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[
1980]
The free-living nematode Caenorhabditis elegans has attracted attention in recent years as an organism for the study of the genetic control of development. This chapter briefly describes the present state of this work. Many of the studies reported on here have not yet been published but have been described in "The Worm Breeder's Gazette", an informal newsletter I edit, and at a C. elegans meeting held at Cold Spring Harbor in May 1979. A previous review of this field was written by Riddle (1978). The use of free-living nematodes in genetic studies was first suggested by Dougherty and Calhoun in 1948. Early studies of C. elegans by Dougherty and co-workers (1959) emphasized methods of axenic cultivation while the sexual cycle was described by Nigon (1949). The present interest in C. elegans, however, was triggered by Sydney Brenner who took up the organism in the late 1960s as a possibly useful organism for the study of the genetic control of the nervous system and of behavior (Brenner, 1973). It was largely due to Brenner (1974) that the present methods of cultivation and of genetic analysis were developed.
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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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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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[
1979]
We have isolated temperature sensitive maternal effect mutants in the free-living nematode Caenorhabditis elegans. We use C. elegans for several basic reasons. It is easy to culture in the laboratory and it has a rapid life cycle. The genetics of C. elegans have been elucidated by Brenner and more recently have been refined by the lethal analysis of Herman et. al. Both embryonic and postembryonic development can be observed directly and conveniently on the living worm with Nomarski differential interference optics because egg shell and worm cuticle are transparent. The precise embryonic cell lineages of C. elegans are known from fertilization to the 200 blastomere stage. All of the postembryonic somatic cell lineages are precisely known. It ...
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Meiosis is the process by which eukaryotes reduce their chromosome content by half. During meiosis, the chromosomes undergo two divisions, the first of which involves the organized synapsis of homologous chromosomes. During this division, synapsis predisposes the chromosomes to recombination and proper disjunction. We review here aspects of meiotic recombination under study using the self-fertilizing hermaphroditic nematode Caenorhabditis elegans. Six linkage groups wre identified by Brenner that correlated with the six chromosomes observed by Nigon. Although the behavior of the chromosomes is reported to be holokinetic, we have not needed to invoke any unusual mechanisms to explain their behavior with regard to meiotic recombination. On the contrary, there appears to be a single homolog recognition site localized at or near one end of each of the chromosomes. It is not known whether the homolog recognition site is associated with a centromere, but it is clear that this region is responsible for the initiation of the meiotic phenomena of homolog pairing, recombination, and proper disjunction.
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[
1985]
At first sight the inclusion of a chapter on Caenorhabditis elegans in a volume on cell biology may seem unusual. However this nematode has been a superb model system for a number of cell biology studies as well as a useful model of aging. This widespread interest in C. elegans is engendered in large part by its genetic system and its optical clarity in Nomarski phase-contrast optics. Nematodes have long been a system in wide use among experimental gerontologists, and with the introduction of C. elegans by Brenner in 1974, this species has become the nematode of choice for most aging studies. We concentrate primarily on C. elegans in this review although a number of other speices, including Caenorhabditis briggsae, Turbatrix aceti, and Panagrellus redivivus, have been used in aging studies also. Other reviews on aging in C. elegans have appeared recently, including a more detailed review in another volume of this series.
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[
1994]
The current interest in the nematode Caenorhabditis elegans began approximately 25 years ago when Sidney Brenner selected this species as the most suitable for studies of metazoan development and nervous system. The basis of this selection rested on the anatomical simplicity of nematodes, which nevertheless possess the major differentiated cell types of higher animals, and the tractability of C. elegans to the genetic approach. Over the past two decades or so, progress has been impressive: the cell lineage from egg to adult and the anatomy of the nervous system have been completely described, genetic investigations of numerous developmental problems are co-ordinated within a universally-agreed, systematic nomenclature, a physical map of the C. elegans genome is nearing completion and a project to sequence the entire genome is underway. Furthermore, the number of laboratories seeking to understand the mechanisms controlling animal development through genetic and molecular investigations of C. elegans is rising rapidly as the advantages of this organism become
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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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[
2010]
Over 30 years ago, Nobel laureate Sydney Brenner recognized that an intellectually straightforward strategy to delineate the basic principles in neurobiology is to utilize a model organism with a nervous system that is simple enough to lend itself to anatomical, cellular, genetic, and molecular analysis, yet be complex enough that lessons learned in that organism would give us insight into general principles of neural function. The humble organism he chose, the nematode Caenorhabditis elegans, is now one of the most thoroughly characterized metazoans, particularly in terms of its nervous system. One of Brenner's motivations in adapting C. elegans as a model organism was to understand the totality of the molecular and cellular basis for the control of animal behavior (Brener 1988). In this chapter, we review what is arguably the best-studied aspect of C. elegans behavior: response to chemical stimuli. The C. elegans neurobiology literature can be intimidating for the uninitiated; we attempt to limit the use of "worm jargon" in this review. For a more C. elegans-centric review, we refer you to other excellent sources (Bargmann 2006).
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[
1975]
Much of the discussion in this symposium has addressed the question of how a single cell differentiates into two different daughter cells. Considerable effort is being made to understand the ability of cells to regulate protein synthesis either by temporal regulation at the level of the genome or through the inherent order of assembly of macromolecules, as is seen in the case of T4 bacteriophage late functions. We now turn to consideration of the genetic control of development in an organism which is complex relative to those prokaryotes and unicellular eukaryotes which have been discussed so far. Studies on the development of prokaryotes or simple eukaryotes rely upon the extensive knowledge of how genes are replicated, transcribed, and translated as deciphered over the past 15 years of molecular biology. An alternative approach is required in studying an organism with several cell types and asymmetries in which there is complex development. I have chosen the small nematode Caenorhabditis elegans for studying genetic control of development because it lends itself to detailed morphological studies and because its genetics is now well defined through the elegant work of Brenner......