Development and validation of a long-read metabarcoding platform for the detection of filarial worm pathogens of animals and humans.

BACKGROUND: Filarial worms are important vector-borne pathogens of a large range of animal hosts, including humans, and are responsible for numerous debilitating neglected tropical diseases such as, lymphatic filariasis caused by Wuchereria bancrofti and Brugia spp., as well as loiasis caused by Loa loa. Moreover, some emerging or difficult-to-eliminate filarioid pathogens are zoonotic using animals like canines as reservoir hosts, for example Dirofilaria sp. 'hongkongensis'. Diagnosis of filariasis through commonly available methods, like microscopy, can be challenging as microfilaremia may wane below the limit of detection. In contrast, conventional PCR methods are more sensitive and specific but may show limited ability to detect coinfections as well as emerging and/or novel pathogens. Use of deep-sequencing technologies obviate these challenges, providing sensitive detection of entire parasite communities, whilst also being better suited for the characterisation of rare or novel pathogens. Therefore, we developed a novel long-read metabarcoding assay for deep-sequencing the filarial nematode cytochrome c oxidase subunit I gene on Oxford Nanopore Technologies' (ONT) MinION™ sequencer. We assessed the overall performance of our assay using kappa statistics to compare it to commonly used diagnostic methods for filarial worm detection, such as conventional PCR (cPCR) with Sanger sequencing and the microscopy-based modified Knott's test (MKT). RESULTS: We confirmed our metabarcoding assay can characterise filarial parasites from a diverse range of genera, including, Breinlia, Brugia, Cercopithifilaria, Dipetalonema, Dirofilaria, Onchocerca, Setaria, Stephanofilaria and Wuchereria. We demonstrated proof-of-concept for this assay by using blood samples from Sri Lankan dogs, whereby we identified infections with the filarioids Acanthocheilonema reconditum, Brugia sp. Sri Lanka genotype and zoonotic Dirofilaria sp. 'hongkongensis'. When compared to traditionally used diagnostics, such as the MKT and cPCR with Sanger sequencing, we identified an additional filarioid species and over 15% more mono- and coinfections. CONCLUSIONS: Our developed metabarcoding assay may show broad applicability for the metabarcoding and diagnosis of the full spectrum of filarioids from a wide range of animal hosts, including mammals and vectors, whilst the utilisation of ONT' small and portable MinION™ means that such methods could be deployed for field use.

Canine filaria species in selected lymphatic filariasis endemic and non-endemic areas in Sri Lanka.

Subperiodic brugian filariasis and dirofilariasis show a rising trend in Sri Lanka posing a threat to public health. As information was limited on canine filaria species in Sri Lanka, we studied the filaria parasites among dog populations in lymphatic filariasis (LF) endemic and non-endemic regions by microscopy and molecular methods. Thick blood smears (TBSs) were performed among 295 dogs presenting to veterinary clinics for surgical or sterilization procedures in Galle (LF endemic) and Mullaitivu (LF non-endemic) districts, of which 55.6% were positive for any microfilariae. We identified Dirofilaria repens (50.8%) and Brugia spp. (20.6%) by microscopy, which, included mono-infections (D. repens 35.3% and Brugia spp. 5%) and co-infections (15.6%). Infections in Galle and Mullaitivu were 61% and 44.9% respectively. The brugian filariasis rate was significantly higher among canines in LF endemic Galle district (29.9%) than in Mullaitivu (LF non-endemic) (1.1%) (P < 0.001), while D. repens infections were comparable in both districts. Genomic DNA extracted from 10% of microfilariae positive TBSs was amplified using pan-filarial primers targeting the internal-transcriber-spacer region-2 (ITS-2). Sequencing of amplicons confirmed the presence of D. repens (89.28%), Brugia pahangi (7.14%) and B. malayi (3.57%) infections. The phylogeny constructed and analysed in MEGA X indicated genetic variability among D. repens and B. pahangi isolates from Sri Lanka. With this study, we were able to report B. pahangi infections for the first time in Sri Lanka.

