Genomic-Bioinformatic Analysis of Transcripts Enriched in the Third-Stage Larva of the Parasitic Nematode Ascaris suum

Differential transcription in Ascaris suum was investigated using a genomic-bioinformatic approach. A cDNA archive enriched for molecules in the infective third-stage larva (L3) of A. suum was constructed by suppressive-subtractive hybridization (SSH), and a subset of cDNAs from 3075 clones subjected to microarray analysis using cDNA probes derived from RNA from different developmental stages of A. suum. The cDNAs (n = 498) shown by microarray analysis to be enriched in the L3 were sequenced and subjected to bioinformatic analyses using a semi-automated pipeline (ESTExplorer). Using gene ontology (GO), 235 of these molecules were assigned to ‘biological process’ (n = 68), ‘cellular component’ (n = 50), or ‘molecular function’ (n = 117). Of the 91 clusters assembled, 56 molecules (61.5%) had homologues/orthologues in the free-living nematodes Caenorhabditis elegans and C. briggsae and/or other organisms, whereas 35 (38.5%) had no significant similarity to any sequences available in current gene databases. Transcripts encoding protein kinases, protein phosphatases (and their precursors), and enolases were abundantly represented in the L3 of A. suum, as were molecules involved in cellular processes, such as ubiquitination and proteasome function, gene transcription, protein–protein interactions, and function. In silico analyses inferred the C. elegans orthologues/homologues (n = 50) to be involved in apoptosis and insulin signaling (2%), ATP synthesis (2%), carbon metabolism (6%), fatty acid biosynthesis (2%), gap junction (2%), glucose metabolism (6%), or porphyrin metabolism (2%), although 34 (68%) of them could not be mapped to a specific metabolic pathway. Small numbers of these 50 molecules were predicted to be secreted (10%), anchored (2%), and/or transmembrane (12%) proteins. Functionally, 17 (34%) of them were predicted to be associated with (non-wild-type) RNAi phenotypes in C. elegans, the majority being embryonic lethality (Emb) (13 types; 58.8%), larval arrest (Lva) (23.5%) and larval lethality (Lvl) (47%). A genetic interaction network was predicted for these 17 C. elegans orthologues, revealing highly significant interactions for nine molecules associated with embryonic and larval development (66.9%), information storage and processing (5.1%), cellular processing and signaling (15.2%), metabolism (6.1%), and unknown function (6.7%). The potential roles of these molecules in development are discussed in relation to the known roles of their homologues/orthologues in C. elegans and some other nematodes. The results of the present study provide a basis for future functional genomic studies to elucidate molecular aspects governing larval developmental processes in A. suum and/or the transition to parasitism.

[1]  M. Blaxter,et al.  Functional genomics for parasitic nematodes and platyhelminths. , 2004, Trends in parasitology.

[2]  C. Mello,et al.  Revealing the world of RNA interference , 2004, Nature.

[3]  A. Krogh,et al.  Predicting transmembrane protein topology with a hidden Markov model: application to complete genomes. , 2001, Journal of molecular biology.

[4]  V. Reinke,et al.  A global profile of germline gene expression in C. elegans. , 2000, Molecular cell.

[5]  Asako Sugimoto,et al.  High-throughput RNAi in Caenorhabditis elegans: genome-wide screens and functional genomics. , 2004, Differentiation; research in biological diversity.

[6]  Y. Dong,et al.  Systematic functional analysis of the Caenorhabditis elegans genome using RNAi , 2003, Nature.

[7]  J. Berg Genome sequence of the nematode C. elegans: a platform for investigating biology. , 1998, Science.

[8]  K. Bennett,et al.  Cross-species RNAi: selected Ascaris suum dsRNAs can sterilize Caenorhabditis elegans. , 2006, Molecular and biochemical parasitology.

[9]  R. Gasser,et al.  Experimental infections of pigs and mice with selected genotypes of Ascaris , 2006, Parasitology.

[10]  P. Geldhof,et al.  RNA interference in parasitic nematodes of animals: a reality check? , 2007, Trends in parasitology.

[11]  M. Blaxter,et al.  Caenorhabditis elegans is a nematode. , 1998, Science.

[12]  Weiwei Zhong,et al.  Genome-Wide Prediction of C. elegans Genetic Interactions , 2006, Science.

[13]  P. Boag,et al.  Molecular aspects of sexual development and reproduction in nematodes and schistosomes. , 2001, Advances in parasitology.

[14]  S. Dudoit,et al.  Normalization for cDNA microarray data: a robust composite method addressing single and multiple slide systematic variation. , 2002, Nucleic acids research.

