Progress with schistosome transgenesis

Genome sequences for Schistosoma japonicum and Schistosoma mansoni are now available. The schistosome genome encodes ~13,000 protein encoding genes for which the function of only a minority is understood. There is a valuable role for transgenesis in functional genomic investigations of these new schistosome gene sequences. In gain-of-function approaches, transgenesis can lead to integration of transgenes into the schistosome genome which can facilitate insertional mutagenesis screens. By contrast, transgene driven, vector-based RNA interference (RNAi) offers powerful loss-of-function manipulations. Our laboratory has focused on development of tools to facilitate schistosome transgenesis. We have investigated the utility of retroviruses and transposons to transduce schistosomes. Vesicular stomatitis virus glycoprotein (VSVG) pseudotyped murine leukemia virus (MLV) can transduce developmental stages of S. mansoni including eggs. We have also observed that the piggyBac transposon is transpositionally active in schistosomes. Approaches with both VSVG-MLV and piggyBac have resulted in somatic transgenesis and have lead to integration of active reporter transgenes into schistosome chromosomes. These findings provided the first reports of integration of reporter transgenes into schistosome chromosomes. Experience with these systems is reviewed herewith, along with findings with transgene mediated RNAi and germ line transgenesis, in addition to pioneering and earlier reports of gene manipulation for schistosomes.     

Schistosoma mansoni genome project: an update

A schistosome genome project was initiated by the World Health Organization in 1994 with the notion that the best prospects for identifying new targets for drugs, vaccines, and diagnostic development lie in schistosome gene discovery, development of chromosome maps, whole genome sequencing and genome analysis. Schistosoma mansoni has a haploid genome of 270 Mb contained on 8 pairs of chromosomes. It is estimated that the S. mansoni genome contains between 15000 and 25000 genes. There are approximately 16689 ESTs obtained from diverse libraries representing different developmental stages of S. mansoni, deposited in the NCBI EST database. More than half of the deposited sequences correspond to genes of unknown function. Approximately 40-50% of the sequences form unique clusters, suggesting that approximately 20-25% of the total schistosome genes have been discovered. Efforts to develop low resolution chromosome maps are in progress. There is a genome sequencing program underway that will provide 3X sequence coverage of the S. mansoni genome that will result in approximately 95% gene discovery. The genomics era has provided the resources to usher in the era of functional genomics that will involve microarrays to focus on specific metabolic pathways, proteomics to identify relevant proteins and protein-protein interactions to understand critical parasite pathways. Functional genomics is expected to accelerate the development of control and treatment strategies for schistosomiasis.     

Evaluation of Schistosome Promoter Expression for Transgenesis and Genetic Analysis

Schistosome worms of the genus Schistosoma are the causative agents of schistosomiasis, a devastating parasitic disease affecting more than 240 million people worldwide. Schistosomes have complex life cycles, and have been challenging to manipulate genetically due to the dearth of molecular tools. Although the use of gene overexpression, gene knockouts or knockdowns are straight-forward genetic tools applied in many model systems, gene misexpression and genetic manipulation of schistosome genes in vivo has been exceptionally challenging, and plasmid based transfection inducing gene expression is limited. We recently reported the use of polyethyleneimine (PEI) as a simple and effective method for schistosome transfection and gene expression. Here, we use PEI-mediated schistosome plasmid transgenesis to define and compare gene expression profiles from endogenous and nonendogenous promoters in the schistosomula stage of schistosomes that are potentially useful to misexpress (underexpress or overexpress) gene product levels. In addition, we overexpress schistosome genes in vivo using a strong promoter and show plasmid-based misregulation of genes in schistosomes, producing a clear and distinct phenotype- death. These data focus on the schistosomula stage, but they foreshadow strong potential for genetic characterization of schistosome molecular pathways, and potential for use in overexpression screens and drug resistance studies in schistosomes using plasmid-based gene expression.     

