Interdomain lateral gene transfer of an essential ferrochelatase gene in human parasitic nematodes.

Lateral gene transfer events between bacteria and animals highlight an avenue for evolutionary genomic loss/gain of function. Herein, we report functional lateral gene transfer in animal parasitic nematodes. Members of the Nematoda are heme auxotrophs, lacking the ability to synthesize heme; however, the human filarial parasite Brugia malayi has acquired a bacterial gene encoding ferrochelatase (BmFeCH), the terminal step in heme biosynthesis. BmFeCH, encoded by a 9-exon gene, is a mitochondrial-targeted, functional ferrochelatase based on enzyme assays, complementation, and inhibitor studies. Homologs have been identified in several filariae and a nonfilarial nematode. RNAi and ex vivo inhibitor experiments indicate that BmFeCH is essential for viability, validating it as a potential target for filariasis control.

Multiplex proteomics analysis of gender-associated proteins in Brugia malayi.

Gender-associated (GA) genes are important for the development and reproduction of filarial nematodes. Identification and characterization of GA genes may provide insight into major pathways and processes involved in development and reproduction. The recent completion of the Brugia malayi genome has provided a good foundation for proteomics studies. Multiplex protein labelling and two-dimensional difference in-gel electrophoresis (2D-DIGE) combined with MALDI-TOF/TOF tandem MS were used to identify GA proteins. Thirty male and 32 female associated proteins were identified in this study. Many of these GA genes have homologues in Caenorhabditis elegans (83% male and 69% female), and most of the homologues have severe RNA interference (RNAi) phenotypes (72% male and 55% female) in C. elegans. Functional analysis showed that the male-associated genes are enriched for energy production, metabolic processes and cytoskeleton, while the female-associated genes are enriched for RNA modification and transcription. GA genes encode many excreted/secreted proteins. In situ localization studies showed that GA genes are mainly expressed in reproductive organs, and this is further evidence for their involvement in reproduction. Improved understanding of the basic biology of filarial nematodes may lead to improved tools for prevention and treatment of filarial infections. This study combined proteomics, in situ hybridization (ISH) and bioinformatics in a systems biology approach to improve understanding of gender differences and key proteins involved in reproduction in filarial worms. Advanced proteomics methods and bioinformatics led to the identification of 62 GA proteins for B. malayi. ISH revealed that most of those GA genes are expressed during embryogenesis or spermatogenesis. ISH results were consistent with RNAi data for C. elegans that linked the homologues of the B. malayi proteins to gamete production and embryogenesis.

Tissue and stage-specific distribution of Wolbachia in Brugia malayi.

BACKGROUND: Most filarial parasite species contain Wolbachia, obligatory bacterial endosymbionts that are crucial for filarial development and reproduction. They are targets for alternative chemotherapy, but their role in the biology of filarial nematodes is not well understood. Light microscopy provides important information on morphology, localization and potential function of these bacteria. Surprisingly, immunohistology and in situ hybridization techniques have not been widely used to monitor Wolbachia distribution during the filarial life cycle. METHODS/PRINCIPAL FINDINGS: A monoclonal antibody directed against Wolbachia surface protein and in situ hybridization targeting Wolbachia 16S rRNA were used to monitor Wolbachia during the life cycle of B. malayi. In microfilariae and vector stage larvae only a few cells contain Wolbachia. In contrast, large numbers of Wolbachia were detected in the lateral chords of L4 larvae, but no endobacteria were detected in the genital primordium. In young adult worms (5 weeks p.i.), a massive expansion of Wolbachia was observed in the lateral chords adjacent to ovaries or testis, but no endobacteria were detected in the growth zone of the ovaries, uterus, the growth zone of the testis or the vas deferens. Confocal laser scanning and transmission electron microscopy showed that numerous Wolbachia are aligned towards the developing ovaries and single endobacteria were detected in the germline. In inseminated females (8 weeks p.i.) Wolbachia were observed in the ovaries, embryos and in decreasing numbers in the lateral chords. In young males Wolbachia were found in distinct zones of the testis and in large numbers in the lateral chords in the vicinity of testicular tissue but never in mature spermatids or spermatozoa. CONCLUSIONS: Immunohistology and in situ hybridization show distinct tissue and stage specific distribution patterns for Wolbachia in B. malayi. Extensive multiplication of Wolbachia occurs in the lateral chords of L4 and young adults adjacent to germline cells.

Targeting protein-protein interactions for parasite control.

