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Weinstock L, Waterston RH, Cooper JA, Coulson AR, Jones M, Hillier L, Wohldmann P, Green P, Roopra A, Smalldon N, Hawkins TL, Favello A, Durbin RM, Bonfield J, Saunders D, Anderson K, Kershaw JK, Sonnhammer ELL, Kirsten J, Berks M, Burton J, Thomas K, Fulton LL, Copsey T, Rifken L, Lightning J, Sims MA, O'Callaghan M, Jier M, Vaudin M, Johnstone L, Percy CM, Fraser A, Dear S, Gardner AE, Ainscough R, Smith M, Lloyd CR, Latreille P, Laisster N, Wilkinson-Sproat J, Connell M, Thierry-Mieg J, Staden R, Baynes C, Vaughan K, Du Z, Craxton M, Sulston JE, Mortimore BJ, Shownkeen R, Parsons JT, Watson A, Smith A, Wilson RK
[
Nature,
1994]
As part of our effort to sequence the 100-megabase (Mb) genome of the nematode Caenorhabditis elegans, we have completed the nucleotide sequence of a contiguous 2,181,032 base pairs in the central gene cluster of chromosome III. Analysis of the finished sequence has indicated an average density of about one gene per five kilobases; comparison with the public sequence databases reveals similarities to previously known genes for about one gene in three. In addition, the genomic sequence contains several intriguing features, including putative gene duplications and a variety of other repeats with potential evolutionary
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Wilson RK, Metzstein MM, Ainscough R, Waterston RH, Coulson AR, Craxton M, Thomas K, Dear S, Qiu L, Staden R, Berks M, Halloran N, Thierry-Mieg J, Hillier L, Sulston JE, Du Z, Durbin RM, Hawkins TL, Green P
[
Nature,
1992]
The long-term goal of this project is the elucidation of the complete sequence of the Caenorhabditis elegans genome. During the first year methods have been developed and a strategy implemented that is amenable to large-scale sequencing. The three cosmids sequenced in this initial phase are surprisingly rich in genes, many of which have mammalian homologues.AD - MRC Laboratory of Molecular Biology, Cambridge, UK.FAU - Sulston, JAU - Sulston JFAU - Du, ZAU - Du ZFAU - Thomas, KAU - Thomas KFAU - Wilson, RAU - Wilson RFAU - Hillier, LAU - Hillier LFAU - Staden, RAU - Staden RFAU - Halloran, NAU - Halloran NFAU - Green, PAU - Green PFAU - Thierry-Mieg, JAU - Thierry-Mieg JFAU - Qiu, LAU - Qiu LAU - et al.LA - engPT - Journal ArticleCY - ENGLANDTA - NatureJID - 0410462RN - 0 (Cosmids)SB - IM
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[
Cell Motil Cytoskeleton,
1995]
We report the cloning and sequencing of genomic DNA encoding a cytoplasmic dynein heavy chain from the nematode Caenorhabditis elegans. In a contiguous stretch of 35,103 bp of DNA from the left arm of linkage group I, we have found a gene that is predicted to encode a protein of 4,568 amino acids. This gene is composed of 15 exons and 14 relatively short introns, and it has significant homology to the other dynein heavy chains in the databases. The deduced molecular mass of the derived polypeptide is 512,624 Da. As with other dynein heavy chains that have been sequenced to date. it contains four GXXGXGK(S/T) motifs that form part of the consensus sequence for nucleotide triphosphate-binding domains. Comparison of axonemal and cytoplasmic dynein heavy chains shows that regions of homology among all dyneins are clustered in the carboxyl terminal two-thirds of the polypeptide, whereas the amino terminal one-third of the heavy chains may contain domains that specify functions that differ between axonemal and cytoplasmic forms of the dynein heavy chain.