[15]  Erik L. L. Sonnhammer,et al.  A Hidden Markov Model for Predicting Transmembrane Helices in Protein Sequences , 1998, ISMB.

[16]  J. Foster,et al.  Mining nematode genome data for novel drug targets. , 2005, Trends in parasitology.

[17]  Andrew Smith Genome sequence of the nematode C-elegans: A platform for investigating biology , 1998 .

[18]  R. Gasser,et al.  Recent insights into the epidemiology and genetics of Ascaris in China using molecular tools , 2006, Parasitology.

[19]  J. Brewer,et al.  The structure of yeast enolase at 2.25-A resolution. An 8-fold beta + alpha-barrel with a novel beta beta alpha alpha (beta alpha)6 topology. , 1989, The Journal of biological chemistry.

[20]  V. Reinke,et al.  Genome-wide analysis of developmental and sex-regulated gene expression profiles in Caenorhabditis elegans. , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[21]  F. Frandsen,et al.  DIFFERENTIATION OF CUTICULAR STRUCTURES DURING THE GROWTH OF THE THIRD-STAGE LARVA OF ASCARIS SUUM (NEMATODA, ASCARIDOIDEA) AFTER EMERGING FROM THE EGG , 2000, The Journal of parasitology.

[22]  Andrew G Fraser,et al.  Genome-Wide RNAi of C. elegans Using the Hypersensitive rrf-3 Strain Reveals Novel Gene Functions , 2003, PLoS biology.

[23]  Anders Krogh,et al.  Prediction of Signal Peptides and Signal Anchors by a Hidden Markov Model , 1998, ISMB.

[24]  H. Mersmann,et al.  Distribution and quantification of beta1-, beta2-, and beta3-adrenergic receptor subtype transcripts in porcine tissues. , 1999, Journal of animal science.

[25]  Paul Horton,et al.  Nucleic Acids Research Advance Access published May 21, 2007 WoLF PSORT: protein localization predictor , 2007 .

[26]  T. Yoshino,et al.  Gene manipulation in parasitic helminths. , 2003, International journal for parasitology.

[27]  Peter J Hotez,et al.  Soil-transmitted helminth infections: ascariasis, trichuriasis, and hookworm , 2006, The Lancet.

[28]  Mark L. Blaxter,et al.  NEMBASE: a resource for parasitic nematode ESTs , 2004, Nucleic Acids Res..

[29]  S. Hashmi,et al.  Caenorhabditis elegans and the study of gene function in parasites. , 2001, Trends in parasitology.

[30]  G. Saunders,et al.  RNA interference in parasitic helminths: current situation, potential pitfalls and future prospects , 2006, Parasitology.

[31]  W. Pomroy,et al.  Anthelmintic resistance in New Zealand: A perspective on recent findings and options for the future , 2006, New Zealand veterinary journal.

[32]  Sang Kyun Park,et al.  Anisakis simplex: analysis of expressed sequence tags (ESTs) of third-stage larva. , 2007, Experimental parasitology.

[33]  Makedonka Mitreva,et al.  Parasitic nematodes - from genomes to control. , 2007, Veterinary parasitology.

[34]  R. Kamath,et al.  Genome-wide RNAi screening in Caenorhabditis elegans. , 2003, Methods.

[35]  F. G. Tromba,et al.  Morphogenesis and migration of Ascaris suum larvae developing to fourth stage in swine. , 1969, The Journal of parasitology.

[36]  S. Brunak,et al.  Improved prediction of signal peptides: SignalP 3.0. , 2004, Journal of molecular biology.

[37]  A. Fire,et al.  Potent and specific genetic interference by double-stranded RNA in Caenorhabditis elegans , 1998, Nature.

[38]  G. Ruvkun,et al.  A common muscarinic pathway for diapause recovery in the distantly related nematode species Caenorhabditis elegans and Ancylostoma caninum. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[39]  D. Knox Technological advances and genomics in metazoan parasites. , 2004, International journal for parasitology.

[40]  A. Roepstorff,et al.  Improved method for the recovery of Ascarus suum larvae from pig intestinal mucosa. , 1997, The Journal of parasitology.

[41]  R. Gasser,et al.  Construction of gender-enriched cDNA archives for adult Oesophagostomum dentatum by suppressive-subtractive hybridization and a microarray analysis of expressed sequence tags , 2006, Parasitology.

[42]  G. Gibson,et al.  Gene expression profiles associated with the transition to parasitism in Ancylostoma caninum larvae. , 2005, Molecular and biochemical parasitology.

