Caenorhabditis Elegans

Information about Caenorhabditis Elegans

Caenorhabditis elegans

An adult hermaphrodite C. elegans worm

Kingdom:	Animalia
Phylum:	Nematoda
Class:	Secernentea
Order:	Rhabditida
Family:	Rhabditidae
Genus:	Caenorhabditis
Species:	*elegans*

Binomial name

Caenorhabditis elegans
Maupas, 1900

Caenorhabditis elegans (IPA: [ˌsiːnəʊræbˈdaɪtɪs ˈelegænz]) is a free-living nematode (roundworm), about 1 mm in length, which lives in temperate soil environments. Research into the molecular and developmental biology of C. elegans was begun in 1974 by Sydney Brenner ^[1] and it has since been used extensively as a model organism.

Biology

C. elegans is unsegmented, vermiform, bilaterally symmetrical, with a cuticle integument, four main epidermal cords and a fluid-filled pseudocoelomate cavity. Members of the species have many of the same organ systems as other animals. In the wild, they feed on bacteria that develop on decaying vegetable matter. C. elegans has both a hermaphrodite sex, and a very rare male population, which makes up 0.05% of the total C. elegans on average. The basic anatomy of C. elegans includes a mouth, pharynx, intestine, gonad, and collagenous cuticle. Males have a single-lobed gonad, vas deferens, and a tail specialized for mating. Hermaphrodites have two ovaries, oviducts, spermatheca, and a single uterus.

C. elegans eggs are laid by the hermaphrodite. After hatching, they pass through four larval stages (L1-L4). When crowded or in the absence of food, C. elegans can enter an alternative third larval stage called the dauer state. Dauer larvae are stress-resistant and do not age. Hermaphrodites produce all their sperm in the L4 stage (150 sperm per gonadal arm) and then switch over to producing oocytes. The sperm are stored in the same area of the gonad as the oocytes until the first oocyte pushes the sperm into the spermatheca (a kind of chamber where the oocytes become fertilized by the sperm). ^[2]. The male can inseminate the hermaphrodite, which will use male sperm preferentially (both types of sperm are stored in the spermatheca). When self-inseminated the wild-type worm will lay approximately 300 eggs. When inseminated by a male, the number of progeny can exceed 1,000. At 20°C, the laboratory strain of C. elegans has an average life span of approximately 2–3 weeks and a generation time of approximately 4 days. Hermaphrodites can mate with males or self-fertilize.

C. elegans has five pairs of autosomes and one pair of sex chromosomes. Sex in C. elegans is based on an X0 sex-determination system. Hermaphrodite C. elegans have a matched pair of sex chromosomes (XX); the rare males have only one sex chromosome (X0).

Laboratory uses

C. elegans is studied as a model organism for a variety of reasons. Strains are cheap to breed and can be frozen. When subsequently thawed they remain viable, allowing long-term storage. Because the complete cell lineage of the species has been determined, C. elegans has proven especially useful for studying cellular differentiation.

From a research perspective, C. elegans has the advantage of being a multicellular eukaryotic organism which is simple enough to be studied in great detail. The developmental fate of every single somatic cell (959 in the adult hermaphrodite; 1031 in the adult male) has been mapped out. These patterns of cell lineage are largely invariant between individuals, in contrast to mammals where cell development from the embryo is more largely dependent on cellular cues. In both sexes, a large number of additional cells (131 in the hermaphrodite, most of which would otherwise become neurons), are eliminated by programmed cell death (apoptosis).

Wild-type C. elegans hermaphrodite stained to highlight the nuclei of all cells

In addition, C. elegans is one of the simplest organisms with a nervous system. In the hermaphrodite, this comprises 302 neurons whose pattern of connectivity has been completely mapped out, and shown to be a small-world network ^[3]. Research has explored the neural mechanisms responsible for several of the more interesting behaviors shown by C. elegans, including chemotaxis, thermotaxis, mechanotransduction, and male mating behavior. Interestingly, the neurons fire no action potentials.

A useful feature of C. elegans is that it is relatively straightforward to disrupt the function of specific genes by RNA interference (RNAi). Silencing the function a gene in this way can sometimes allow a researcher to infer what the function of that gene may be. The nematode can either be soaked in (or injected with) a solution of double stranded RNA, the sequence of which is complentary to the sequence of the gene that the researcher wishes to disable. Alternatively, worms can be fed on genetically transformed bacteria which express the double stranded RNA of interest.