Pyruvate produced by Brugia spp. via glycolysis is essential for maintaining the mutualistic association between the parasite and its endosymbiont, Wolbachia.

Human parasitic nematodes are the causative agents of lymphatic filariasis (elephantiasis) and onchocerciasis (river blindness), diseases that are endemic to more than 80 countries and that consistently rank in the top ten for the highest number of years lived with disability. These filarial nematodes have evolved an obligate mutualistic association with an intracellular bacterium, Wolbachia, a symbiont that is essential for the successful development, reproduction, and survival of adult filarial worms. Elimination of the bacteria causes adult worms to die, making Wolbachia a primary target for developing new interventional tools to combat filariases. To further explore Wolbachia as a promising indirect macrofilaricidal drug target, the essential cellular processes that define the symbiotic Wolbachia-host interactions need to be identified. Genomic analyses revealed that while filarial nematodes encode all the enzymes necessary for glycolysis, Wolbachia does not encode the genes for three glycolytic enzymes: hexokinase, 6-phosphofructokinase, and pyruvate kinase. These enzymes are necessary for converting glucose into pyruvate. Wolbachia, however, has the full complement of genes required for gluconeogenesis starting with pyruvate, and for energy metabolism via the tricarboxylic acid cycle. Therefore, we hypothesized that Wolbachia might depend on host glycolysis to maintain a mutualistic association with their parasitic host. We did conditional experiments in vitro that confirmed that glycolysis and its end-product, pyruvate, sustain this symbiotic relationship. Analysis of alternative sources of pyruvate within the worm indicated that the filarial lactate dehydrogenase could also regulate the local intracellular concentration of pyruvate in proximity to Wolbachia and thus help control bacterial growth via molecular interactions with the bacteria. Lastly, we have shown that the parasite's pyruvate kinase, the enzyme that performs the last step in glycolysis, could be a potential novel anti-filarial drug target. Establishing that glycolysis is an essential component of symbiosis in filarial worms could have a broader impact on research focused on other intracellular bacteria-host interactions where the role of glycolysis in supporting intracellular survival of bacteria has been reported.

Rapid detection and identification of Wuchereria bancrofti, Brugia malayi, B. pahangi, and Dirofilaria immitis in mosquito vectors and blood samples by high resolution melting real-time PCR.

A simple, rapid, and high-throughput method for detection and identification of Wuchereria bancrofti, Brugia malayi, Brugia pahangi, and Dirofilaria immitis in mosquito vectors and blood samples was developed using a real-time PCR combined with high-resolution melting (HRM) analysis. Amplicons of the 4 filarial species were generated from 5S rRNA and spliced leader sequences by the real-time PCR and their melting temperatures were determined by the HRM method. Melting of amplicons from W. bancrofti, B. malayi, D. immitis, and B. pahangi peaked at 81.5±0.2℃, 79.0±0.3℃, 76.8±0.1℃, and 79.9±0.1℃, respectively. This assay is relatively cheap since it does not require synthesis of hybridization probes. Its sensitivity and specificity were 100%. It is a rapid and technically simple approach, and an important tool for population surveys as well as molecular xenomonitoring of parasites in vectors.

An unusual case of Brugia sp. infection in a dog from Alberta, Canada.