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[
J Biochem,
1997]
The full-length cDNA coding for a putative copper transporting P-type ATPase (Cu2+-ATPase) was cloned from Caenorhabditis elegans. The putative Cu2+-ATPase is a 1,238-amino acid protein, and highly homologous to the Menkes and Wilson disease gene products mutations of which are responsible for human defects of copper metabolism. The Saccharomyces cerevisiae mutant with a disrupted CCC2 gene (yeast Menkes/Wilson disease gene homologue) was rescued by the cDNA for the C. elegans Cu2+-ATPase but not by the cDNA with an Asp-786 (an invariant phosphorylation site) to Asn mutation, suggesting that the C. elegans Cu2+-ATPase functions as a copper transporter in yeast. The expressed C. elegans protein was detected in yeast vacuolar membranes by immunofluorescence microscopy. The yeast expression system may facilitate further studies on copper transporting P-type ATPases.
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[
MicroPubl Biol,
2021]
Saul-Wilson Syndrome (SWS) is an ultra-rare, autosomal dominant skeletal dysplasia syndrome discovered in 1990; only 16 patients have been identified to date (Saul and Wilson 1990; Ferreira et al. 2018, OMIM#: 618150). The disease is characterized by short stature, various craniofacial abnormalities, shortened fingers and toes, and speech and physical developmental delay (Ferreira 2020). SWS is caused by a missense mutation in the COG4 gene, resulting in a G516R residue change. Other pathogenic mutations have been observed in this gene and all are clustered at the C-terminal end of the protein (R724W, R729W, R729A, E764A). These are associated with Congenital Disorder of Glycosylation type 2j (CDGIIj). This is a recessive disease characterized by mild psychomotor delay, mild dysmorphic features, epilepsy, and defective sialylation (Reynders et al. 2009). Besides the mild developmental delay, this disease seems to share virtually no phenotypic similarity with SWS.
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[
Genome Res,
1997]
Repetitive DNA is a significant component of eukaryotic genomes. We have developed a strategy to efficiently and accurately sequence repetitive DNA in the nematode Caenorhabditis elegans using integrated artificial transposons and automated fluorescent sequencing. Mapping and assembly tools represent important components of this strategy and facilitate sequence assembly in complex regions. We have applied the strategy to several cosmid assembly gaps resulting from repetitive DNA and have accurately recovered the sequences of these regions. Analysis of these regions revealed six novel transposon-like repetitive elements, IR-1, IR-2, IR-3, IR-4, IR-5, and TR-1. Each of these elements represents a middle-repetitive DNA family in C. elegans containing at least 3-140 copies per genome. Copies of IR-1, IR-2, IR-4, and IR-5 are located on all (or most) of the six nematode chromosomes, whereas IR-3 is predominantly located on chromosome X. These elements are almost exclusively interspersed between predicted genes or within the predicted introns of these genes, with the exception of a single IR-5 element, which is located within a predicted exon. IR-1, IR-2, and IR-3 are flanked by short sequence duplications resembling the target site duplications of transposons. We have established a website database (http:(/)/www.welch.jhu.edu/approximately devine/RepDNAdb.html) to track and cross-reference these transposon-like repetitive elements that contains detailed information on individual element copies and provides links to appropriate GenBank records. This set of tools may be used to sequence, track, and study repetitive DNA in model organisms and humans.
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Van der Gaag, Victoria L., Edison, Arthur S., Muzio, Cole J., Asif, Muhammad Zaka, Nocilla, Kelsey A., Guo, Jane
[
MicroPubl Biol,
2021]
1-Hydroxyphenazine (1-HP) is a small molecule produced by Pseudomonas aeruginosa, a bacterium that is used for pathogenesis models in C. elegans (Cezairliyan et al., 2013; Mahajan-Miklos, Tan, Rahme, & Ausubel, 1999). 1-HP is an especially interesting toxin to study as it has been shown to interact with human cells causing ciliary-slowing associated with dyskinesia and ciliostasis (Wilson et al., 1987). Prior research in our lab has shown that this molecule is toxic to C. elegans, with an LD50 between 150 and 200 M, but C. elegans can glycosylate 1-HP, which detoxifies the molecule (Stupp et al., 2013).
