RNA interference mediated knockdown of Brugia malayi UDP-Galactopyranose mutase severely affects parasite viability, embryogenesis and in vivo development of infective larvae.

BACKGROUND: Galactofuranose is an essential cell surface component present in bacteria, fungi and several nematodes such as Caenorhabditis spp., Brugia spp., Onchocerca spp. and Strongyloides spp. This sugar maintains the integrity of parasite surface and is essential for virulence. UDP-Galactopyranose mutase (bmugm) plays a key role in Galf biosynthesis by catalyzing conversion of UDP-Galactopyranose into UDP-galactofuranose and knockout studies of the gene in Leishmania major, Mycobacterium and Aspergillus fumigatus displayed attenuated virulence while RNA interference study in C. elegans exhibited detrimental effects. Presence of UGM in several prokaryotic and eukaryotic microbial pathogens and its absence in higher eukaryotes renders it an attractive drug target. In the present study, RNA interference studies have been carried out to validate bmugm as an antifilarial drug target. METHODS: RNA interference studies using two different sequences of siRNAs targeting bmugm were carried out. The in vitro gene silencing of adult B. malayi parasites was undertaken to observe the effects on parasites. Infective larvae were also exposed to siRNAs and their in vivo development in jirds was observed. RESULTS: The in vitro gene silencing induced by siRNA1 and 2 individually as well as together knocked down the bmugm gene expression causing impaired viability of the exposed worms along with extremely reduced motility, abridged microfilarial release and adversely effected embryogenesis. The combinatorial in vitro gene silencing revealed marginally better results than both the siRNAs individually. Thus, infective larvae were treated with siRNA combination which showed downregulation of bmugm mRNA expression resulting into sluggish larval movements and/or death. The siRNA-treated actively motile larvae when inoculated intraperitoneally into jirds demonstrated highly reduced transformation of these larvae into adult worms with detrimental effects on embryogenesis. The effects of gene silencing were long-lasting as the adult worms developed from siRNA-treated larvae showed noticeable knockdown in the target gene expression. CONCLUSIONS: The validation studies undertaken here conclude that bmugm is essential for the proper development and survival of the parasite and support its candidature as an antifilarial drug target.

Expression of five acetylcholine receptor subunit genes in Brugia malayi adult worms.

Acetylcholine receptors (AChRs) are required for body movement in parasitic nematodes and are targets of "classical" anthelmintic drugs such as levamisole and pyrantel and of newer drugs such as tribendimidine and derquantel. While neurotransmission explains the effects of these drugs on nematode movement, their effects on parasite reproduction are unexplained. The levamisole AChR type (L-AChRs) in Caenorhabditis elegans is comprised of five subunits: Cel-UNC-29, Cel-UNC-38, Cel-UNC-63, Cel-LEV-1 and Cel-LEV-8. The genome of the filarial parasite Brugia malayi contains nine AChRs subunits including orthologues of Cel-unc-29, Cel-unc-38, and Cel-unc-63. We performed in situ hybridization with RNA probes to localize the expression of five AChR genes (Bm1_35890-Bma-unc-29, Bm1_20330-Bma-unc-38, Bm1_38195-Bma-unc-63, Bm1_48815-Bma-acr-26 and Bm1_40515-Bma-acr-12) in B. malayi adult worms. Four of these genes had similar expression patterns with signals in body muscle, developing embryos, spermatogonia, uterine wall adjacent to stretched microfilariae, wall of V as deferens, and lateral cord. Three L-AChR subunit genes (Bma-unc-29, Bma-unc-38 and Bma-unc-63) were expressed in body muscle, which is a known target of levamisole. Bma-acr-12 was co-expressed with these levamisole subunit genes in muscle, and this suggests that its protein product may form receptors with other alpha subunits. Bma-acr-26 was expressed in male muscle but not in female muscle. Strong expression signals of these genes in early embryos and gametes in uterus and testis suggest that AChRs may have a role in nervous system development of embryogenesis and spermatogenesis. This would be consistent with embryotoxic effects of drugs that target these receptors in filarial worms. Our data show that the expression of these receptor genes is tightly regulated with regard to localization in adult worms and developmental stage in embryos and gametes. These results may help to explain the broad effects of drugs that target AChRs in filarial worms.

