Cuticular collagen genes from the parasitic nematode Ostertagia circumcincta

A highly conserved, inhibitable astacin metalloprotease from Teladorsagia circumcincta is required for cuticle formation and nematode development

•

Astacin metalloprotease, DPY-31, is conserved throughout the nematode phylum.

•

DPY-31 is crucial to Teladorsagia circumcincta cuticle formation.

•

Matrix metalloprotease inhibitors are efficacious against recombinant DPY-31.

•

Novel hydroxamate inhibitors caused Dumpy and Moult defects in nematodes.

•

DPY-31 is a potential target for future nematode control.

Parasitic nematodes cause chronic, debilitating infections in both livestock and humans worldwide, and many have developed multiple resistance to the currently available anthelmintics. The protective collagenous cuticle of these parasites is required for nematode survival and its synthesis has been studied extensively in the free-living nematode, Caenorhabditis elegans. The collagen synthesis pathway is a complex, multi-step process involving numerous key enzymes, including the astacin metalloproteases. Nematode astacinsare crucial for C. elegans development, having specific roles in hatching, moulting and cuticle synthesis. NAS-35 (also called DPY-31) is a homologue of a vertebrate procollagen C-proteinase and performs a central role in cuticle formation of C. elegans as its mutation causes temperature-sensitive lethality and cuticle defects. The characterisation of DPY-31 from the ovine gastrointestinal nematode Teladorsagia circumcincta and its ability to rescue the C. elegans mutant is described. Compounds with a hydroxamate functional group have previously been shown to be potent inhibitors of procollagen C-proteinases and were therefore examined for inhibitory activity against the T. circumcincta enzyme. Phenotypic screening against T. circumcincta, Haemonchus contortus and C. elegans larval stages identified compounds that caused body morphology phenotypes consistent with the inhibition of proteases involved in cuticle collagen synthesis. These compounds correspondingly inhibited the activity of recombinant T. circumcincta DPY-31, supporting the hypothesis that this enzyme may represent a potentially novel anthelmintic drug target.

CUTI-1: A novel tetraspan protein involved in C. elegans CUTicle formation and epithelial integrity

The nematode cuticle is a tough extracellular matrix composed primarily of cross-linked collagens and non-collagenous cuticulins. It is required for nematode motility and protection from the external environment. Little is known about how the complex process of cuticle formation has been adapted to the specialized requirements of the nematode cuticle, which is structurally and compositionally unique from other organisms. The C. elegans gene cuti-1 (CUTicle and epithelial Integrity) encodes a nematode-specific protein. We have shown that CUTI-1 is expressed in the epithelia and in seam cells. Within these tissues the expression of cuti-1 mRNA cycles throughout development in line with the molting cycle, a process that involves synthesis of a new cuticle. In addition, knockdown of cuti-1 by RNA interference (RNAi) results in worms that display post-embryonic phenotypes related to cuticle dysfunction and defects in epithelial integrity. This is one of the first reports of a nematode-specific protein involved in extracellular matrix formation. It provides further insight into how novel ways have evolved to regulate the formation of the cuticle, which is the primary protective barrier and skeletal component of nematodes.

Molecular cloning of a cDNA encoding a putative cuticle collagen of Trichinella spiralis

A 5-day-old adult stage-specific cDNA fragment from Trichinella spiralis was identified by suppression subtractive hybridization and was used as a probe to screen the cDNA library. The cDNA sequence coding for a putative T. spiralis cuticle collagen was isolated. The cDNA encoded an open reading frame of 343 amino acid residues with molecular weight of 35.1 k Da. The deduced protein contained an N-terminal signal peptide, a nematode cuticle collagen N-terminal domain and a collagen triple helix repeat domain. Searches in GenBank using BLASTP showed up to 47% identity to cuticle collagens from other nematodes. Southern blot analysis of genomic DNA indicated this gene was present as a single copy in T. spiralis genome.

