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Elife,
2021]
Experiments in <i>C. elegans</i> reveal new insights into how the ANC-1 protein helps to anchor the nucleus and other organelles in place.
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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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Virulence,
2010]
The ability of free-living organisms to defend themselves against pathogen attack is essential for their survival in the environment. Thus, the cellular processes that coordinate host defense responses are strongly conserved across millions of years of evolution. The nematode Caenorhabditis elegans, for example, employs a sophisticated innate immune system to detect and counter pathogen attack, whether the invading microorganism is ingested or comes into external contact with the animal. Furthermore, genetic analyses in rigorous laboratory infection models have revealed that coordination of the nematode defense responses involves several highly conserved elements that have mammalian orthologs. Thus, the molecular dissection of innate immunity in C. elegans offers insights into the mechanisms and evolution of comparable systems in more highly evolved metazoans.
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Elife,
2023]
Various aspects of olfactory memory are represented as modulated responses across different classes of neurons in <i>C. elegans.</i>
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Elife,
2023]
A molecular pathway involving compounds found in processed foods and biogenic amines increases food intake and aging in the roundworm <i>C. elegans</i>.
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Cell Metab,
2007]
Dietary restriction provides considerable health benefits and may even increase life span in humans. Panowski et al. (2007) have now identified PHA-4/FoxA as an essential and specific component of DR-induced life-span extension in C. elegans.
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Cell,
2009]
The serine/threonine kinase Akt is a focal point in signaling pathways that control cell tumorigenesis and insulin resistance. In this issue, Padmanabhan et al. (2009) identify a phosphatase regulatory subunit PPTR-1 that regulates the insulin/insulin-like growth factor 1 pathway by counteracting Akt activity in worms and mammalian cells.
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Neuron,
2004]
Insulin/IGF signaling has emerged as a central regulator of metazoan aging. In C. elegans, insulin-like peptides are expressed predominately in neurons. Alcedo and Kenyon demonstrate that removal of specific gustatory and olfactory neurons result in longer life, suggesting that metazoan longevity is influenced by sensory perception.
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J Cell Biol,
2022]
During cytokinesis, microtubules become compacted into a dense midbody prior to abscission. Using genetic perturbations and imaging of C. elegans zygotes, Hirsch et al. (2022. J. Cell Biol.https://doi.org/10.1083/jcb.202011085) uncover an unexpected source of microtubules that can populate the midbody when central spindle microtubules are missing.
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J Neurophysiol,
2007]
The work of Clark et al. in this issue of J. Neurophysiology extends the analysis of thermotaxis in C. elegans by providing a detailed analysis of the adaptation of thermotactic behavior. Previous work indicates that thermotaxis in C. elegans involves a biased random walk in which changes in temperature alter the duration of the runs that an animal makes between turns. Interestingly, the authors find that although behavioral responses to increases and decreases in temperature have opposite effects on run length, the two responses are of similar magnitude and adapt with similar kinetics. These properties are predicted to allow the system act as a band-pass filter that would be less sensitive to temperature fluctuations occurring on a time-scale significantly faster or slower than the time needed for an average run. This analysis of C. elegans thermotaxis raises potential parallels to bacterial chemotaxis, with the kinetics of adaptation playing an important role in determining the ability of the organism to sense a stimulus gradient. This raises the possibility that diverse organisms may exploit similar system properties to solve similar problems, such as the problem of responding robustly to subtle gradations in an external stimulus.