Efficient in vitro RNA interference and immunofluorescence-based phenotype analysis in a human parasitic nematode, Brugia malayi.

BACKGROUND: RNA interference (RNAi) is an efficient reverse genetics technique for investigating gene function in eukaryotes. The method has been widely used in model organisms, such as the free-living nematode Caenorhabditis elegans, where it has been deployed in genome-wide high throughput screens to identify genes involved in many cellular and developmental processes. However, RNAi techniques have not translated efficiently to animal parasitic nematodes that afflict humans, livestock and companion animals across the globe, creating a dependency on data tentatively inferred from C. elegans. RESULTS: We report improved and effective in vitro RNAi procedures we have developed using heterogeneous short interfering RNA (hsiRNA) mixtures that when coupled with optimized immunostaining techniques yield detailed analysis of cytological defects in the human parasitic nematode, Brugia malayi. The cellular disorganization observed in B. malayi embryos following RNAi targeting the genes encoding γ-tubulin, and the polarity determinant protein, PAR-1, faithfully phenocopy the known defects associated with gene silencing of their C. elegans orthologs. Targeting the B. malayi cell junction protein, AJM-1 gave a similar but more severe phenotype than that observed in C. elegans. Cellular phenotypes induced by our in vitro RNAi procedure can be observed by immunofluorescence in as little as one week. CONCLUSIONS: We observed cytological defects following RNAi targeting all seven B. malayi transcripts tested and the phenotypes mirror those documented for orthologous genes in the model organism C. elegans. This highlights the reliability, effectiveness and specificity of our RNAi and immunostaining procedures. We anticipate that these techniques will be widely applicable to other important animal parasitic nematodes, which have hitherto been mostly refractory to such genetic analysis.

Localization of gender-regulated gene expression in the filarial nematode Brugia malayi.

We used in situ hybridization (ISH) to localize expression of gender-biased genes in the filarial parasite Brugia malayi that were previously identified by microarray analysis and quantitative reverse transcriptase PCR (qRT-PCR). We studied seven genes with male-biased expression, 11 genes with female-biased expression, and one control gene with equal expression in males and females. RNA probes were hybridized to frozen sections of adult worms. ISH confirmed gender-biased expression for all 18 of the differentially expressed genes and non-biased expression for the control. We identified six patterns of expression for these genes. As expected, most of the gender-biased genes were expressed in reproductive organs, developing gametes and embryos. Hybridization signal intensities correlated with relative mRNA levels as assessed by qRT-PCR. Some of the differentially expressed genes had tightly regulated expression patterns. For example, a high mobility group protein gene (Bm-hmg) was exclusively expressed in developing larvae in females. Expression was first detected in late stage oocytes, peaked in morula stage embryos and no signal was detected in late pretzel stage or in stretched microfilariae. Another female up-regulated gene (microfilarial sheath protein Bm-shp-1) was exclusively expressed in the epithelium of uterine sections that contained morulae or early pretzel embryos. No signal was detected in other female structures, in late embryos or in male worms. This result suggests that microfilarial sheath proteins are produced by the uterus epithelium and not by embryos. Transcripts of the male-upregulated major sperm protein-1 (Bm-msp-1) were detected in spermatocytes in the early spermatogenesis zone and in spermatids but not in spermatozoa in the vas deferens. Thus, ISH provides a means to independently confirm differential expression of genes identified by other methods. In addition, localization patterns provide insight regarding the function of known or novel genes in the parasite.

Sequences necessary for trans-splicing in transiently transfected Brugia malayi.

