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[
WormBook,
2007]
Strongyloides is a genus of parasitic nematodes, which, unusually, has a free-living adult generation. Here we introduce the biology of this genus, especially the fascinating, but complex, life-cycle together with an overview of the taxonomy, morphology, genetics and genomics of this genus.
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[
WormBook,
2005]
The C. elegans germ line proliferates from one primordial germ cell (PGC) set aside in the early embryo to over a thousand cells in the adult. Most germline proliferation is controlled by the somatic distal tip cell, which provides a stem cell niche at the distal end of the adult gonad. The distal tip cell signals to the germ line via the Notch signaling pathway, which in turn controls a network of RNA regulators. The FBF-1 and FBF-2 RNA-binding proteins promote continued mitoses in germ cells located close to the distal tip cell, while the GLD-1 , GLD-2 , GLD-3 , and NOS-3 RNA regulators promote entry into meiosis as germ cells leave the stem cell niche. In addition to these key regulators, many other genes affect germline proliferation.
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[
1994]
Nematodes have been cultured continuously in the laboratory since 1944 when Margaret Briggs Gochnauer isolated and cultured the free-living hermaphroditic species Caenorhabditis briggsae. Work with C. briggsae and other rhabditid nematodes, C. elegans, Rhabditis anomala, and R. pellio, demonstrated the relative ease with which they could be cultured. The culturing techniques described here were developed for C. elegans, but are generally suitable (to varying degrees) for other free-living nematodes. Whereas much of the early work involved axenic culturing, most of these techniques are no longer in common use and are not included here. In the 1970s C. elegans became the predominant research model due to work by Brenner and co-workers on the genetics and development of this species. An adult C. elegans is about 1.5 mm long, and under optimal laboratory conditions has a life cycle of approximately 3 days. There are two sexes, males and self-fertile hermaphrodites, that are readily distinguishable as adults. The animals are transparent throughout the life cycle, permitting observation of cell divisions in living animals using differential interference microscopy. The complete cell lineage and neural circuitry have been determined and a large collection of behavioral and anatomical mutants have been isolated. C. elegans has six developmental stages: egg, four larval stages (L1-L4), and adult. Under starvation conditions or specific manipulations of the culture conditions a developmentally arrested dispersal stage, the dauer larva, can be formed as an alternative third larval stage. Many of the protocols included here and other experimental protocols have been summarized in "The Nematode Caenorhabditis elegans". We also include a previously unpublished method for long-term chemostat cultures of C. elegans. General laboratory culture conditions for nematode parasites of animals have been described, but none of these nematodes can be cultured in the laboratory through more than one life cycle. Marine nematodes and some plant parasites have been cultured xenically or with fungi. Laboratory cultivation of several plant parasites on Arabidopsis thaliana seedlings in agar petri plates has also been reported.
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[
1983]
Most multicellular eukaryotes posses a distinct group of germ-line cells that produces oocytes in one sex and sperm in the other. The production of adult germ cells appears to involve several developmental steps. First, during early embryogenesis, one or a few cells are committd to become germ precursor cells. Secondly, after a period of proliferation, some or all germ line descendants of the germ precursor cell leave the mitotic cell cycle and enter meiotic prophase. Thirdly, the meiotic germ cell matures as either a sperm or an oocyte. In this paper, I will review our knowledge of how each of these steps might be controlled in the small non-parasitic soil nematode, Caenorhabditis elegans.
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[
1998]
The use of antibodies to visualize the distribution and subcellular localization of gene products powerfully complements genetic and molecular analysis of gene function in C. elegans. The challenge to immunolabeling C. elegans is finding the fixation and permeabilization methods that effectively make antigens accessible without destroying the tissue morphology or the antigen. Embryos are surrounded by a chitinous eggshell and larvae and adults are surrounded by a collagenous cuticle, each of which must be permeabilized to allow penetration of antibodies. In addition, antigens and antibodies are sensitive to different fixing and permeabilizing conditions. For example, some antibodies do not work well on paraformaldehyde-fixed samples, and others are sensitive to incubation in acetone. There are many protocols used in the C. elegans field; additional protocols are summarized in Miller and Shakes (1994) and on the C. elegans World
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[
Methods Cell Biol,
1995]
Genetic balancers are genetic constructs or chromosomal rearrangements that allow lethal or sterile mutations to be stably maintained in heterozygotes. In this chapter we use the term balancer primarily to refer to chromosomal duplications or rearrangements that suppress crossing over. In addition, we define lethal as any mutation that blocks survival or reproduction. Phenotypes associated with lethal mutations in Caenorhabditis elegans range from egg or larval lethality to adult sterility and maternal effect lethality, and can include conditional effects such as temperature sensitivity. The number of essential genes in C. elegans (those identified by lethal mutations) may range as high as 7000 according to genetic estimates. Thus, lethal mutations constitute a rich source of information about basic biological processes in this nematode.