C. elegans has also been useful in the study of meiosis. As sperm and egg nuclei move down the length of the gonad, they undergo a temporal progression through meiotic events. This progression means that every nuclei at a given position in the gonad will be at roughly the same step in meiosis, eliminating the difficulties of heterogeneous populations of cells.

The organism has also been identified as a model for nicotine dependence as it has been found to experience the same symptoms humans experience when they quit smoking. ^[4]

As for most model organisms, there is a dedicated online database for the species that is actively curated by scientists working in this field. The WormBase database attempts to collate all published information on C. elegans and other related nematodes. A reward of $5000 has been advertised on their website, for the finder of a new species of closely related nematode.^[5] Such a discovery would broaden research opportunities with the worm.^[6]

The genome

C. elegans was the first multicellular organism to have its genome completely sequenced. The finished genome sequence was published in 1998,^[7] although a number of small gaps were present (the last gap was finished by October 2002). The C. elegans genome sequence is approximately 100 million base pairs long and contains approximately 20,000 genes. The vast majority of these genes encode for proteins but there are likely to be as many as 1,000 RNA genes. Scientific curators continue to appraise the set of known genes, such that new gene predictions continue to be added and incorrect ones modified or removed.

In 2003, the genome sequence of the related nematode C. briggsae was also determined, allowing researchers to study the comparative genomics of these two organisms ^[8]. Work is now ongoing to determine the genome sequences of more nematodes from the same genus such as C. remanei [1], C. japonica [2] and C. brenneri [3]. These newer genome sequences are being determined by using the whole genome shotgun technique which means that the resulting genome sequences are likely to not be as complete or accurate as C. elegans (which was sequenced using the 'hierarchical' or clone-by-clone appoach).

The official version of the C. elegans genome sequence continues to change as and when new evidence reveals errors in the original sequencing (DNA sequencing is not an error free process). Most changes are usually minor, adding or removing only a few base pairs (bp) of DNA. E.g. the WS169 release of WormBase (December 2006) lists a net gain of 6 bp to the genome sequence ^[9]. Occasionally more extensive changes are made, e.g. the WS159 release of May 2006 added over 300 bp to the sequence ^[10].

Nematode evolution

It has been shown that a small number of conserved protein sequences from sponges are more similar to humans than to C. elegans ^[11]. This suggests that there has been an accelerated rate of evolution in the C. elegans lineage. The same study found that several phylogenetically ancient genes are not present in C. elegans.

C. elegans scientists''

In 2002, the Nobel Prize for Medicine was awarded to Sydney Brenner, H. Robert Horvitz and John Sulston for their work on the genetics of organ development and programmed cell death (PCD) in C. elegans. The 2006 Nobel Prize in Physiology or Medicine was awarded to Andrew Fire and Craig C. Mello, for their discovery of RNA interference in C. elegans.^[12]

Because all research into C. elegans essentially started with Sydney Brenner in the 1970's, many scientists working in this field share a close connection to Brenner (they either worked as a post-doctoral or post-graduate researcher in Brenner's lab or in the lab of someone who previously worked with Brenner). Because most people who worked in his lab went on to establish their own worm research labs, there is now a fairly well documented 'lineage' of C. elegans scientists. This lineage was recorded in some detail at the 2003 International Worm Meeting and the results were stored in the Wormbase database.

C. elegans in the media

C. elegans made news when it was discovered that specimens had survived the Space Shuttle Columbia disaster in February 2003.^[13]