Many genes in parasitic nematodes are both cis- and trans-spliced. Previous studies have demonstrated that a 7nt element encoded in the first intron of the Brugia malayi 70kDa heat shock protein (BmHSP70) gene was necessary to permit trans-splicing of transgenic mRNAs in embryos transfected with constructs encoding portions of the BmHSP70 gene. Here we demonstrate that this element (the B. malayi HSP70 trans-splicing motif, or BmHSP70 TSM) is necessary and sufficient to direct trans-splicing of transgenic mRNAs derived from two genes naturally containing this motif. Mutations introduced into any position of the BmHSP70 TSM abrogated its ability to direct trans-splicing. Transgenic mRNAs derived from embryos transfected with constructs containing promoters and associated downstream domains from two normally trans-spliced genes that lack a BmHSP70 TSM homologue (the B. malayi 12kDa small subunit ribosomal protein (BmRPS12) gene and the B. malayi RNA-binding protein (BmRBP1) gene), were not trans-spliced. Transfer of the BmHSP70 TSM into the first intron of the BmRPS12 gene rendered it competent for trans-splicing. Insertion of the BmHSP70 TSM into the single intron of the BmRBP1 gene did not render it trans-splicing competent. However, tagged constructs of the full-length BmRBP1 gene were trans-splicing competent. An analysis of the first exons and introns of over 200 trans-spliced B. malayi genes found homologues for the BmHSP70 TSM in roughly 25%. Thus, while the BmHSP70 TSM is necessary and sufficient to direct trans-splicing in some genomic contexts, independent trans-splicing signals are employed by other genes.

Synthesis and activity of substituted anthraquinones against a human filarial parasite, Brugia malayi.

Lymphatic filariasis (elephantiasis) is a global public health problem caused by the parasitic nematodes Wuchereria bancrofti and Brugia malayi. We have previously reported anthraquinones from daylily roots with potent activity against pathogenic trematode Schistosoma mansoni. Here we report the synthesis of novel anthraquinones A-S and their antifilrarial activity. Anthraquinones A-S were synthesized by a single-step Friedel-Crafts acylation reaction between phthalic anhydrides and substituted benzenes. The antifilarial properties of these synthetic anthraquinones were tested against microfilaria as well as adult male and female worms of B. malayi. The most active anthraquinone was K, which showed 100% mortality within 1, 5, and 3 days, respectively, against microfilaria and adult male and female worms at 5 ppm concentration. Albendazole, an oral drug currently used to treat parasitic infections, was used as a positive control. Methylated products of anthraquinones did not affect the microfilaria. Histological examination of treated adult female parasites showed most of the anthraquinones caused marked effects on intrauterine embryos.

Search for new prototypes for the chemotherapy of filariasis: a chemotherapeutic and biochemical approach.

The antifilarial activity of two coumarin derivatives (A, B) and three glycosyl amine derivatives (D, E, F) was evaluated against a subperiodic strain of human lymphatic filarial parasite Brugia malayi by the intraperitoneal route at 50 mg/kg for 5 consecutive days. Of these, the two sugar derivatives (D and E) were selected for evaluation by the oral route based on their microfilaricidal (mild), macrofilaricidal and female worm sterilization efficacy using the i.p. route of administration. Compound E was finally selected for combination therapy on the basis of its microfilaricidal and embryostatic action by the oral route and its spectrum of activity against micro- and macrofilariae including embryostatic activity by the i.p. route. In addition, E also significantly inhibited the parasite DNA topoisomerase II. Compound A, in contrast, led to an enhanced adult worm burden. Compound B was toxic by the i.p. route, killing all of the treated animals before completion of the experiment. Some of these compounds demonstrated significant antifilarial efficacy of varying degree when tested in vitro Compounds B, D and F also killed adult B. malayi in vitro at 100 muM while 50 muM resulted in very slow motility of worms. Compound E in combination with a promising macrofilaricidal benzopyran derivative reported by us recently (compound C) did not show any synergistic or additive effect. These two compounds (C and E) individually on oral administration with either DEC or ivermectin significantly improved microfilaricidal efficacy in terms of intensity and duration of suppressed microfilaraemia. The combination of DEC with compound E demonstrated marginal enhancement in adulticidal efficacy, however, the embryostatic effect of the duo was significantly higher than that exerted by the individual agents. It may thus be inferred that in the absence of an adulticidal antifilarial drug, the use of potential antifilarials in combination with the standard filaricides may yield better results.