Finding new drug targets for pathogenic infections would be of great utility for humanity, as there is a large need to develop new drugs to fight infections due to the developing resistance and side effects of current treatments. Current drug targets for pathogen infections involve only a single protein. However, proteins rarely act in isolation, and the majority of biological processes occur via interactions with other proteins, so protein-protein interactions (PPIs) offer a realm of unexplored potential drug targets and are thought to be the next-generation of drug targets. Parasitic worms were chosen for this study because they have deleterious effects on human health, livestock, and plants, costing society billions of dollars annually and many sequenced genomes are available. In this study, we present a computational approach that utilizes whole genomes of 6 parasitic and 1 free-living worm species and 2 hosts. The species were placed in orthologous groups, then binned in species-specific orthologous groups. Proteins that are essential and conserved among species that span a phyla are of greatest value, as they provide foundations for developing broad-control strategies. Two PPI databases were used to find PPIs within the species specific bins. PPIs with unique helminth proteins and helminth proteins with unique features relative to the host, such as indels, were prioritized as drug targets. The PPIs were scored based on RNAi phenotype and homology to the PDB (Protein DataBank). EST data for the various life stages, GO annotation, and druggability were also taken into consideration. Several PPIs emerged from this study as potential drug targets. A few interactions were supported by co-localization of expression in M. incognita (plant parasite) and B. malayi (H. sapiens parasite), which have extremely different modes of parasitism. As more genomes of pathogens are sequenced and PPI databases expanded, this methodology will become increasingly applicable.

Gender-associated genes in filarial nematodes are important for reproduction and potential intervention targets.

BACKGROUND: A better understanding of reproductive processes in parasitic nematodes may lead to development of new anthelmintics and control strategies for combating disabling and disfiguring neglected tropical diseases such as lymphatic filariasis and onchocerciasis. Transcriptomatic analysis has provided important new insights into mechanisms of reproduction and development in other invertebrates. We have performed the first genome-wide analysis of gender-associated (GA) gene expression in a filarial nematode to improve understanding of key reproductive processes in these parasites. METHODOLOGY/PRINCIPAL FINDINGS: The Version 2 Filarial Microarray with 18,104 elements representing ∼85% of the filarial genome was used to identify GA gene transcripts in adult Brugia malayi worms. Approximately 19% of 14,293 genes were identified as GA genes. Many GA genes have potential Caenorhabditis elegans homologues annotated as germline-, oogenesis-, spermatogenesis-, and early embryogenesis- enriched. The potential C. elegans homologues of the filarial GA genes have a higher frequency of severe RNAi phenotypes (such as lethal and sterility) than other C. elegans genes. Molecular functions and biological processes associated with GA genes were gender-segregated. Peptidase, ligase, transferase, regulator activity for kinase and transcription, and rRNA and lipid binding were associated with female GA genes. In contrast, catalytic activity from kinase, ATP, and carbohydrate binding were associated with male GA genes. Cell cycle, transcription, translation, and biological regulation were increased in females, whereas metabolic processes of phosphate and carbohydrate metabolism, energy generation, and cell communication were increased in males. Significantly enriched pathways in females were associated with cell growth and protein synthesis, whereas metabolic pathways such as pentose phosphate and energy production pathways were enriched in males. There were also striking gender differences in environmental information processing and cell communication pathways. Many proteins encoded by GA genes are secreted by Brugia malayi, and these encode immunomodulatory molecules such as antioxidants and host cytokine mimics. Expression of many GA genes has been recently reported to be suppressed by tetracycline, which blocks reproduction in female Brugia malayi. Our localization of GA transcripts in filarial reproductive organs supports the hypothesis that these genes encode proteins involved in reproduction. CONCLUSIONS/SIGNIFICANCE: Genome-wide expression profiling coupled with a robust bioinformatics analysis has greatly expanded our understanding of the molecular biology of reproduction in filarial nematodes. This study has highlighted key molecules and pathways associated with reproductive and other biological processes and identified numerous potential candidates for rational drug design to target reproductive processes.

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.

Molecular mapping of developing dorsal horn-enriched genes by microarray and dorsal/ventral subtractive screening.