References

1. ^ Brenner, S. (1974). The Genetics of Caenorhabditis elegans. Genetics 77: 71–94.
2. ^ Nayak, S., J. Goree & T. Schedl (2004). fog-2 and the Evolution of Self-Fertile Hermaphroditism in Caenorhabditis. PLoS Biology 3 (1): e6. DOI: 10.1371/journal.pbio.0030006.
3. ^ Watts D. J. & S. H. Strogatz (1998). Collective dynamics of 'small-world' networks. Nature 393 (6684): 440–442.
4. ^ Feng et al. (2006). A C. elegans Model of Nicotine-Dependent Behavior: Regulation by TRP-Family Channels. Cell 127: 621-633.
5. ^ Caenorhabditis isolation guide. WormBase. Retrieved on 2007-08-30.
6. ^ (31 Aug 2007) "Slime for a dime". Science 317 (5842): 1157.
7. ^ The C. elegans Sequencing Consortium (1998). Genome sequence of the nematode C. elegans: a platform for investigating biology. Science 282: 2012–2018.
8. ^ Stein, L. D. et al. (2003). The Genome Sequence of Caenorhabditis briggsae: A Platform for Comparative Genomics. PLoS Biology 1: 166–192.
9. ^ . Wormbase. Retrieved on 2007-02-21.
10. ^ . Wormbase. Retrieved on 2007-01-21.
11. ^ Gamulin, V (December 2000). "Sponge proteins are more similar to those of Homo sapiens than to Caenorhabditis elegans". Biological Journal of the Linnean Society 71 (4): 821-828.
12. ^ A. Fire, S.Q. Xu, M.K. Montgomery, S.A. Kostas, S. E. Driver, C.C. Mello: Potent and specific genetic interference by double-stranded RNA in Caenorhabditis elegans. In: Nature. 391/1998, S. 806-811, ISSN 0028-0836
13. ^ "Worms survived Columbia disaster", BBC News, 2003-05-01.

Relevant publications

Bird, A. F & J. Bird (1991). The Structure of Nematodes. Academic Press, Inc., San Diego, pp 1, 69–70, 152–153, 165, 224–225.
Gamulin, Vera; Müller, Isabel M. & Müller, Werner E. G. (2000): Sponge proteins are more similar to those of Homo sapiens than to Caenorhabditis elegans. Biol. J. Linn. Soc. 71(4): 821–828. HTML abstract
Hope, I. A. (1999). C. elegans: A practical approach. Oxford University Press, New York, pp 1–6.
Riddle, D.L., T. Blumenthal, R. J. Meyer & J. R. Priess (1997). C. elegans II. Cold Spring Harbor Laboratory Press, New York, pp 1-4, 679–683.

Online resources

WormBase - an extensive online database covering the biology and genomics of C. elegans and other nematodes
WormBook - a free online compendium of all aspects of C. elegans biology, including laboratory protocols
Wormatlas - an online database for behavioral and structural anatomy of C. elegans
Wellcome Trust Sanger Institute C. elegans page - half of the genome sequence is still maintained by this institute
WashU Genome Sequencing Center C. elegans page - the institute maintaining the other half of the genome
AceView WormGenes - another genome database for C. elegans, maintained at the NCBI
Worm Classroom - An education portal for C. elegans
Textpresso - WormBase search engine
C. elegans movies - Timelapse films made by C. elegans researchers worldwide
C. elegans II - a free online textbook.
Silencing Genomes RNA interference (RNAi) experiments and bioinformatics in C. elegans for education. From the Dolan DNA Learning Center of Cold Spring Harbor Laboratory.

Nobel lectures

Brenner S (2002) Nature's Gift to Science. In. http://nobelprize.org/nobel_prizes/medicine/laureates/2002/brenner-lecture.pdf
Horvitz HR (2002) Worms, Life and Death. In. http://nobelprize.org/nobel_prizes/medicine/laureates/2002/horvitz-lecture.pdf
Sulston JE (2002) The Cell Lineage and Beyond. In. http://nobelprize.org/nobel_prizes/medicine/laureates/2002/sulston-lecture.pdf

External links

Nematodes With a Craving for Nicotine

Major Model Organisms in Genetic Studies • • [ e]
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Scientific classification or biological classification is a method by which biologists group and categorize species of organisms. Scientific classification also can be called scientific taxonomy, but should be distinguished from folk taxonomy, which lacks scientific basis.
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Nematoda
Rudolphi, 1808

Classes

Adenophorea
   Subclass Enoplia
   Subclass Chromadoria
Secernentea
   Subclass Rhabditia
   Subclass Spiruria
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Secernentea

Subclasses

see text

Secernentea are a class of nematodes characterised by numerous caudal papillae and an excretory system possessing lateral canals. They have no circulatory or respiratory system.
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Rhabditida
Chitwood, 1933

Families

Cephalobidae
Myolaimidae
Oxyuridae
Panagrolaimidae
Rhabditidae
Steinernematidae
Strongyloididae
Teratocephalidae

