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Trends in Neurosciences,
1985]
The connectivity of all the 302 neurones that make up the nervous system of Caenorhabditis elegans has been deduced from reconstructions of electron micrographs of serial sections. The nervous system is arranged as a collection of bundles of parallel processes. Within these bundles the relatively unbranched processes of neurones run in defined locations making en passant synapses to their neighbours. The low level of mixing within process bundles has the consequence that a given process runs in a restricted neighbourhood and has only relatively few potential synaptic partners. Neurones make synaptic contacts with many of these potential partners however. There is some evidence that neurones will still behave in this way regardless of what neighbourhood they happen to be in. The highly locally connected arrangement of the nervous sytem has consequences for the synaptic circuitry, in that the formation of triangular sub-circuits is favoured. The placement of processes into specific neighbourhoods is therefore a major determinant of connectivity. Placement seems to be achieved both by cell lineage mechanisms, which place specific neurones in appropriate locations, and by the selective fasciculation of outgrowing processes to neighbours with high adhesive affinities.
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Nature Neuroscience,
2002]
A molecule that may be important for sorting presynaptic components into the developing axon is now revealed by a study using the genetic tools available in C. elegans.
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Cell,
1996]
Anyone who has watched an early embryo develop cannot help but be awed by the choreography of the early cleavages. The orientation and timing of cleavage in an animal cell are always such that the cleavage furrow bisects the mitotic apparatus (MA) during telophase, thus ensuring the equal partitioning of daughter chromosomes. In addition, the regulation of cleavage plane orientation is necessary for correct partitioning of localized determinants to specific daughter cells, for optimal positioning of cells in developing embryos, and for morphogenesis in plants, which are not motile.
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Philos Trans R Soc Lond B Biol Sci,
2018]
Wave propagation during locomotory movements of <i>Caenorhabditis elegans</i> is constrained to a single dorso/ventral plane. By contrast, the tip of the head (snout) can make rapid exploratory movements in all directions relative to the body axis. These extra degrees of freedom are probably important for animals to seek and identify desirable passages in the interstices of the three-dimensional matrix of soil particles, their usual habitat. The differences in degrees of freedom of movement between snout and body are reflected in the innervation of the musculature. Along the length of the body, the two quadrants of dorsal muscle receive common innervation as do the two quadrants of ventral muscle. By contrast, muscles in the snout have an octagonal arrangement of innervation. It is likely that the exploratory behaviour of the snout is mediated by octant-specific motor and sensory neurons, together with their associated interneurons. The well-defined anatomical structure and neural circuitry of the snout together with behavioural observations should facilitate the implementation of models of the neural basis of exploratory movements, which could lead to an understanding of the basis of this relatively complex behaviour, a behaviour that has similarities to foraging in some vertebrates.This article is part of a discussion meeting issue 'Connectome to behaviour: modelling <i>C. elegans</i> at cellular resolution'.
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Philos Trans R Soc Lond B Biol Sci,
2015]
The article 'Structure of the nervous system of the nematode Caenorhabditis elegans' (aka 'The mind of a worm') by White et al., published for the first time the complete set of synaptic connections in the nervous system of an animal. The work was carried out as part of a programme to begin to understand how genes determine the structure of a nervous system and how a nervous system creates behaviour. It became a major stimulus to the field of C. elegans research, which has since contributed insights into all areas of biology. Twenty-six years elapsed before developments, notably more powerful computers, made new studies of this kind possible. It is hoped that one day knowledge of synaptic structure, the connectome, together with results of many other investigations, will lead to an understanding of the human brain. This commentary was written to celebrate the 350th anniversary of the journal Philosophical Transactions of the Royal Society.
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Science,
1994]
In 1967, Sydney Brenner isolated the first behavioral mutants of the nematode Caenorhabditis elegans, and in 1970, John White began the systematic reconstruction of its nervous system. This dual approach of genetics coupled with detailed morphological analysis, now enhanced by the tools of molecular biology and electrophysiology, still dominates the study of the function and development of the C. elegans nervous system. Although Brenner's vision of a comprehensive understanding of this simple animal has taken time to mature, findings of the past few years indicate that the tree is bearing fruit.
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Results Probl Cell Differ,
2000]
Aging can be defined in three ways: (1) as a progressive increase in the probability of dying of nonaccidental causes, (2) as a progressive increase in the probability of being afflicted with a number of specific diseases, such as cancer, cardiovascular diseases, and neurodegenerative diseases, and (3) as a progressive increase in the prevalence of features that are not in themselves pathological, but which are linked to chronological age, like wrinkled skin or white hair. In recent years, several investigators have used definition (1) and the measure of life span in the nematode Caenorhabditis elegans to study genetic, cellular, and molecular mechanisms that might be responsible for the aging process in all organisms.
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Cell,
1996]
Across the animal kingdom, fertilization requires the encounter between a large stationary egg and small motile sperm. To maximize their likelihood of reaching the egg before their competition, sperm are extraordinarily specialized cells, generally consisting of little more than a haploid nucleus, mitochondria to generate energy, and a highly efficient movement engine. Almost all animal sperm are flagellated and seek the egg by swimming quickly through a liquid environment. Nematodes, however, produce sperm that move by crawling along solid substrates. These roundworm sperm extend pseudopods that look and behave like the actin-rich pseudopods of a wide variety of cells ranging from free-living soil amoebae to human white blood cells. The crawling sperm appear by most criteria to be exploiting classic actin-based cell motility, with one important difference: the sperm contain practically no actin (Nelson et al., 1982).