Brugia is a vector-transmitted nematode that is commonly known for its zoonotic significance of causing lymphatic filariasis in Asia and Oceanic regions of the world. In addition to public health concerns, Brugia species have been known to infect domestic animals, including dogs and cats. However, information is scarce regarding genus Brugia in North America, and rare infections have been noted in domestic cats, humans, and other wild mammals. Herein, we document the first reported case of a Brugia species infection in a dog from North America and the first molecular characterization of the species in question. A three-year-old German Shepard from Alberta, Canada presented to a local veterinary clinic with a facial subcutaneous nodule that was surgically excised. Histopathology identified an enlarged buccal lymph node containing small foci of eosinophilic and granulomatous inflammation within the cortex and capsule. This inflammation was associated with adult filarioid nematodes localized within lymphatic vessels or adjacent connective tissue. Genomic DNA was extracted from formalin-fixed paraffin-embedded tissue, and PCR targeting the Hha1 repeat and the partial cytochrome oxidase c subunit 1 (cox1) of the mitochondrial DNA confirmed parasite identity as Brugia sp. While we can rule out B. beaveri being the causative agent, we cannot exclude B. lepori infection or a third uncharacterized Brugia species. Veterinarians and physicians should be made aware of North American Brugia infections and their possible health concerns.

Characterization of the genetics and epidemiology of Brugia sp. in domestic dogs in Chad, Africa.

Neglected tropical diseases pose a threat to domestic animal health, as domestic animals can serve as reservoirs for certain zoonotic parasitic infections, including Guinea worm (Dracunculus medinensis) and lymphatic filariasis. Surveillance for these parasites in domestic animals is needed to understand infection prevalence and transmission cycles, with the goal of instituting appropriate interventions. The goal of this research was to report our finding of Brugia sp. infection in dogs from Chad, Africa, and to characterize the genetics and epidemiology of the parasite. During a recent Chadian canine pathogen surveillance project, we identified Brugia sp. infections in a total of 46 out of 428 dogs (10.7%) sampled at three time points in 2019-2020. We found high levels of sequence similarity to B. malayi and B. pahangi based on amplification of 18S rRNA, 5.8S rRNA, and ITS-2 regions. Phylogenetic analysis of 18S rRNA gene sequences placed the Chadian Brugia sp. in a clade with other Brugia spp. but grouped it separately from both B. malayi and B. pahangi. Analysis of Hha I sequences showed the greatest similarity with B. patei, a parasite previously reported from dogs, cats, and wildlife hosts in Kenya. Epidemiologic analysis using generalized linear regression modeling found significantly higher odds of Brugia sp. detection among dogs in villages in southern Chad compared to those in the northern region. Further, within the northern region, there were higher odds of detection in the dry season, compared to the wet season, which is consistent with the ecology of a presumably mosquito-borne parasite. The same 428 dogs were tested for Dirofilaria immitis antigen using a commercial assay (IDEXX SNAP 4Dx) at the earliest time point of the study, with 119 dogs testing positive. However, no association was noted between Brugia infection and a dog being positive for Di. immitis antigen, with only seven of the 119 Di. immitis antigen-positive dogs being Brugia-positive. This is the first report of Brugia sp. in domestic dogs in Chad and additional research is needed to definitively identify the species present, elucidate transmission, and understand potential risks to canine and human health.

X-treme loss of sequence diversity linked to neo-X chromosomes in filarial nematodes.

The sequence diversity of natural and laboratory populations of Brugia pahangi and Brugia malayi was assessed with Illumina resequencing followed by mapping in order to identify single nucleotide variants and insertions/deletions. In natural and laboratory Brugia populations, there is a lack of sequence diversity on chromosome X relative to the autosomes (πX/πA = 0.2), which is lower than the expected (πX/πA = 0.75). A reduction in diversity is also observed in other filarial nematodes with neo-X chromosome fusions in the genera Onchocerca and Wuchereria, but not those without neo-X chromosome fusions in the genera Loa and Dirofilaria. In the species with neo-X chromosome fusions, chromosome X is abnormally large, containing a third of the genetic material such that a sizable portion of the genome is lacking sequence diversity. Such profound differences in genetic diversity can be consequential, having been associated with drug resistance and adaptability, with the potential to affect filarial eradication.

Backpack PCR: A point-of-collection diagnostic platform for the rapid detection of Brugia parasites in mosquitoes.

