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In the next five years, molecular biology will get its first look at the complete genetic code of a multicellular animal. The Caenorhabditis elegans genome sequencing project, a collaboration between Robert Waterston's group in St. Louis and John Sulston's group in Cambridge, is currently on schedule towards its goal of obtaining the complete sequence of this organism and all its estimated 15,000 to 20,000 genes by 1998. By that time, we should also know the complete genome sequence of a few other organisms as well, including the prokaryote Escherichia coli and the single-celled eukaryote Saccharomyces
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Sorrentino V, Deplancke B, Ouhmad T, Cornaglia M, Gijs MA, Auwerx J, Williams EG, Krishnamani G, Frochaux MV, Nicolet-Dit-Felix AA, Lin T, Mouchiroud L
[
Curr Protoc Neurosci,
2016]
Phenotyping strategies in simple model organisms such as D. melanogaster and C. elegans are often broadly limited to growth, aging, and fitness. Recently, a number of physical setups and video tracking software suites have been developed to allow for accurate, quantitative, and high-throughput analysis of movement in flies and worms. However, many of these systems require precise experimental setups and/or fixed recording formats. We report here an update to the Parallel Worm Tracker software, which we termed the Movement Tracker. The Movement Tracker allows variable experimental setups to provide cross-platform automated processing of a variety of movement characteristics in both worms and flies and permits the use of simple physical setups that can be readily implemented in any laboratory. This software allows high-throughput processing capabilities and high levels of flexibility in video analysis, providing quantitative movement data on C. elegans and D. melanogaster in a variety of different conditions. 2016 by John Wiley and Sons, Inc.
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[
WormBook,
2005]
Cell-division control affects many aspects of development. Caenorhabditis elegans cell-cycle genes have been identified over the past decade, including at least two distinct Cyclin-Dependent Kinases (CDKs), their cyclin partners, positive and negative regulators, and downstream targets. The balance between CDK activation and inactivation determines whether cells proceed through G 1 into S phase, and from G 2 to M, through regulatory mechanisms that are conserved in more complex eukaryotes. The challenge is to expand our understanding of the basic cell cycle into a comprehensive regulatory network that incorporates environmental factors and coordinates cell division with growth, differentiation and tissue formation during development. Results from several studies indicate a critical role for CKI-1 , a CDK inhibitor of the Cip/Kip family, in the temporal control of cell division, potentially acting downstream of heterochronic genes and dauer regulatory pathways.
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[
Methods Cell Biol,
1995]
Although Caenorhabditis elegans was originally chosen as a model organism for cell biology with serial section electron microscopy (EM) methods in mind, these methods have remained a daunting challenge. There is an apocryphal story that Nichol Thomson originally advised Sydney Brenner that C. elegans was unsuitable for electron microscopy and that Brenner should choose another species. Other experienced microscopists have probably shared similar dark thoughts from time to time. Nonetheless, the worm's very small size, simple organization, and cablelike nervous system have permitted Brenner's colleagues to characterize every cell and cell contact in the wild-type animal, potentiating the genetic characterization of cellular development in remarkable detail. We attempt to provide an adequate background for anyone to initiate EM studies of C. elegans. Two decades ago, as the first of Brenner's postdoctoral fellows left his laboratory to establish new worm laboratories, it was standard practice to include an EM component in their studies. Their combined efforts to characterize the adult animal's cell types and the essential steps in its development helped to erect a lovely scaffold of key manuscripts, capped by the description of the "Mind of the Worm" in some 600 micrographs and 175 drawings. Many of these works required technical heroics or suffered long delays before publication. Most people later chose to leave electron microscopy behind in pursuit of molecular quarry. The fruits of their molecular and genetic studies should soon stimulate a renewed flowering of electron microscopy. We hope to smooth your entry or reentry into these techniques. We also summarize our methods for three-dimensional (3D) image reconstruction, based largely on film techniques introduced by John White and Randle Ware. Digital imaging techniques seem poised to make 3D reconstruction more accessible, and may simplify the exchange of morphological data between laboratories. We discuss several computer systems that the C. elegans community could adopt for high-resolution studies of structure and function. In addition, we briefly cover several specialized specimen preparation techniques for electron microscopy, including freeze fracture and electron microscopic immunocytochemistry.
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[
WormBook,
2006]
There are two sexes in C. elegans, hermaphrodite and male. While there are many sex-specific differences between males and hermaphrodites that affect most tissues, the basic body plan and many of its structures are identical. However, most structures required for mating or reproduction are sexually dimorphic and are generated by sex-specific cell lineages. Thus to understand cell fate specification in hermaphrodites, one must consider how the body plan, which is specified during embryogenesis, influences the fates individual cells. One possible mechanism may involve the asymmetric distribution of POP-1 /Tcf, the sole C. elegans Tcf homolog, to anterior-posterior sister cells. Another mechanism that functions to specify cell fates along the anterior-posterior body axis in both hermaphrodites and males are the Hox genes. Since most of the cell fate specifications that occur in hermaphrodites also occur in males, the focus of this chapter will be on those that only occur in hermaphrodites. This will include the cell fate decisions that affect the HSN neurons, ventral hypodermal P cells, lateral hypodermal cells V5 , V6 , and T ; as well as the mesodermal M, Z1 , and Z4 cells and the intestinal cells. Both cell lineage-based and cell-signaling mechanisms of cell fate specification will be discussed. Only two direct targets of the sex determination pathway that influence cell fate specification to produce hermaphrodite-specific cell fates have been identified. Thus a major challenge will be to learn additional mechanisms by which the sex determination pathway interacts with signaling pathways and other cell fate specification genes to generate hermaphrodite-specific cell fates.