Brugia malayi: effects of gamma radiation on adult worms and their intracellular Wolbachia bacteria.

Prior studies have shown that intracellular Wolbachia endobacteria are necessary for the normal development, reproduction, and survival of filarial nematodes. The purpose of this study was to examine effects of gamma radiation on Wolbachia and reproduction in Brugia malayi adult worms. Worms were exposed to 0, 10, 25, 45, 75, and 105 krad of gamma radiation from a 137cesium source and cultured in vitro for 10 days. Irradiation reduced production of microfilariae in a dose-dependent manner. Embryograms of irradiated female worms showed dose-related abnormalities with arrested development at the early embryo stage. Irradiation reduced the viability of adult worms in a dose-dependent manner, but no lethal effect was observed. Electron microscopy studies showed that irradiation cleared Wolbachia from worm tissues. Real-time polymerase chain reaction studies demonstrated greatly reduced Wolbachia DNA in irradiated worms. These effects are essentially the same as those observed in adult worms treated with doxycycline. These studies suggest that effects of irradiation on reproduction in Brugia malayi may be caused by effects of irradiation on Wolbachia.

4-Methyl-7-(tetradecanoyl)-2H-1-benzopyran-2-one: a novel DNA topoisomerase II inhibitor with adulticidal and embryostatic activity against sub-periodic Brugia malayi.

A compound of the coumarin class, 4-methyl-7-(tetradecanoyl)-2H-1-benzopyran-2-one, was evaluated for antifilarial activity against the human filarial parasite, Brugia malayi (sub-periodic strain) in Mastomys coucha. The test compound brought about a 24.4% reduction in circulating microfilaremia on day 8 after initiation of treatment when administered by the peritoneal route at a dose of 50 mg/kg for 5 consecutive days. The compound also caused a 62.0% mortality in adult parasites. Apart from killing adult filariids, it also brought about sterilization of 81.8% of the surviving female B. malayi. An oral dose of 200 mg/kg for 5 consecutive days was less effective (35.5% adulticidal efficacy and 65.8% sterilization). In vitro, the compound killed adult B. malayi at 100 microM concentration and inhibited DNA topoisomerase II activity in the filarial parasite. Studies are in progress using the compound in combination with standard antifilarials as well as other active agents.

Analysis of the Brugia malayi HSP70 promoter using a homologous transient transfection system.

Biolistic transient transfection of Brugia malayi embryos with constructs driving the expression of a luciferase reporter gene was used to identify regions of the upstream sequence of the heat shock protein 70 (HSP70) gene of B. malayi necessary for transgene expression. Analysis of 1160 nucleotides upstream of the start codon of the HSP70 gene identified several potentially important elements, including putative CAAT and TATA boxes, a core promoter domain, a polypurine stretch, and a spliced leader addition site. Nested deletion analysis of the HSP70 upstream domain mapped the promoter of the HSP70 gene to the region 396 to 31 nucleotides upstream of the start codon. This encompassed the putative CAAT and TATA boxes, and putative core promoter. Deletion of the putative CAAT box did not result in any diminution of reporter activity, while constructs in which the TATA box or core promoter were deleted retained roughly half of the activity of the undeleted construct. Unlike the native gene, transcripts derived from constructs containing the HSP70 upstream sequences were not trans-spliced. However, incorporation of the 495 nucleotides downstream of the start codon (encompassing exon 1, intron 1 and part of exon 2) resulted in the production of transcripts that were correctly cis- and trans-spliced. Similarly, a construct containing the 495 downstream nucleotides in which most of exon 1 was deleted, was correctly cis- and trans-spliced. This finding suggests that downstream intron sequences in addition to the splice leader addition site are necessary for trans-splicing in B. malayi.

An embryo-associated fatty acid-binding protein in the filarial nematode Brugia malayi.