BACKGROUND: Currently, molecular xenomonitoring efforts for lymphatic filariasis rely on PCR or real-time PCR-based detection of Brugia malayi, Brugia timori and Wuchereria bancrofti in mosquito vectors. Most commonly, extraction of DNA from mosquitoes is performed using silica column-based technologies. However, such extractions are both time consuming and costly, and the diagnostic testing which follows typically requires expensive thermal cyclers or real-time PCR instruments. These expenses present significant challenges for laboratories in many endemic areas. Accordingly, in such locations, there exists a need for inexpensive, equipment-minimizing diagnostic options that can be transported to the field and implemented in minimal resource settings. Here we present a novel diagnostic approach for molecular xenomonitoring of filarial parasites in mosquitoes that uses a rapid, NaOH-based DNA extraction methodology coupled with a portable, battery powered PCR platform and a test strip-based DNA detection assay. While the research reported here serves as a proof-of-concept for the backpack PCR methodology for the detection of filarial parasites in mosquitoes, the platform should be easily adaptable to the detection of W. bancrofti and other mosquito-transmitted pathogens. METHODOLOGY/PRINCIPAL FINDINGS: Through comparisons with standard silica column-based DNA extraction techniques, we evaluated the performance of a rapid, NaOH-based methodology for the extraction of total DNA from pools of parasite-spiked vector mosquitoes. We also compared our novel test strip-based detection assay to real-time PCR and conventional PCR coupled with gel electrophoresis, and demonstrated that this method provides sensitive and genus-specific detection of parasite DNA from extracted mosquito pools. Finally, by comparing laboratory-based thermal cycling with a field-friendly miniaturized PCR approach, we have demonstrated the potential for the point-of-collection-based use of this entire diagnostic platform that is compact enough to fit into a small backpack. CONCLUSIONS/SIGNIFICANCE: Because this point-of-collection diagnostic platform eliminates reliance on expensive and bulky instrumentation without compromising sensitivity or specificity of detection, it provides an alternative to cost-prohibitive column-dependent DNA extractions that are typically coupled to detection methodologies requiring advanced laboratory infrastructure. In doing so, this field-ready system should increase the feasibility of molecular xenomonitoring within B. malayi-endemic locations. Of greater importance, this backpack PCR system also provides the proof-of-concept framework for the development of a parallel assay for the detection of W. bancrofti.

A novel gene from Brugia sp. that encodes a cytotoxic fatty acid binding protein allergen recognized by canine monoclonal IgE and serum IgE from infected dogs.

Brugia pahangi infection of dogs is a well characterized model of human lymphatic filariasis in which sera consistently show IgG or IgE reactivity to a 35-kDa antigen. Using dog lymph node B cells, we previously established a heterohybridoma cell line producing canine monoclonal IgE (cmAb 2.39) that activates and degranulates canine mast cells, and specifically recognizes a 35-kDa B. pahangi antigen. By affinity purification and sequencing of the native protein from B. pahangi adults, a 19-amino acid sequence was obtained; the derived nucleotide sequence showed homology to a Brugia malayi and 2 related Onchocerca volvulus expressed sequence tag (EST) clones from the Filarial Genome Project database. Consensus primers amplified a 244-bp product from adult and infective larval stage cDNA libraries of B. malayi, O. volvulus, and Wuchereria bancrofti, but not from those of nonfilarial nematodes. The B. malayi EST clone only showed nucleotide sequence homology to O. volvulus EST sequences. A 684-bp region from the open reading frame was expressed as a glutathione S-transferase fusion protein designated BmAl-1. CmAb 2.39, as well as serum IgE from dogs infected with B. pahangi and canine filarial heartworm, Dirofilaria immitis, recognized BmAl-1 on enzyme-linked immunosorbent assay and Western blots. BmAl-1 showed high binding affinity for a fatty acid; however, a search for sequence homology with known fatty acid binding proteins indicated that BmAl-1 is a unique fatty acid binding protein. This 35-kDa protein seems to be highly conserved in different stages and species of filarids, and it represents a previously unknown allergen that is possibly involved in the pathogenesis of filarial disease.

