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J Proteomics,
2010]
Much of our knowledge on heredity, development, physiology and the underlying cellular and molecular processes is derived from the studies of model, or reference, organisms. Despite the great variety of life, a common base of shared principles could be extracted by studying a few life forms, selected based on their amenability to experimental studies. Very briefly, the origins of a few model organisms are described, including E. coli, yeast, C. elegans, Drosophila, Xenopus, zebrafish, mouse, maize and Arabidopsis. These model organisms were chosen because of their importance and wide use, which made them systems of choice for genome-wide studies. Many of their genomes were between the first to be fully sequenced, opening unprecedented opportunities for large-scale transcriptomics and proteomics studies.
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Genetics,
2015]
A little over 50 years ago, Sydney Brenner had the foresight to develop the nematode (round worm) Caenorhabditis elegans as a genetic model for understanding questions of developmental biology and neurobiology. Over time, research on C. elegans has expanded to explore a wealth of diverse areas in modern biology including studies of the basic functions and interactions of eukaryotic cells, host-parasite interactions, and evolution. C. elegans has also become an important organism in which to study processes that go awry in human diseases. This primer introduces the organism and the many features that make it an outstanding experimental system, including its small size, rapid life cycle, transparency, and well-annotated genome. We survey the basic anatomical features, common technical approaches, and important discoveries in C. elegans research. Key to studying C. elegans has been the ability to address biological problems genetically, using both forward and reverse genetics, both at the level of the entire organism and at the level of the single, identified cell. These possibilities make C. elegans useful not only in research laboratories, but also in the classroom where it can be used to excite students who actually can see what is happening inside live cells and tissues.
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Nat Rev Genet,
2001]
The nematode Caenorhabditis elegans is well known to practising biologists as a model organism. Early work with C. elegans is best understood as part of a descriptive tradition in biological practice. Although the resources that have been generated by the C. elegans community have been revolutionary, they were produced by traditional methods and approaches. Here, I review the choice and use of the worm as an experimental organism for genetics and neurobiology that began in the 1960s.
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Neuron,
2024]
In an interview with Neuron, Cori Bargmann discusses C.&#
xa0;elegans as a model organism, the importance of considering the animal's own world (thinking like a worm), choosing a scientific problem, and her experience as head of science at the Chan Zuckerberg Initiative and co-chair of the BRAIN Initiative.
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Gradolewski D, Krawczuk M, Tojza P, Koncicki A, Ambroziak D, Redlarski G, Lewczuk B, Jakubiuk K, Jaworski J, Skarbek L, Piechocki J, Zak A
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Biomed Res Int,
2015]
Current technologies have become a source of omnipresent electromagnetic pollution from generated electromagnetic fields and resulting electromagnetic radiation. In many cases this pollution is much stronger than any natural sources of electromagnetic fields or radiation. The harm caused by this pollution is still open to question since there is no clear and definitive evidence of its negative influence on humans. This is despite the fact that extremely low frequency electromagnetic fields were classified as potentially carcinogenic. For these reasons, in recent decades a significant growth can be observed in scientific research in order to understand the influence of electromagnetic radiation on living organisms. However, for this type of research the appropriate selection of relevant model organisms is of great importance. It should be noted here that the great majority of scientific research papers published in this field concerned various tests performed on mammals, practically neglecting lower organisms. In that context the objective of this paper is to systematise our knowledge in this area, in which the influence of electromagnetic radiation on lower organisms was investigated, including bacteria, E. coli and B. subtilis, nematode, Caenorhabditis elegans, land snail, Helix pomatia, common fruit fly, Drosophila melanogaster, and clawed frog, Xenopus laevis.
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Genetics,
1996]
I fell in love with Caenorhabditis elegans in the summer of '72. Our relationship was cemented four years later, 20 years ago now, by the publication of a paper in Genetics on C. elegans chromosome rearrangements (Herman et al. 1976). My pleasant assignment here is to describe the beginning of that work and to relate it to current worm cytogenetics and chromosome mechanics.
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Science,
2002]
The nematode worm known as Caenorhabditis elegans is not much to look at. Just a millimeter long and transparent to boot, it is almost invisible to the naked eye. But in biological research the tiny worm looms large, providing a model system for studying everything from embryonic development to aging. Now, three researchers who pioneered the use of C. elegans as a model organism have won the Nobel Prize in Physiology or Medicine.
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Genetics,
2002]
This article marks the 25th anniversary of a paper reporting the first sex-determination mutants to be found in the nematode Caenorhabditis elegans. The isolation of these mutants initiated an extensive analysis of nematode sex determination and dosage compensation, carried out by a number of laboratories over the subsequent decades. As a result, the process of sex determination is now one of the most thoroughly understood parts of C. elegans development, in both genetic and molecular terms. It has also proved to have interesting repercussions on the study of sex determination in other organisms.
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Exp Oncol,
2012]
The story of cell death began with the origins of cell biology, including important observations by Elie (Ilya) Metchnikoff, who realized that phagocytes engulfed dying cells. Most of the early studies were observational. By the middle of the 20th C, researchers were beginning to explore how cells died, had recognized that cell death was a physiologically controlled process, that the most common mode of death ("shrinkage necrosis", later apoptosis) was tightly controlled, and were speculating whether lysosomes were "suicide bags". Just prior to 1990 several discoveries led to rapid expansion of interest in the field and elucidation of the mechanisms of apoptosis. Closer to the beginning of the 21st C comprehensive analysis of the molecules that controlled and effected apoptosis led to the conclusion that autophagic processes were linked to apoptosis and could serve to limit or increase cell death. Today, realizing that knowledge of the components of cell death has not yet produced pharmaceuticals of therapeutic value, research is turning to questions of what metabolic or other mechanisms indirectly control the activation or suppression of the cell death positive feedback loop. This article is part of a Special Issue entitled "Apoptosis: Four Decades Later"
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Stud Hist Philos Biol Biomed Sci,
2012]
This paper argues that the history of the computer, of the practice of computation and of the notions of 'data' and 'programme' are essential for a critical account of the emergence and implications of data-driven research. In order to show this, I focus on the transition that the investigations on the worm C. elegans experienced in the Laboratory of Molecular Biology of Cambridge (UK). Throughout the 1980s, this research programme evolved from a study of the genetic basis of the worm's development and behaviour to a DNA mapping and sequencing initiative. By examining the changing computing technologies which were used at the Laboratory, I demonstrate that by the time of this transition researchers shifted from modelling the worm's genetic programme on a mainframe apparatus to writing minicomputer programs aimed at providing map and sequence data which was then circulated to other groups working on the genetics of C. elegans. The shift in the worm research should thus not be simply explained in the application of computers which transformed the project from hypothesis-driven to a data-intensive endeavour. The key factor was rather a historically specific technology-in-house and easy programmable minicomputers-which redefined the way of achieving the project's long-standing goal, leading the genetic programme to co-evolve with the practices of data production and distribution.