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[
Nucleic Acids Res,
1997]
Representation of subcloned Caenorhabditis elegans and human DNA sequences in both M13 and pUC sequencing vectors was determined in the context of large scale genomic sequencing. In many cases, regions of subclone under-representation correlated with the occurrence of repeat sequences, and in some cases the under-representation was orientation specific. Factors which affected subclone representation included the nature and complexity of the repeat sequence, as well as the length of the repeat region. In some but not all cases, notable differences between the M13 and pUC subclone distributions existed. However, in all regions lacking one type of subclone (either M13 or pUC), an alternate subclone was identified in at least one orientation. This suggests that complementary use of M13 and pUC subclones would provide the most comprehensive subclone coverage of a given genomic sequence.
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[
BMC Genomics,
2010]
BACKGROUND: Hookworm infection is one of the most important neglected diseases in developing countries, with approximately 1 billion people infected worldwide. To better understand hookworm biology and nematode parasitism, the present study generated a near complete transcriptome of the canine hookworm Ancylostoma caninum to a very high coverage using high throughput technology, and compared it to those of the free-living nematode Caenorhabditis elegans and the parasite Brugia malayi. RESULTS: The generated transcripts from four developmental stages, infective L3, serum stimulated L3, adult male and adult female, covered 93% of the A. caninum transcriptome. The broad diversity among nematode transcriptomes was confirmed, and an impact of parasitic adaptation on transcriptome diversity was inferred. Intra-population analysis showed that A. caninum has higher coding sequence diversity than humans. Examining the developmental expression profiles of A. caninum revealed major transitions in gene expression from larval stages to adult. Adult males expressed the highest number of selectively expressed genes, but adult female expressed the highest number of selective parasitism-related genes. Genes related to parasitism adaptation and A. caninum specific genes exhibited more expression selectivity while those conserved in nematodes tend to be consistently expressed. Parasitism related genes were expressed more selectively in adult male and female worms. The comprehensive analysis of digital expression profiles along with transcriptome comparisons enabled identification of a set of parasitism genes encoding secretory proteins in animal parasitic nematode. CONCLUSIONS: This study validated the usage of deep sequencing for gene expression profiling. Parasitic adaptation of the canine hookworm is related to its diversity and developmental dynamics. This comprehensive comparative genomic and expression study substantially improves our understanding of the basic biology and parasitism of hookworms and, is expected, in the long run, to accelerate research toward development of vaccines and novel anthelmintics.
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[
PLoS Negl Trop Dis,
2008]
BACKGROUND: The nematode intestine is a major organ responsible for nutrient digestion and absorption; it is also involved in many other processes, such as reproduction, innate immunity, stress responses, and aging. The importance of the intestine as a target for the control of parasitic nematodes has been demonstrated. However, the lack of detailed knowledge on the molecular and cellular functions of the intestine and the level of its conservation across nematodes has impeded breakthroughs in this application. METHODS AND FINDINGS: As part of an extensive effort to investigate various transcribed genomes from Ascaris suum and Haemonchus contortus, we generated a large collection of intestinal sequences from parasitic nematodes by identifying 3,121 A. suum and 1,755 H. contortus genes expressed in the adult intestine through the generation of expressed sequence tags. Cross-species comparisons to the intestine of the free-living C. elegans revealed substantial diversification in the adult intestinal transcriptomes among these species, suggesting lineage- or species-specific adaptations during nematode evolution. In contrast, significant conservation of the intestinal gene repertories was also evident, despite the evolutionary distance of approximately 350 million years separating them. A group of 241 intestinal protein families (IntFam-241), each containing members from all three species, was identified based on sequence similarities. These conserved proteins accounted for approximately 20% of the sampled intestinal transcriptomes from the three nematodes and are proposed to represent conserved core functions in the nematode intestine. Functional characterizations of the IntFam-241 suggested important roles in molecular functions such as protein kinases and proteases, and biological pathways of carbohydrate metabolism, energy metabolism, and translation. Conservation in the core protein families was further explored by extrapolating observable RNA interference phenotypes in C. elegans to their parasitic counterparts. CONCLUSIONS: Our study has provided novel insights into the nematode intestine and lays foundations for further comparative studies on biology, parasitism, and evolution within the phylum Nematoda.