Morphological and molecular characteristics of Malayfilaria sofiani Uni, Mat Udin & Takaoka n. g., n. sp. (Nematoda: Filarioidea) from the common treeshrew Tupaia glis Diard & Duvaucel (Mammalia: Scandentia) in Peninsular Malaysia.

BACKGROUND: The filarial nematodes Wuchereria bancrofti (Cobbold, 1877), Brugia malayi (Brug, 1927) and B. timori Partono, Purnomo, Dennis, Atmosoedjono, Oemijati & Cross, 1977 cause lymphatic diseases in humans in the tropics, while B. pahangi (Buckley & Edeson, 1956) infects carnivores and causes zoonotic diseases in humans in Malaysia. Wuchereria bancrofti, W. kalimantani Palmieri, Pulnomo, Dennis & Marwoto, 1980 and six out of ten Brugia spp. have been described from Australia, Southeast Asia, Sri Lanka and India. However, the origin and evolution of the species in the Wuchereria-Brugia clade remain unclear. While investigating the diversity of filarial parasites in Malaysia, we discovered an undescribed species in the common treeshrew Tupaia glis Diard & Duvaucel (Mammalia: Scandentia). METHODS: We examined 81 common treeshrews from 14 areas in nine states and the Federal Territory of Peninsular Malaysia for filarial parasites. Once any filariae that were found had been isolated, we examined their morphological characteristics and determined the partial sequences of their mitochondrial cytochrome c oxidase subunit 1 (cox1) and 12S rRNA genes. Polymerase chain reaction (PCR) products of the internal transcribed spacer 1 (ITS1) region were then cloned into the pGEM-T vector, and the recombinant plasmids were used as templates for sequencing. RESULTS: Malayfilaria sofiani Uni, Mat Udin & Takaoka, n. g., n. sp. is described based on the morphological characteristics of adults and microfilariae found in common treeshrews from Jeram Pasu, Kelantan, Malaysia. The Kimura 2-parameter distance between the cox1 gene sequences of the new species and W. bancrofti was 11.8%. Based on the three gene sequences, the new species forms a monophyletic clade with W. bancrofti and Brugia spp. The adult parasites were found in tissues surrounding the lymph nodes of the neck of common treeshrews. CONCLUSIONS: The newly described species appears most closely related to Wuchereria spp. and Brugia spp., but differs from these in several morphological characteristics. Molecular analyses based on the cox1 and 12S rRNA genes and the ITS1 region indicated that this species differs from both W. bancrofti and Brugia spp. at the genus level. We thus propose a new genus, Malayfilaria, along with the new species M. sofiani.

Ancient horizontal transfers of retrotransposons between birds and ancestors of human pathogenic nematodes.

Parasite host switches may trigger disease emergence, but prehistoric host ranges are often unknowable. Lymphatic filariasis and loiasis are major human diseases caused by the insect-borne filarial nematodes Brugia, Wuchereria and Loa. Here we show that the genomes of these nematodes and seven tropical bird lineages exclusively share a novel retrotransposon, AviRTE, resulting from horizontal transfer (HT). AviRTE subfamilies exhibit 83-99% nucleotide identity between genomes, and their phylogenetic distribution, paleobiogeography and invasion times suggest that HTs involved filarial nematodes. The HTs between bird and nematode genomes took place in two pantropical waves, >25-22 million years ago (Myr ago) involving the Brugia/Wuchereria lineage and >20-17 Myr ago involving the Loa lineage. Contrary to the expectation from the mammal-dominated host range of filarial nematodes, we hypothesize that these major human pathogens may have independently evolved from bird endoparasites that formerly infected the global breadth of avian biodiversity.

