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.

Impact of population structure on genetic diversity of a potential vaccine target in the canine hookworm (Ancylostoma caninum).

Ancylostoma caninum is a globally distributed canine parasitic nematode. To test whether positive selection, population structure, or both affect genetic variation at the candidate vaccine target Ancylostoma secreted protein 1 (asp-1), we have quantified the genetic variation in A. caninum at asp-1 and a mitochondrial gene, cytochrome oxidase subunit 1 (cox-1), using the statistical population analysis tools found in the SNAP Workbench. The mitochondrial gene cox-1 exhibits moderate diversity within 2 North American samples, comparable to the level of variation observed in other parasitic nematodes. The protein coding portion for the C-terminal half of asp-1 shows similar levels of genetic variation in a Wake County, North Carolina, sample as cox-1. Standard tests of neutrality provide little formal evidence for selection acting on this locus, but haplotype networks for 2 of the exon regions have significantly different topologies, consistent with different evolutionary forces shaping variation at either end of a 1.3-kilobase stretch of sequence. Evidence for gene flow among geographically distinct samples suggests that the mobility of hosts of A. caninum is an important contributing factor to the population structure of the parasite.

Investigating hookworm genomes by comparative analysis of two Ancylostoma species.

BACKGROUND: Hookworms, infecting over one billion people, are the mostly closely related major human parasites to the model nematode Caenorhabditis elegans. Applying genomics techniques to these species, we analyzed 3,840 and 3,149 genes from Ancylostoma caninum and A. ceylanicum. RESULTS: Transcripts originated from libraries representing infective L3 larva, stimulated L3, arrested L3, and adults. Most genes are represented in single stages including abundant transcripts like hsp-20 in infective L3 and vit-3 in adults. Over 80% of the genes have homologs in C. elegans, and nearly 30% of these were with observable RNA interference phenotypes. Homologies were identified to nematode-specific and clade V specific gene families. To study the evolution of hookworm genes, 574 A. caninum/A. ceylanicum orthologs were identified, all of which were found to be under purifying selection with distribution ratios of nonsynonymous to synonymous amino acid substitutions similar to that reported for C. elegans/C. briggsae orthologs. The phylogenetic distance between A. caninum and A. ceylanicum is almost identical to that for C. elegans/C. briggsae. CONCLUSION: The genes discovered should substantially accelerate research toward better understanding of the parasites' basic biology as well as new therapies including vaccines and novel anthelmintics.

Gene expression profiles associated with the transition to parasitism in Ancylostoma caninum larvae.

Ancylostoma caninum is a common canine parasite responsible for anemia and death in infected dogs. Gene expression profiling was used to investigate molecular differences between two different forms of the third larval stage (L3s): infective free-living larvae and in vitro serum-stimulated larvae that mimic the initial stages of parasitism of a host. We developed an A. caninum cDNA microarray consisting of 4191 EST clones, and used it to identify a set of 113 genes that are differentially regulated between infective and parasitic larval stages. Real-time RT-PCR was used to confirm the expression differences of a subset of the genes. Of the genes repressed upon serum stimulation, seven encode members of the 'Ancylostoma secreted protein' ASP family, while another transcript encoding a 24 kDa excretory protein with similarity to ASP was up-regulated in serum-stimulated L3s. This suggests that different members of a protein family that has important implications for the hookworm's parasitic lifestyle are regulated in a complementary manner in response to serum stimulation. Comparison of two strains of A. caninum from North Carolina and Maryland only identified a single gene, one of the members of the ASP family, that was differentially repressed upon serum stimulation.

Cloning and characterisation of genes encoding two transforming growth factor-beta-like ligands from the hookworm, Ancylostoma caninum.

To elucidate the role of transforming growth factor beta (TGF-beta) signalling in the arrest/reactivation pathway of the Ancylostoma caninum hookworm, two parasite-encoded TGF-beta-like ligands were cloned and characterised. Ac-dbl-1 showed 60% amino acid identity to the Caenorhabditis elegansdbl-1 gene, which regulates growth while Ac-daf-7 showed 46% amino acid identity to Ce-daf-7 which regulates arrested development. Exon/intron organisation of the genes for Ac-dbl-1 and Ac-daf-7 were different from that of the corresponding C. elegans genes with nine and 10 exons, respectively, and introns ranging in size from 56 to 2,556 bp. Based on real-time reverse transcriptase (RT)-PCR, Ac-dbl-1 and Ac-daf-7 were expressed in all stages tested, i.e. egg, first/second stage larvae (L1/L2), infective third stage larvae (iL3), serum-stimulated third stage larvae (ssL3), and male and female adult worms. Expression of Ac-dbl-1 peaked in the adult male stage suggesting a similar role to Ce-dbl-1 in regulating male tail patterning. Ac-daf-7 expression was at a maximum in the arrested iL3 and reactivated ssL3 stages, which differs from that of Ce-daf-7 expression and may be unique to parasitic nematodes that have an obligate requirement to undergo developmental arrest. In support of the PCR results, antibodies to the A. caninum TGF-beta-like ligands detected proteins in iL3, ssL3, and adult worm extracts. Immunofluorescent studies showed that Ac-daf-7 is expressed in the anterior region of the iL3 similar to Ce-daf-7, which is localised to the ASI chemosensory neurons.

A putative serine protease among the excretory-secretory glycoproteins of L1 Trichinella spiralis.

Trichinella spiralis first-stage larvae infect susceptible hosts by invading epithelial cells that line the small intestine. During this process the larva disgorges several glycoproteins that bear an unusual, highly antigenic sugar moiety, tyvelose (3,6-dideoxy arabinohexose). Monoclonal antibodies specific for tyvelose protect the intestine against infection, implicating tyvelose-bearing glycoproteins as mediators of invasion and niche establishment in the intestinal epithelium. In order to investigate these glycoproteins at the molecular level, we first prepared monoclonal anti-peptide antibodies. The antibodies bind a family of glycoproteins that are present in excretory-secretory products of first-stage larvae and are delivered to epithelial cells during invasion by T. spiralis. The major species present in an affinity purified fraction of crude T. spiralis antigens were subjected to tryptic peptide digestion. De novo amino acid sequencing of the peptides using Q-TOF tandem mass spectrometry, in combination with database searches and antibody screening of an L1 cDNA library, showed that the glycoproteins are variably glycosylated homologues of the serine protease family.