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[
1975]
Studies in behaviour genetics have covered a wide field: motivation, development, sensory capacities, intelligence, learning, evolution, neuromorphology and neurochemistry have all been approached using genetic techniques, and there are probably others. Whilst it is at present impossible to construct any unities one must accept that many such studies have as their common aim one of the most fundamental problems in biology: how is behavioral potential encoded in genetic terms and expressed in the course of development? The relative enormity of this problem is often matched by its inaccessibilty. It cannot be claimed that there is any agreed view of the way forward and much of the work has frankly to be opportunistic-seizing on some favourable material or a useful new analytical technique to gain a limited objective. Consequently, behaviour genetics often presents a confusing picture of numerous disjointed studies, with
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[
WormBook,
2005]
Protein kinases are one of the largest and most influential of gene families: constituting some 2% of the proteome, they regulate almost all biochemical pathways and may phosphorylate up to 30% of the proteome. Bioinformatics and comparative genomics were used to determine the C. elegans kinome and put it in evolutionary and functional context. Kinases are deeply conserved in evolution, and the worm has family homologs for over 80% of the human kinome. Almost half of the 438 worm kinases are members of worm-specific or worm-expanded families. Such radiations include genes involved in spermatogenesis, chemosensation, Wnt signaling and FGF receptor-like kinases. The C. briggsae kinome is largely similar apart from the expanded classes, showing that such expansions are evolutionarily recent.
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[
WormBook,
2007]
The mechanism of action of volatile anesthetics remains an enigma, despite their worldwide use. The nematode C. elegans has served as an excellent model to unravel this mystery. Genes and gene sets that control the behavior of the animal in volatile anesthetics have been identified, using multiple endpoints to mimic the phenomenon of anesthesia in man. Some of these studies have clear translational implications in more complicated organisms.
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[
1993]
In the past 10 years, the remarkable discovery has been made that molecular mechanisms of development are conserved among all animals, and that many of the same molecular components appear in signal transduction pathways of all eukaryotes from yeast to man. This mechanistic conservation means that molecules can be studied in the organism in which their properties are most transparent; general principles or specific predictions made from work in one organism can subsequently be explored in other organisms. This chapter reviews aspects of nervous system development that have been studied using genetic approaches in two simple invertebrates, the fruit fly Drosophila melanogaster (herein referred to as Drosophila) and the soil nematode worm Caenorhabditis elegans (C. elegans). The nervous systems of both of these organisms are extremely simple compared to those of mammals....
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[
WormBook,
2016]
In C. elegans, mutants that are defective in muscle function and/or structure are easy to detect and analyze since: 1) body wall muscle is essential for locomotion, and 2) muscle structure can be assessed by multiple methods including polarized light, electron microscopy (EM), Green Fluorescent Protein (GFP) tagged proteins, and immunofluorescence microscopy. The overall structure of the sarcomere, the fundamental unit of contraction, is conserved from C. elegans to man, and the molecules involved in sarcomere assembly, maintenance, and regulation of muscle contraction are also largely conserved. This review reports the latest findings on the following topics: the transcriptional network that regulates muscle differentiation, identification/function/dynamics of muscle attachment site proteins, regulation of the assembly and maintenance of the sarcomere by chaperones and proteases, the role of muscle-specific giant protein kinases in sarcomere assembly, and the regulation of contractile activity, and new insights into the functions of the dystrophin glycoprotein complex.
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[
1960]
For the purpose of the present chapter the noun 'cultivation' is to be taken as the maintenance, in the laboratory, of a population of organisms belonging to a desired species through successive generations and subcultures over a prolonged period of time (weeks, months, or years). This is a deliberate restriction of the term. The noun 'culture' is most aptly used for a population within a circumscribed vessel or container (test-tube, Petri dish, U.S. Bureau of Plant Industry watch glass, etc.); it is also used in a looser, more general way (as "in culture") to cover conditions of substantial growth whether or not leading to cultivation in the strict sense
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[
Methods Cell Biol,
1995]
Geneticists like to point out that the ultimate test of a proposed function for a gene and its encoded product (or products) in a living organism involves making a mutant and analyzing its phenotype. This is the goal of reverse genetics: a gene is cloned and sequenced, its transcripts and protein coding sequence are analyzed, and a function may be proposed; one must then introduce a mutation in the gene in a living organism to see what the functional consequences are. The analysis of genetic mosaics takes this philosophy a step further. In mosaics, some cells of an individual are genotypically mutant and other cells are genotypically wild type. One then asks what the phenotypic consequences are for the living organism. This is not the same as asking what cells transcribe the gene or in what cells the protein product of the gene is to be found, but rather it is asking in what cells the wild-type gene is needed for a given function...
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[
1990]
Induction of the C. elegans vulva is a simple example of pattern formation in which the combined action of two intercellular signals specifies three cell types in a precise spatial pattern. These two signals, a graded inductive signal and a short-range lateral signal, are each mediated by a distinct genetic pathway. To understand how these intercellular signals specify cell type, we are studying, by genetic analysis and molecular cloning, genes whose products are involved in the induction pathway.
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[
2000]
Computer tracking of Caenorhabditis elegans, a free-living soil nematode, is a promising tool to assess behavioral changes upon exposure to contaminants. A short life cycle, a known genetic make-up, thoroughly studied behavior, and a completely mapped nervous system make C. elegans an attractive soil test organism with many advantages over the commonly used earthworm. Although many toxicity tests have been performed with C. elegans, the majority focused on mortality, a much less sensitive endpoint than behavior. A computer tracking system has been developed to monitor behavioral changes using C. elegans. Because conditions unrelated to specific toxicant exposures, such as changes in temperature, developmental stage, and presence of adequate food sources, can affect behavior, there is a need to standardize tracking procedures. To this end, we have developed reference charts for control movement comparing the movement of four and five day-old adult nematodes. The use of K-medium versus deionized (DI) H2O for pre-tracking rinses was also investigated. A final reference chart compared the behavioral responses of nematodes at various food densities (i.e. bacterial concentrations).
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[
Methods Cell Biol,
1995]
The number of easily distinguishable mutant phenotypes in Caenorhabditis elegans is relatively small, and this constrains the number of factors that can be followed in standard genetic crosses. Consequently, a new mutation is mapped, first to a chromosome using two-factor data from one or more crosses, and then to a chromosomal subregion by successive three-factor crosses. Mapping would be more efficient if it were possible to score a large number of well-distributed markers in a single cross. The advent of the polymerase chain reaction makes this approach feasible by allowing polymorphic genomic regions to serve as genetic markers that are easily scored in DNA released from individual animals. The only "phenotype" is a band on a gel, so the segregation of many of these markers can be followed in a single cross. Following the terminology proposed by Olsen et al. (1989), we refer to polymorphisms that can be scored by appropriately designed polymerase chain reaction (PCR) assays as polymorphic seqeunce-tagged sites (STSs)...