The BCL7 gene family: deletion of BCL7B in Williams syndrome.

The BCL7A gene, which maps to human chromosome 12q24.13, was cloned through its direct involvement with MYC and IGH in a three-way translocation in a Burkitt lymphoma cell line. Here, we describe the identification of two related human genes, BCL7B and BCL7C, which share 90% identity to the amino-terminal 51 amino acids of human BCL7A, as well as 41% identity in the same region to Drosophila melanogaster, Caenorhabditis elegans, and Brugia malayi EST sequences. This degree of relatedness in the amino-terminal domain suggests we have defined a new gene family of unknown function. There was little sequence conservation between the family members outside this conserved domain and no identified protein motifs could be deduced. Human BCL7B and BCL7C mapped to chromosome 7q11.23, and 16p11, respectively. No chromosomal rearrangements affecting BCL7B or BCL7C were detected in lymphoid malignancies. BCL7B did, however, map within the region of 7q11.23 which is commonly deleted in the congenital disorder, Williams syndrome.

Cloned antigen genes of Brugia filarial parasites.

Human lymphatic filariasis is a chronic, potentially debilitating disease caused by Brugia and Wuchereria species of parasitic nematodes. The spectrum of clinical manifestations appears to be related to the immune response of individuals to invasive larvae, adult worms and circulating first-stage larvae (microfilariae). Potential immunopathological outcomes place constraints on vaccine development, emphasizing the need to understand the basis of immunity and pathology. Clones coding for a number of distinct antigenic proteins of Brugia pahangi and Brugia malayi have been isolated via immunological screening of a cDNA expression library. A small number of these expressed peptides show exclusive reactivity with antibody from amicrofilaraemic, potentially immune individuals. Surprisingly, a dominant immunogen isolated with human antibody is the filarial parasite homologue of heat shock protein (hsp) 70. This protein is constitutively expressed in both insect- and mammalian-dwelling parasitic stages, but does not appear to presented to the host immune system in intact worms.

A multi-copy gene encodes a potentially protective antigen in Brugia malayi.

A genomic library of Brugia malayi was constructed and screened by hybridization with a cDNA clone corresponding to a potentially protective antigen of 63 kDa. The antigen is encoded by a multicopy gene family. Five distinct gene copies were isolated and one was characterized in detail by nucleotide sequence analysis. An apparent pseudogene was also characterized. The organization of genes encoding the antigen is typical of higher eukaryotes in exon/intron organization although the introns have an unusually high A+T content (75%). Organization of the genomic sequence along with S1 nuclease and primer extension analyses indicate that a short untranslated exon is spliced to the 5' end of the mRNAs encoding the antigen.

Species-specific oligonucleotide probes for the identification of human filarial parasites.

Species-specific oligonucleotide probes have been constructed for the filarial parasites Brugia malayi and Brugia pahangi. Both parasites contain a 322 base pair repeated DNA sequence that is cleaved once by the restriction endonuclease HhaI. A consensus repeat sequence was determined from the DNA sequence of 15 cloned isolates of each species. Although the two repeats have an average homology of 89%, half the differences are clustered in a region of 66 nucleotides that has a homology of only 72%. Within this region, two probes, a 29-mer that is B. malayi specific and a 21-mer that is B. pahangi specific, were constructed. The sequence of both probes was chosen to obtain the maximum difference between the consensus sequences of the two species. The probes were also selected to be GC rich to increase their stability as a DNA hybrid. In a filter hybridization assay, the B. malayi probe has a 500-fold preference for B. malayi DNA versus B. pahangi DNA and a sensitivity of 200 pg. The B. pahangi probe has similar specificity and sensitivity for B. pahangi DNA. A rapid lysis procedure allows the probes to detect 1-2 third stage larvae of either B. malayi or B. pahangi in a filter hybridization assay.

Phylogeny of Onchocerca volvulus and related species deduced from rRNA sequence comparisons.