Enzymes involved in the biogenesis of the nematode cuticle

Nematodes include species that are significant parasites of man, his domestic animals and crops, and cause chronic debilitating diseases in the developing world; such as lymphatic filariasis and river blindness caused by filarial species. Around one third of the World's population harbour parasitic nematodes; no vaccines exist for prevention of infection, limited effective drugs are available and drug resistance is an ever-increasing problem. A critical structure of the nematode is the protective cuticle, a collagen-rich extracellular matrix (ECM) that forms the exoskeleton, and is critical for viability. This resilient structure is synthesized sequentially five times during nematode development and offers protection from the environment, including the hosts' immune response. The detailed characterization of this complex structure; it's components, and the means by which they are synthesized, modified, processed and assembled will identify targets that may be exploited in the future control of parasitic nematodes. This review will focus on the nematode cuticle. This structure is predominantly composed of collagens, a class of proteins that are modified by a range of co- and post-translational modifications prior to assembly into higher order complexes or ECMs. The collagens and their associated enzymes have been comprehensively characterized in vertebrate systems and some of these studies will be addressed in this review. Conversely, the biosynthesis of this class of essential structural proteins has not been studied in such detail in the nematodes. As with all morphogenetic, functional and developmental studies in the Nematoda phylum, the free-living species Caenorhabditis elegans has proven to be invaluable in the characterization of the cuticle and the cuticle collagen gene family, and is now proving to be an excellent model in the study of cuticle collagen biosynthetic enzymes. This model system will be the main focus of this review.

Functional analysis of the glutathione S-transferase 3 from Onchocerca volvulus (Ov-GST-3): a parasite GST confers increased resistance to oxidative stress in Caenorhabditis elegans

This study examined the genomic organisation of the coding region of the glutathione S-transferase 3 (Ov-GST-3) from the human parasitic nematode Onchocerca volvulus; alternative splicing leads to three different transcripts (Ov-GST-3/1; Ov-GST-3/2 and Ov-GST-3/3). Since the expression of Ov-GST-3 is inducible by oxidative stress, it is assumed that it is involved in the defense against reactive oxygen species (ROS) resulting from cellular metabolism. Furthermore, we suggest that Ov-GST-3 plays an important role in the protection of the parasite against ROS derived from the host's immune system. To experimentally investigate these speculations, we generated Caenorhabditis elegans lines transgenic for Ov-GST-3 (AK1) and examined their resistance to artificially generated ROS. The AK1 worms (extrachromosomal and integrated lines) were found to be much more resistant to internal (juglone) and external (hypoxanthine/xanthine oxidase) oxidative stress than wild-type C.elegans worms. RNA interference experiments targeted to the Ov-GST-3 transcripts resulted in decreased resistance, confirming that this effect is due to the transgenic expression of Ov-GST-3. These results clearly demonstrate that the Ov-GST-3 gene confers an increased resistance to oxidative stress. This study also shows the applicability of C.elegans as a model organism for the functional characterization of genes from (parasitic) nematode species which are not accessible to genetic manipulations.

Immunolocalization of a putative cuticular collagen protein in several developmental stages of Meloidogyne arenaria, Globodera pallida and G. rostochiensis

The monoclonal antibody IACR-CCNj.3d has previously been used to isolate a gene (gp-col-8) with strong similarity to cuticular collagen from a mixed stage Globodera pallida cDNA expression library. The antibody has also been shown to label specifically the amphidial canal of pre-parasitic second stage juveniles (J2) of several plant nematode species without any reactivity on the cuticular surface, indicating that this protein is either not present or is inaccessible on the cuticular surface. This paper investigates the cross-reactivity of Mab IACR-CCNj.3d with Meloidogyne arenaria and the localization of the putative collagen protein on the cuticular surface of parasitic stages in planta and on the cuticular surface of juveniles inside eggs. The antigen was shown to be present in all developmental stages of the two species of potato cyst nematodes and M. arenaria. The antibody bound strongly to the amphidial canal and hypodermis of pre-parasitic J2 and adult females. The antigen was present on the cuticular surface of the sausage-shaped J2 in planta and of first stage juveniles (J1) inside the eggs. The presence of collagen on the surface of the cuticle of moulting stages of plant parasitic nematodes has been observed for the first time. It is clear that this protein has a role in the construction of the cuticle of the first stage juveniles and parasitic second stage juveniles, during moulting inside the eggs and in the root tissue, respectively.

Caenorhabditis elegans and the study of gene function in parasites

The free-living nematode Caenorhabditis elegans is a tractable experimental model system for the study of both vertebrate and invertebrate biology. Its most significant advantages are its simplicity, both in anatomy and in genomic organization, and the elaborate methods that have been developed to attribute function to previously uncharacterized genes. Importantly, > 40% of parasitic nematode genes exhibit high levels of homology to genes within the C. elegans genome. Studying such genes using the C. elegans model should yield new insights into key molecules and their possible implications in parasite survival, leading to the discovery of new drug targets and vaccine candidates.

