, but lacked the conserved disulfide bond. The specific characteristic of cestode cystatins was also indicated in phylogenetic analysis where they formed a separate clade. Additionally, the tertiary structure of T. solium cystatin showed both similarities and differences when compared to chicken cystatin. This study provided the first insights into the abundance, gene structure, 3D model structure, evolution and functional diversification of the cestode cystatin superfamily. The biochemistry of platyhelminth stefins and cystatins needs to be further characterized, especially for the unusual cestode superfamily.
Supporting Information
S1 Fig. Alignment of platyhelminth stefin superfamily.
https://doi.org/10.1371/journal.pone.0124683.s001
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S2 Fig. Alignment of platyhelminth cystatin superfamily.
https://doi.org/10.1371/journal.pone.0124683.s002
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S3 Fig. Superimposing 3D models of chicken and cestode cystatins.
The 3D structures for chicken cystain are shown in yellow, cestode cystains in other colors. Conserved cysteines (in green stick view) are displayed. The three parts of the papain binding domain (in stick view) are surrounded by ellipses.
https://doi.org/10.1371/journal.pone.0124683.s003
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S1 Table. Putative the disulfide bonds in platyhelminth cystatins.
https://doi.org/10.1371/journal.pone.0124683.s004
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Acknowledgments
The author would like to express his appreciation to Dr. Ya-dong Zheng for critical reading and to the reviewers for their constructive suggestions in this manuscript. The author would also like to thank the Beijing Genome Institute for providing unpublished genomic sequencing data.
Author Contributions
Conceived and designed the experiments: AG. Performed the experiments: AG. Analyzed the data: AG. Contributed reagents/materials/analysis tools: AG. Wrote the paper: AG.
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