Transgenesis of schistosomes: approaches employing mobile genetic elements

Draft genome sequences for Schistosoma mansoni and Schistosoma japonicum are now available. However, the identity and importance of most schistosome genes have yet to be determined. Recently, progress has been made towards the genetic manipulation and transgenesis of schistosomes. Both loss-of-function and gain-of-function approaches appear to be feasible in schistosomes based on findings described in the past 5 years. This review focuses on reports of schistosome transgenesis, specifically those dealing with the transformation of schistosomes with exogenous mobile genetic elements and/or their endogenous relatives for the genetic manipulation of schistosomes. Transgenesis mediated by mobile genetic elements offers a potentially tractable route to introduce foreign genes to schistosomes, a means to determine the importance of schistosome genes, including those that could be targeted in novel interventions and the potential to undertake large-scale forward genetics by insertional mutagenesis.     

Human U6 promoter drives stronger shRNA activity than its schistosome orthologue in Schistosoma mansoni and human fibrosarcoma cells

Blood flukes or schistosomes are the causative agents of human schistosomiasis, one of the major neglected tropical diseases. Draft genome sequences have been reported for schistosomes, but functional genomics tools are needed to investigate the role and essentiality of the newly reported genes. Vector based RNA interference can contribute to functional genomics analysis for schistosomes. Using mRNA encoding reporter firefly luciferase as a model target, we compared the performance of a schistosome and a human promoter from the U6 gene in driving shRNA in human fibrosarcoma cells and in cultured schistosomes. Further, both a retroviral [Murine leukemia virus (MLV)] and plasmid (piggyBac, pXL-Bac II) vector were utilized. The schistosome U6 gene promoter was 270 bp in length, the human U6 gene promoter was 264 bp; they shared 41% identity. Following transduction of both HT1080 fibrosarcoma cells and schistosomules of Schistosoma mansoni with pseudotyped MLV virions, stronger knockdown of luciferase activity was seen with the virions encoding the human U6 promoter driven shRNA than the schistosome U6 promoter. A similar trend was seen after transfection of HT1080 cells and schistosomules with the pXL-Bac-II constructs-stronger knockdown of luciferase activity was seen with constructs encoding the human compared to schistosome U6 promoter. The findings indicate that a human U6 gene promoter drives stronger shRNA activity than its schistosome orthologue, not only in a human cancer cell line but also in larval schistosomes. This RNA polymerase III promoter represents a potentially valuable component for vector based RNA interference studies in schistosomes and related platyhelminth parasites.     

Pseudotyped murine leukemia virus for schistosome transgenesis: approaches,methods and perspectives

Draft genome sequences for the human schistosomes, Schistosoma japonicum, S. mansoni and S. haematobium are now available. The schistosome genome contains ~11,000 protein encoding genes for which the functions of few are well understood. Nonetheless, the newly described gene products and novel non-coding RNAs represent potential intervention targets, and molecular tools are being developed to determine their importance. Over the past decade, noteworthy advances has been reported towards development of tools for gene manipulation of schistosomes, including gene expression perturbation by RNAi, and transient and stable transfection including transgenesis mediated by genome integration competent vectors. Retrovirus-mediated transgenesis is an established functional genomic approach for model species. It offers the means to establish gain- or loss-of-function phenotypes, supports vector-based RNA interference, and represents a powerful forward genetics tool for insertional mutagenesis. Murine leukemia virus (MLV) pseudotyped with vesicular stomatitis virus glycoprotein mediates somatic transgenesis in S. mansoni, and vertical transmission of integrated transgenes in S. mansoni has been demonstrated, leading the establishment of transgenic lines. In addition, MLV transgenes encoding antibiotic resistance allow the selection of MLV-transduced parasites with the appropriate antibiotics. Here we describe detailed methods to produce and quantify pseudotyped MLV particles for use in transducing developmental stages of schistosomes. Approaches to analyze MLV-transduced schistosomes, including qPCR and high throughput approaches to verify and map genome integration of transgenes are also presented. We anticipate these tools should find utility in genetic investigations in other laboratories and for other helminth pathogens of important neglected tropical diseases.     

FISH techniques for constructing physical maps on schistosome chromosomes

In an effort to provide useful information about parasites important in tropical diseases, the WHO has initiated genome mapping projects for a number of parasites. One goal of this effort is to establish physical maps of the genomes of the targeted parasites. Multicellular parasites (helminths) contain various numbers of chromosomes, some large, that condense during the cell cycle. Here Hirohisa Hirai and Phil LoVerde present details of fluorescence in situ hybridization as a means to localize genes and DNA fragments to schistosome chromosomes. Although the techniques presented are for schistosome chromosomes, they are applicable to any system where the chromosomes condense at metaphase.     