[43]  R. Isaac,et al.  Functional genomics of parasitic worms: the dawn of a new era. , 2002, Parasitology international.

[44]  S. Brunak,et al.  SHORT COMMUNICATION Identification of prokaryotic and eukaryotic signal peptides and prediction of their cleavage sites , 1997 .

[45]  M. Ashburner,et al.  Gene Ontology: tool for the unification of biology , 2000, Nature Genetics.

[46]  P. A. Madden,et al.  Differentiation of Late Fourth and Early Fifth Stages of Ascaris suum Goeze, 1782 (Nematoda: Ascaridoidea) in Swine , 1981 .

[47]  Shivashankar H. Nagaraj,et al.  Gender-enriched transcripts in Haemonchus contortus--predicted functions and genetic interactions based on comparative analyses with Caenorhabditis elegans. , 2008, International journal for parasitology.

[48]  J. de la Cruz,et al.  Fal1p is an essential DEAD-box protein involved in 40S-ribosomal-subunit biogenesis in Saccharomyces cerevisiae , 1997, Molecular and cellular biology.

[49]  Robin B Gasser,et al.  Profiling of gender-specific gene expression for Trichostrongylus vitrinus (Nematoda: Strongylida) by microarray analysis of expressed sequence tag libraries constructed by suppressive-subtractive hybridisation. , 2004, International journal for parasitology.

[50]  R. Gasser,et al.  Extending from PARs in Caenorhabditis elegans to homologues in Haemonchus contortus and other parasitic nematodes , 2006, Parasitology.

[51]  Linda A. Murray,et al.  Using Caenorhabditis elegans for functional analysis of genes of parasitic nematodes. , 2006, International journal for parasitology.

[52]  Shivashankar H. Nagaraj,et al.  Transcriptional Changes in the Hookworm, Ancylostoma caninum, during the Transition from a Free-Living to a Parasitic Larva , 2008, PLoS neglected tropical diseases.

[53]  D. Riddle C. Elegans II , 1998 .

[54]  R. Barstead,et al.  Genome-wide RNAi. , 2001, Current opinion in chemical biology.

[55]  R. Beech,et al.  Population genetics of anthelmintic resistance in parasitic nematodes , 2007, Parasitology.

[56]  W. Wood,et al.  Onset of C. elegans gastrulation is blocked by inhibition of embryonic transcription with an RNA polymerase antisense RNA. , 1996, Developmental biology.

[57]  N. Gray,et al.  The roles of cytoplasmic poly(A)-binding proteins in regulating gene expression: a developmental perspective. , 2004, Briefings in functional genomics & proteomics.

[58]  Joshua M. Stuart,et al.  A Gene Expression Map for Caenorhabditis elegans , 2001, Science.

[59]  J. Urban,et al.  Factors contributing to the in vitro development of Ascaris suum from second-stage larvae to mature adults. , 1983, The Journal of parasitology.

[60]  J. Hawdon,et al.  Phosphoinositide-3-OH-kinase inhibitor LY294002 prevents activation of Ancylostoma caninum and Ancylostoma ceylanicum third-stage infective larvae. , 2004, International journal for parasitology.

[61]  J. Kaplan,et al.  The EGL-3 Proprotein Convertase Regulates Mechanosensory Responses of Caenorhabditis elegans , 2001, The Journal of Neuroscience.

[62]  A. Coulson,et al.  Full-genome RNAi profiling of early embryogenesis in Caenorhabditis elegans , 2005, Nature.

[63]  I. Fairweather,et al.  Drug resistance in veterinary helminths. , 2004, Trends in parasitology.

[64]  B. Besier New anthelmintics for livestock: the time is right. , 2007, Trends in parasitology.

[65]  Manabu Yamada,et al.  Pyrophosphatase of the Roundworm Ascaris suum Plays an Essential Role in the Worm's Molting and Development , 2005, Infection and Immunity.

[66]  P. Nansen,et al.  Effects of bile on the in vitro hatching, exsheathment, and migration of Ascaris suum larvae , 2000, Parasitology Research.

[67]  J. López-Abán,et al.  Antigens from Ascaris suum trigger in vitro macrophage NO production , 2005, Parasite immunology.

[68]  T R Bürglin,et al.  Caenorhabditis elegans as a model for parasitic nematodes. , 1998, International journal for parasitology.

[69]  R. Gasser,et al.  Molecular biology of reproduction and development in parasitic nematodes: progress and opportunities. , 2004, International journal for parasitology.

[70]  Rolf Apweiler,et al.  Evaluation of methods for the prediction of membrane spanning regions , 2001, Bioinform..