Characterisation of a collagen gene subfamily from the potato cyst nematode Globodera pallida

We have isolated two full-length genomic DNA sequences, which encode the cuticle collagen proteins GP-COL-1 and GP-COL-2, from the potato cyst nematode Globodera pallida. A third, partial collagen gene ORF termed gp-col-t(t=truncated) has also been isolated and appears to represent an unexpressed pseudogene. The gp-col-1 and gp-col-2 genes both contain three short (<97 bp) introns which disrupt coding regions predicted to specify proteins with molecular weights of 33 and 32.7 kDa respectively. All three sequences show high similarity to each other and to the previously isolated G. pallida cDNA clone gp-col-8. The conserved pattern of cysteine residues and non-(Gly-X-Y)(n) region sequence similarity observed in all four G. pallida genes suggests that these molecules form part of the same subfamily of collagens. Southern analysis indicates that this subfamily is likely to contain further members. The G. pallida collagen sequences show striking similarity to twelve genes from Caenorhabditis elegans which collectively represent the recently classified Group 1a collagen subfamily. No data exists on the function of this subfamily in C. elegans. gp-col-1 and gp-col-2 are developmentally regulated with transcripts of both genes detected in adult virgin and gravid females but not in pre-parasitic second stage juveniles. A similar expression pattern is observed for the Group 1a collagen lemmi 5 from Meloidogyne incognita perhaps indicating a generic link between subfamily and function during the various changes in cuticular structure which accompany nematode growth and reproduction. Immunochemical studies indicate that the GP-COL-1 protein is specifically located in the hypodermis of G. pallida adult females.

Cuticle collagen genes. Expression in Caenorhabditis elegans

Collagen is a structural protein used in the generation of a wide variety of animal extracellular matrices. The exoskeleton of the free-living nematode, Caenorhabditis elegans, is a complex collagen matrix that is tractable to genetic research. Mutations in individual cuticle collagen genes can cause exoskeletal defects that alter the shape of the animal. The complete sequence of the C. elegans genome indicates upwards of 150 distinct collagen genes that probably contribute to this structure. During the synthesis of this matrix, individual collagen genes are expressed in distinct temporal periods, which might facilitate the formation of specific interactions between distinct collagens.

Biochemical and structural characterization of a divergent loop cyclophilin from Caenorhabditis elegans

Cyclophilin 3 (CYP-3) is one of the most abundantly expressed cyclophilin isoforms in the free living nematode Caenorhabditis elegans. The detailed post-embryonic expression pattern of the cyp-3 transcript is unusual, peaking during early larval development. The spatial expression pattern was examined via reporter gene analysis demonstrating that the cyp-3 transcript is exclusively expressed in the single anterior excretory cell. Recombinant cyclophilin 3 has been purified, crystallized and solved to a resolution of 1.8 A. The peptidyl-prolyl isomerase activity of CYP-3 has been characterized against the substrate N-succinyl-Ala-Ala-Pro-Phe-p-nitroanilide, and gives a k(cat)/K(m) value of 2.4 x 10(6) M(-1) s(-1). The immunosuppressive drug cyclosporin A binds and inhibits CYP-3 with an IC(50) value of 16 nM, comparable with the range of values found for human cyclophilin A. The x-ray structure shows that the overall fold and active site geometry is similar to other cyclophilin structures. There are however a number of distinctive features, and we use this structure and amino acid sequence alignment analysis to identify a subgroup of "divergent-loop cyclophilins". This subgroup has a number of uniquely conserved features: an additional loop between residues 48 and 54 (KSGKPLH); two cysteine residues (Cys(40) and Cys(168)) that are in close proximity but remain in the unoxidized form, and two other conserved residues, His(54) and Glu(83). We suggest that these features are functionally important for the role played by this class of cyclophilins during cellular responses to stress caused by changes in the redox environment or by up-regulation of cellular activity. This study represents a detailed biological, biochemical, and structural characterization of a single cyclophilin isoform in the model organism Caenorhabditis elegans.