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[
1979]
Caenorhabditis elegans, a free-living nematode, is the subject of intensive genetic and developmental studies. Embryogenesis in C. elegans, like other nematodes, is strictly determinate and virtually invariant among individuals. The newly hatched juvenile has only about 550 cells arranged quite predictably. Postembryonic development is also quite regular and the number of nongonadal cells increases to only about 810 in the adult hermaphrodite. Here we will summarize results of embryonic cell lineage studies in our laboratory including the wild type and temperature-sensitive embryonic arrest mutants. We will also compare the developmental mechanisms of C. elegans to those of higher animals, and speculate about the possible role of histones in the timing of cell divisions in embryogenesis.
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[
WormBook,
2005]
Understanding the biology of C. elegans relies on identification and analysis of essential genes, genes required for growth to a fertile adult. Approaches for identifying essential genes include several types of classical forward genetic screens, genome-wide RNA interference screens and systematic targeted gene knockout. Based on most estimates made from screening results thus far, from 15-30% of C. elegans genes appear to be essential. Genetic redundancy masks some essential functions and pleiotropy of many essential genes poses a challenge for a full understanding of their functions. Temperature sensitive mutations are valuable tools for studies of essential genes, but our ability to analyze essential genes would benefit from development of new tools for conditional inactivation or activation of specific genes.
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[
1998]
The use of antibodies to visualize the distribution and subcellular localization of gene products powerfully complements genetic and molecular analysis of gene function in C. elegans. The challenge to immunolabeling C. elegans is finding the fixation and permeabilization methods that effectively make antigens accessible without destroying the tissue morphology or the antigen. Embryos are surrounded by a chitinous eggshell and larvae and adults are surrounded by a collagenous cuticle, each of which must be permeabilized to allow penetration of antibodies. In addition, antigens and antibodies are sensitive to different fixing and permeabilizing conditions. For example, some antibodies do not work well on paraformaldehydefixed samples, and others are sensitive to incubation in acetone. There are many protocols used in the C. elegans field; additional protocols are summarized in Miller and Shakes (1994) and on the C. elegans World Wide Web page
(http://elegans.swmed.edu/). -
[
1987]
Vitellogenins of many insects, vertebrates, nematodes and sea urchins are very similar in size and amino acid composition. We have determined the nucleotide sequences of the genes that encode vitellogenins in nematodes (C. elegans) and sea urchins (S. purpuratus), and compared the deduced amino acid sequences to the published sequences of two vertebrate vitellogenins (X. laevis and G. gallus). This comparison demonstrated unequivocally that the nematode and vertebrate proteins are encoded by distant members of a single gene family. The less extensive sequence data available for the sea urchin gene indicates that this, too, may be a member of this family of genes, as may the vitellogenin genes of locust. On the other hand, we were unable to detect any similarity between these genes and the D. melanogaster yolk protein genes. Thus it appears that while nematodes, vertebrates, sea urchins and at least some insects utilize the same family of genes to encode vitellogenins, Drosophila uses a different gene family. All of the vitellogenin genes are regulated in a tissue-specific manner. They are expressed in the intestine in nematodes, in the liver in vertebrates, in the fat body in insects, and in the intestine and gonad in sea urchins. Their production is limited to adult females in all species except sea urchins, in which they are expressed by adults of both sexes. In nematodes we have identified two heptameric sequence elements repeated multiple times in all eleven of the vitellogenin genes sequenced. One of these elements is also present in the vertebrate promoters and has recently been shown to be required for transcriptional activation. All of the 5' ends of the vitellogenin mRNAs of nematodes, vertebrates and locust can be folded into potentially-stable secondary structures. We present evidence that these structures have been strongly selected for and presumably perform some function in regulation of vitellogenin production.