Synonyms

Oxyurida

Rhabditida
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Caenorhabditis

This genus contains the noted model organism Caenorhabditis elegans and several other species for which a genome sequence is available for, or which is currently being determined. The two most-studied species in this genus (C.
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binomial nomenclature is the formal system of naming species. The system is also called binominal nomenclature (particularly in zoological circles), binary nomenclature (particularly in botanical circles), or the binomial classification system.
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Nematoda
Rudolphi, 1808

Classes

Adenophorea
   Subclass Enoplia
   Subclass Chromadoria
Secernentea
   Subclass Rhabditia
   Subclass Spiruria
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1 millimetre =
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Molecular biology is the study of biology at a molecular level. The field overlaps with other areas of biology and chemistry, particularly genetics and biochemistry. Molecular biology chiefly concerns itself with understanding the interactions between the various systems of a cell,
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Developmental Biology is the official journal of the Society for Developmental Biology. It publishes research on the mechanisms of development, differentiation, and growth in animals and plants at the molecular, cellular, and genetic levels.
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19th century - 20th century - 21st century
1940s 1950s 1960s - 1970s - 1980s 1990s 2000s
1971 1972 1973 - 1974 - 1975 1976 1977

Year 1974 (MCMLXXIV
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Sydney Brenner, CH FRS (born January 13, 1927) is a South African biologist and 2002 Nobel prize in Physiology or Medicine laureate.

Brenner was born in a small town, Germiston (South Africa). His parents were immigrants.
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model organism is a species that is extensively studied to understand particular biological phenomena, with the expectation that discoveries made in the organism model will provide insight into the workings of other organisms.
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Vermiform is an adjective meaning worm-like. Assuming that the features of a worm-like animal include bilateral symmetry, leglessness and soft-bodies with a length greater than two or three times its breadth, there are 16 animal phyla which can be considered to consist solely of
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cuticle or cuticula is given to a variety of tough but flexible, non-mineral outer coverings of an organism, or part of an organism, that provide protection. They are non-homologous, differing in their origin, structure and chemical composition.
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body cavity is any fluid filled space in a multicellular organism. However, the term usually refers to the space, located between an animal’s outer covering (epidermis) and the outer lining of the gut cavity, where internal organs develop.
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hermaphrodite is an organism that posses both male and female genetalia.^[1] In many species, hermaphroditism is a common part of the life-cycle, particularly in some asexual animals and some plants.
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The gonad is the organ that makes gametes. The gonads in males are the testes and the gonads in females are the ovaries. The product, gametes, are haploid germ cells. For example, sperm and egg cells are gametes.
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The vas deferens (plural: vasa deferentia), also called ductus deferens, (Latin: "carrying-away vessel") is part of the male anatomy of some species, including humans.
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larva (Latin; plural larvae) is a juvenile form of animal with indirect development, undergoing metamorphosis (for example, insects or amphibians).

The larva can look completely different from the adult form, for example, a caterpillar differs from a butterfly.
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Dauer is a German word meaning "enduring" and is used to describe an alternative developmental stage of nematodes, particularly Caenorhabditis elegans. It is also considered by some to be equivalent to the infective stage of parasitic nematode larvae.
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Celsius is, or relates to, the Celsius temperature scale (previously known as the centigrade scale). The degree Celsius (symbol: °C) can refer to a specific temperature on the Celsius scale
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An autosome is a non-sex chromosome. It is an ordinarily pairedIn the case of higher ploidy levels than the usual diploid, there will be the same number of an autosome as the ploidy level itself. For example, in a pentaploid, there will be five copies of each autosome.
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A sex-determination system is a biological system that determines the development of sexual characteristics in an organism. Most sexual organisms have two sexes. In many cases, sex determination is genetic: males and females have different alleles or even different genes that
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The X0 sex-determination system is a system that grasshoppers, crickets, roaches, and some other insects use to determine the sex of their offspring. In this system, there is only one sex chromosome, referred to as X.
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strain is used in three related ways.

Microbiology/Virology

A strain is a genetic variant or subtype of a virus or bacterium. For example, a "flu strain" is a certain biological form of the influenza or "flu" virus. Compare clade.
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Cellular differentiation is a concept from developmental biology describing the process by which cells acquire a "type". The morphology of a cell may change dramatically during differentiation, but the genetic material remains the same, with few exceptions.
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