Identification of promoter elements of parasite nematode genes in transgenic Caenorhabditis elegans

Transformation of the free-living nematode Caenorhabditis elegans with promoter/reporter gene constructs is a very powerful technique to examine and dissect gene regulatory mechanisms. No such transformation system is available for parasitic nematode species. We have exploited C. elegans as a heterologous transformation system to examine activity and specificity of parasitic nematode gene promoters. Using three different parasite promoter/lac Z reporter constructs strict tissue-specific expression is observed. Upstream sequences of the Haemonchus contortus gut pepsinogen gene pep-1 and cysteine protease gene AC-2 direct expression exclusively in gut cells, while promoter sequence of the Ostertagia circumcincta cuticular collagen gene colost-1 directs hypodermal-specific expression. Mutation analysis indicates that AC-2 promoter function is dependent on a GATA-like motif close to the translation start site, similar to our findings with the C. elegans cpr-1 cysteine protease gene. While the spatial expression of these parasite promoters in C. elegans correlates with their expression in the parasite, the exact timing of expression does not. This suggests that regulatory mechanisms influencing the timing of expression may have evolved more rapidly than those controlling spatial expression of structural genes.

Molecular characterization of a Haemaphysalis longicornis tick salivary gland-associated 29-kilodalton protein and its effect as a vaccine against tick infestation in rabbits

The use of tick vaccines in mammalian hosts has been shown to be the most promising alternative tick control method to current use of acaricides, which suffers from a number of limitations. However, the success of this method is dependent on the identification, cloning, and in vitro expression of tick molecules involved in the mediation of key physiological roles with respect to the biological success of a tick as a vector and pest. We have sequenced and characterized a Haemaphysalis longicornis tick salivary gland-associated cDNA coding for a 29-kDa extracellular matrix-like protein. This protein is expressed in both unfed and fed immature and mature H. longicornis ticks. The predicted amino acid sequence of p29 shows high homology to sequences of some known extracellular matrix like-proteins with the structural conservation similar to all known collagen proteins. Immunization with the recombinant p29 conferred a significant protective immunity in rabbits, resulting in reduced engorgement weight for adult ticks and up to 40 and 56% mortality in larvae and nymphs that fed on the immunized rabbits. We speculate that this protein is associated with formation of tick cement, a chemical compound that enables the tick to remain attached to the host, and suggest a role for p29 as a candidate tick vaccine molecule for the control of ticks. We have discussed our findings with respect to the search of tick molecules for vaccine candidates.

The first isolated collagen gene of the root-knot nematode Meloidogyne javanica is developmentally regulated

The nematode's surface comprises a multilayered cuticle, which consists mainly of collagen proteins. We identified, cloned and characterized the first cuticular collagen gene, Mjcol-3, of the plant-parasitic nematode Meloidogyne javanica. The gene putatively encodes a 32.4-kDa collagen protein, including a propeptide which possesses a subtilisin-like protease-cleavage site. Six introns were identified in the gene sequence, with three slightly different acceptor-splicing sites. The basic structure of the predicted MJCOL-3 protein sequence is highly similar to that of the Caenorhabditis elegans DPY-7, with 65.9% identity between the two amino acid sequences. Relative to DPY-7, the putative MJCOL-3 protein has a shorter carboxy-terminus. This non-conserved feature may indicate different contributions of DPY-7 and MJCOL-3 collagens to the structure of the cuticle. Mjcol-3 is developmentally regulated: transcripts were found mainly in preparasitic developing eggs, less in parasitic third- and fourth-stage juveniles and young females shortly after the fourth molt, and much less in females before egg-laying.

Conservation of the Caenorhabditis elegans cuticle collagen gene col-12 in Caenorhabditis briggsae

The functional importance of the majority of Caenorhabditis elegans cuticle collagen genes is unknown. We have identified, cloned and sequenced the Caenorhabditis briggsae homologue of the C. elegans gene col-12, a cuticle collagen for which no mutants have yet been identified. Homology in the flanking sequence has allowed us to unambiguously identify this gene as the col-12 homologue, as opposed to some other closely related member of this large multigene family. The whole of the predicted polypeptide is highly conserved (94.9% identical), including those regions not yet shown by mutational analysis to be important for C. elegans cuticle collagen function. These include the whole of the N-terminal non-Gly-X-Y domain and the X and Y positions of the Gly-X-Y domain. This may be a consequence of the requirement of cuticle collagens to participate in intermolecular interactions throughout the full length of the polypeptide. There is increasing evidence to suggest that conservation between C. elegans and C. briggsae is confined to functionally significant sequence. Hence, the conservation of col-12 between these two species provides evidence that this member of the cuticle collagen family has a significant structural function.