A rapid, direct method for determining the partial nucleotide sequence of large subunit ribosomal RNA was adapted and applied to a group of helminth parasites. Small samples of total, unfractionated cellular RNA isolated from each organism were analysed and the nucleotide sequences of equivalent portions of the large subunit ribosomal RNA compared. The data obtained were used to construct a phylogenetic tree showing the evolutionary relationships within this group of organisms.

Comparison of the body wall myosin heavy chain sequences from Onchocerca volvulus and Brugia malayi.

The complete coding sequence of Onchocerca volvulus myosin heavy chain has been determined from a series of overlapping cDNAs. The protein sequences from the 2 filarids, one responsible for subcutaneous filariasis, the other for lymphatic filariasis, show 92% identity, and are 1957 amino acids long. Each protein sequence is also equally related, with 75% identity, to MHC-B, the protein encoded by the unc-54 gene of the free-living nematode C.elegans. Such analysis is useful in phylogenetic studies among nematodes, as well as in structure-function relationships among myosin isolates.

Characterization of an hsp70 gene from the human filarial parasite, Brugia malayi (Nematoda).

We have previously shown that an Onchocerca volvulus cDNA clone in lambda gt-11 designated OvG15, potentially encoding a peptide homologous to the 70-kDa heat shock protein (Hsp70), was recognized by sera of many individuals living in a zone endemic for lymphatic filariasis and most strikingly by sera from amicrofilaremic individuals including endemic normals, those with chronic symptoms and TPE patients. Few asymptomatic microfilaremics recognized the Hsp70. We have now used the insert from the OvG15 clone to isolate the homologous gene from Brugia malayi and analyze its primary structure and expression. The data presented in this communication describe a heat-inducible member of the hsp70 gene family of B. malayi which demonstrates intriguing features of tissue specific basal level expression, developmental regulation and heat inducibility.

Characterization of a beta-tubulin gene and a beta-tubulin gene products of Brugia pahangi.

A genomic clone containing a beta-tubulin gene from the parasitic nematode Brugia pahangi was isolated. This gene was sequenced to determine its size, structural organization, and corresponding primary amino acid sequence. The coding sequence of the beta-tubulin gene spans 3.8 kb, is organized into 9 exons and expresses an mNRA of 1.8 kb which codes for a protein of 448 amino acids. The predicted beta-tubulin amino acid sequence is 89%, 94%, 90% and 88% identical to the chicken beta 2, and the Caenorhabditis elegans ben-1, tub-1 and mec-7 gene products, respectively. Southern hybridization analyses demonstrated that there is only one copy of this gene isotype but that other distinct beta-tubulin genes may exist in the Brugia pahangi genome. A nematode specific antipeptide rabbit antiserum raised against the predicted amino acid sequence of the extreme carboxy-terminal region of the B. pahangi beta-tubulin was used to identify beta-tubulin isoforms in adult nematodes and microfilariae. Isoforms detected by this nematode-specific antipeptide antiserum were identical in both adult worms and microfilariae and did not differ from the isoform patterns detected by a monoclonal antibody recognizing a conserved beta-tubulin epitope. This suggests that this carboxy-terminal peptide is highly represented in the beta-tubulin isoforms of B. pahangi.

Isolation and partial sequence of a collagen gene from the human filarial parasite Brugia malayi.

We report the isolation and sequence of a part of a gene encoding a collagen from the genome of the human filarial parasite Brugia malayi. The deduced amino acid sequence of the sequenced portion of this gene, which we have designated BmCol1, differs from the most catalogued nematode collagens in that it is composed predominantly of the glycine-X-Y motif, where either X or Y (or both) may be proline. The gene appears to be similar to two recently described Caenorhabditis elegans collagen genes whose deduced amino acid sequences resemble mammalian basement membrane collagens. BmCol1 is a single copy gene and appears to be present in several other parasitic nematodes examined.