The dorsal horn of the spinal cord consists of distinct laminae that serve as a pivotal region for relaying a variety of somatosensory signals such as temperature, pain, and touch. The molecular mechanisms underlying the development of the dorsal horn are poorly understood. To define a molecular map of the dorsal horn circuit, we have profiled dorsal horn-enriched (DHE) gene expression in dorsal spinal cords on embryonic day 15.5 (E15.5) by genome-wide microarray and smart subtractive screening based on polymerase chain reaction (PCR). High-throughput in situ hybridization (ISH) was carried out to validate the expression of 379 genes in the developing dorsal spinal cord. A total of 113 DHE genes were identified, of which 59% show lamina-specific expression patterns. Most lamina-specific genes were expressed across at least two laminae, however. About 32% of all DHE genes are transcription factors, which represent the largest percentage of the group of all DHE functional classifications. Importantly, several individual lamina-specific transcription factors such c-Maf, Rora, and Satb1 are identified for the first time. Epistasis studies revealed several putative effectors of known DHE transcription factors such as Drg11, Tlx3(Rnx), and Lmx1b. These effector genes, including Grp, Trpc3, Pcp4, and Enc1, have been implicated in synaptic transmission, calcium homeostasis, and structural function and thus may have similar roles in the dorsal horn. The identification of a large number of DHE genes, especially those that are lamina specific, lays a foundation for future studies on the molecular machinery that controls the development of the dorsal horn and on functional differences of these distinct laminae in the dorsal spinal cord.

TCP10L is expressed specifically in spermatogenic cells and binds to death associated protein kinase-3.

The human transcriptional factor T-complex protein 10 like (TCP10L) gene is expressed exclusively in the liver and testis. However, the function of TCP10L in the testis remains unknown. We examined the expression of TCP10L in human testis and found that TCP10L was expressed specifically in the nucleus of spermatogenic cells during spermatogenesis. In addition, we identified death associated protein kinase 3 (DAPK-3/ZIP kinase) as a binding partner for TCP10L by yeast two-hybrid screening, followed with immunoprecipitation and subcellular localization experiments. Mutagenesis study revealed that this interaction was dependant on the leucine zipper motif-containing region. The specific expression pattern of TCP10L and interaction with DAPK-3 implies that TCP10L might play crucially important roles in spermatogenesis through its interaction with DAPK-3.

Human liver specific transcriptional factor TCP10L binds to MAD4.

A human gene T-complex protein 10 like (TCP10L) was cloned in our lab. A previous study showed that it expressed specifically in the liver and testis. A transcription experiment revealed that TCP10L was a transcription factor with transcription inhibition activity. In this study, the human MAD4 was identified to interact with TCP10L by a yeast two-hybrid screen. This finding was confirmed by immunoprecipitation and subcellular localization experiments. As MAD4 is a member of the MAD family, which antagonizes the functions of MYC and promotes cell differentiation, the biological function of the interaction between TCP10L and MAD4 may be to maintain the differentiation state in liver cells. Also, we propose that the up-regulation of Myc is caused by the down-regulation of TCP10L in human hepatocarcinomas.

Identification of a novel liver-specific expressed gene, TCP10L, encoding a human leucine zipper protein with transcription inhibition activity.

The incidence of hepatoma is high in the Chinese population. Searching for genes involved in the functions of the liver, especially genes specifically expressed in the liver, will facilitate an insight into the molecular basis of normal and abnormal liver functions. Based on a differentially displayed cDNA fragment, which was down regulated in hepatoma tissues, we cloned a novel cDNA of 957 bp, TCP10L (T-complex protein 10 like), from the human liver cDNA library. Northern hybridization of this novel gene in 30 adult human tissues was examined. The result revealed that TCP10L expressed specifically in the human liver and testis. The TCP10L contains a 645-bp open reading frame encoding a deduced protein of 215 amino acids. As the deduced protein was analyzed further, a typical leucine zipper motif was found. We firstly examined the transcriptional function of the TCP10L protein by transfecting recombinant pM-TCP10L into mammalian cells. The subsequent analysis based on the dual luciferase assay system showed that TCP10L significantly inhibited the expression of reporter genes. Compared with that of the negative control, the luciferase activity were down regulated in HEK293 and SK-HEP-1, CHO cells by about 2.6, 9.8, and 5.5 folds respectively. A mutated type of TCP10L was also constructed. It showed that the repression of TCP10L to the expression of the reporter gene almost completely decreased, suggesting that the leucine zipper structure is critical for TCP10L to play its role in regulation function. Then we transfected the recombinant TCP10L-EGFP into cells. The results indicated that TCP10L subcellularly located in nuclei, either in HEK 293 or SK-HEP-1 cells. In addition, human TCP10L was found comprised of five exons and four introns, and mapped to chromosome 21q22.11.