Brugia malayi is a filarial nematode parasite that causes lymphatic filariasis, a disease that affects millions of people in the tropics. Sexual reproduction of filarial worms occurs within the lymphatic vessels of the human host and is crucial for transmission of the parasite to the mosquito vector. We have previously identified several B. malayi genes that exhibit apparent gender-specific expression. One of these had significant sequence similarity to the Ascaris suum embryo-associated fatty acid binding protein, As-p18. The full length cDNA for the B. malayi female-associated fatty acid binding protein (Bm-FAB-1) encodes a 17.8 kDa protein (excluding a signal peptide) with 70% sequence identity with mature As-p18 and significant similarity to Caenorhabditis elegans and mammalian fatty acid-binding proteins (FABPs). Antibodies raised to Bm-FAB-1 bound to developing embryos within female worms, especially around early embryo cells and the surfaces of immature worms within eggs. Functional studies showed that recombinant Bm-FAB-1 binds to several long chain fatty acids including oleate, but not retinol. Taken together, these results demonstrate that Bm-FAB-1 is a member of an unusual nematode-specific, secreted lipid binding protein family. The existence of a novel class of lipid binding proteins in nematode embryos raises the possibility that drugs targeting these proteins could be developed with broad activity against nematode parasites of medical and veterinary importance.

Nitric oxide synthase in filariae: demonstration of nitric oxide production by embryos in Brugia malayi and Acanthocheilonema viteae.

The radical gas nitric oxide (NO) is synthesized by nitric oxide synthase (NOS) from l-arginine and molecular oxygen. Nitric oxide is an important signaling molecule in invertebrate and vertebrate systems. Previously we have shown that NOS is localized to more tissues in Brugia malayi than has been reported in Ascaris suum. In this paper, we analyze the distribution of NOS in Acanthocheilonema viteae, a filarial nematode that differs from B. malayi in that A. viteae females release microfilariae without a sheath. A. viteae is also one of a few filarial parasites without the Wolbachia intracellular endosymbiont. By use of a specific antibody, NOS was demonstrated in extracts of A. viteae and Dirofilaria immitis. The localization pattern of NOS in A. viteae was similar to that seen in B. malayi, with the enzyme localized to the body wall muscles of both sexes, developing spermatozoa, intrauterine sperm, and early embryos. By use of DAF-2, a fluorescent indicator specific for nitric oxide, the embryos of B. malayi and A. viteae were demonstrated to produce NO ex utero. The near identical staining patterns seen in A. viteae and B. malayi argue that NO is not produced by Wolbachia, nor is it produced by the nematodes in response to the infection. Localization of NOS to the sperm of filarial nematodes suggests a role for NO during fertilization as has been described for sea urchin and ascidian fertilization. Demonstration of the activity of embryonic NOS supports our earlier hypothesis that NO is a signaling molecule during embryogenesis in filarial nematodes.

Chitin synthase in the filarial parasite, Brugia malayi.

Fragments of putative chitin synthase (chs) genes from two filarial species (Brugia malayi and Dirofilaria immitis) were amplified by PCR using degenerate primers. The full genomic and cDNA sequences were obtained for the B. malayi chs gene (Bm-chs-1); the predicted amino acid sequence is highly similar, over a large region, to two CHS sequences of the nematode Caenorhabditis elegans and also to two insect CHS sequences. Bm-chs-1 is abundantly transcribed in B. malayi adult females, independent of their fertilization status, but is also expressed in males and microfilariae. Oocytes and early embryos contain large amounts of Bm-chs-1 transcript by in situ hybridization, but later stage embryos within the maternal uterus show little or no Bm-chs-1 transcript. No specific hybridization could be demonstrated in maternal somatic tissues. Polyclonal antibodies were raised against a peptide expressed from a recombinant cDNA fragment of Bm-chs-1; immunostaining detected CHS protein in oocytes and early to midstage embryos. These studies characterize a gene that is likely to be essential to oogenesis and embryonic development in a parasitic nematode. Because chitin synthesis and eggshell formation begin after fertilization, the presence of CHS protein in early oocytes suggests that the enzyme must be activated as a result of fertilization. These studies also demonstrate that chitin synthesis may not be restricted to eggshell formation in nematodes, as the Bm-chs-1 gene is transcribed in life cycle stages other than adult females.