日本血吸虫期别差异表达基因文库的构建及分析

为从期别差异表达基因分析入手研究血吸虫的生长发育机制,应用抑制性消减杂交 (suppressed subtractive hybridization , SSH) 技术首次构建了日本血吸虫尾蚴、虫卵和成虫的期别差异表达基因文库 . 经消减效率分析和三种文库克隆的 EST 的期别差异性鉴定,表明所建文库质量较高,为在整个基因组水平分离血吸虫的差异表达基因提供了重要材料 . 由三个文库选择 257 个插入片段大于 500 bp 的克隆测定了 EST 序列 . 同源性分析结果表明 257 个 EST 代表 182 种血吸虫基因,其中有 22 种为血吸虫已知基因,有 128 种为血吸虫已知 EST ,有 32 种为新发现的血吸虫基因 . 对 EST 编码蛋白的功能预测结果显示：尾蚴消减文库的基因多与运动、能量代谢、转录调节及致病性相关;虫卵消减文库的基因可能参与信号转导、细胞粘附、蛋白质和碳水化合物的代谢以及抗氧化反应;成虫消减文库的基因多参与蛋白质的合成、转运及分解代谢,参与虫体的运动等 . 大规模分离、分析血吸虫期别差异表达基因将对从分子水平去解读血吸虫的生长发育机制,筛选高效疫苗候选抗原、药物靶标及诊断制剂有重要意义 .     

Differential Spatial Repositioning of Activated Genes in Biomphalaria glabrata Snails Infected with Schistosoma mansoni

Schistosomiasis is an infectious disease infecting mammals as the definitive host and fresh water snails as the intermediate host. Understanding the molecular and biochemical relationship between the causative schistosome parasite and its hosts will be key to understanding and ultimately treating and/or eradicating the disease. There is increasing evidence that pathogens that have co-evolved with their hosts can manipulate their hosts'' behaviour at various levels to augment an infection. Bacteria, for example, can induce beneficial chromatin remodelling of the host genome. We have previously shown in vitro that Biomphalaria glabrata embryonic cells co-cultured with schistosome miracidia display genes changing their nuclear location and becoming up-regulated. This also happens in vivo in live intact snails, where early exposure to miracidia also elicits non-random repositioning of genes. We reveal differences in the nuclear repositioning between the response of parasite susceptible snails as compared to resistant snails and with normal or live, attenuated parasites. Interestingly, the stress response gene heat shock protein (Hsp) 70 is only repositioned and then up-regulated in susceptible snails with the normal parasite. This movement and change in gene expression seems to be controlled by the parasite. Other differences in the behaviour of genes support the view that some genes are responding to tissue damage, for example the ferritin genes move and are up-regulated whether the snails are either susceptible or resistant and upon exposure to either normal or attenuated parasite. This is the first time host genome reorganisation has been seen in a parasitic host and only the second time for any pathogen. We believe that the parasite elicits a spatio-epigenetic reorganisation of the host genome to induce favourable gene expression for itself and this might represent a fundamental mechanism present in the human host infected with schistosome cercariae as well as in other host-pathogen relationships.     

Potential applications of equine genomics in dissecting diseases and fertility

Following the recent development of high-resolution gene maps and generation of several basic tools and resources to use them in analyzing traits that are economically important to horse owners, genome analysis in horses is witnessing a shift towards developing an ability to analyze complex traits. The likelihood of this happening in the very near future is great, mainly because of the recent availability of the whole genome sequence in the horse. The latter has triggered the development of novel tools like SNP-chip and expression arrays that will permit rapid genome-wide analysis. While these tools will be used for a range of multi-factorial disease traits, attempts are underway to develop focused tools that can target reproduction, fertility and sex determination. For this, a catalog of sex and reproduction related (SRR) genes is being developed in horses. A recently developed dense map of the horse Y chromosome will provide genes that are expressed exclusively in males and, therefore, have an impact on stallion fertility. Overall, these advances in equine genome analysis hold promise for improved diagnosis and treatment of various conditions in horses.