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Pflugers Arch,
2015]
Mechanosensory neurons, whose activity is controlled by mechanical force, underlie the senses of touch, hearing, and proprioception, yet despite their importance, the molecular basis of mechanotransduction is poorly understood. Genetic studies in Caenorhabditis elegans have provided a useful approach for identifying potential components of mechanotransduction complexes that might be conserved in more complex organisms. This review describes the mechanosensory systems of C. elegans, including the sensory neurons and circuitry involved in body touch, nose touch, and proprioception. In addition, the roles of genes encoding known and potential mechanosensory receptors, including members of the broadly conserved transient receptor potential (TRP) and degerin/epithelial Na(+) channel (DEG/ENaC) channel families, are discussed.
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Bioessays,
1996]
The nematode C. elegans exhibits a variety of responses to touch. When specific sets of mechanosensory neurons are killed with a laser, specific touch responses are abolished. Many mutations that result in defective mechanosensation have been identified. Some of the mutations define genes that specify the fate of a set of mechanoreceptors called the touch cells, which mediate response to light touch to the body of the worm. Genes specifying touch cell fate appear to regulate genes that encode touch-cell differentiation proteins, including apparent subunits of a touch-cell-specific ion channel, rare mutant forms of which lead to swelling and lysis of the touch cells. Molecular attachments of the ion channel, both to extracellular matrix components and, intracellularly, to a special large-diameter microtubule, may be required for mechanical gating of the channel. A mechanoreceptor-interneuron-motorneuron reflex circuit for response to light touch has been proposed.
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Curr Biol,
1996]
The cloning of genes needed for gentle-touch sensitivity in the nematode Caenorhabditis elegans has provided new molecular details about a proposed mechanosensory ion channel complex.
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J Cell Biol,
2010]
The sense of touch detects forces that bombard the body's surface. In metazoans, an assortment of morphologically and functionally distinct mechanosensory cell types are tuned to selectively respond to diverse mechanical stimuli, such as vibration, stretch, and pressure. A comparative evolutionary approach across mechanosensory cell types and genetically tractable species is beginning to uncover the cellular logic of touch reception.
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Annu Rev Neurosci,
1998]
Caenorhabditis elegans interacts with its environment by sensing chemicals, touch, and temperature; genetic analysis of each of these responses has led to the identification of candidate signaling molecules within sensory neurons. A molecular model for touch sensation has emerged from studies of the mechanosensory response; the receptors and signal transduction mechanisms in olfactory neurons are being elucidated; and an unusual neuroendocrine role for a TGF-beta-related peptide in chemosensory neurons has been discovered. Presynaptic and postsynaptic components of neuronal synapses have been identified in behavioral and pharmacological mutant screens. Mutations have been found in multiple classes of nicotinic acetylcholine receptor genes, excitatory and inhibitory glutamate receptor genes, and candidate gap junction genes, allowing their function to be studied in vivo. Different G-protein signaling pathways have characteristic effects on behavior, neuronal degeneration, and embryonic development.
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J Neurobiol,
1993]
Mutations causing a touch-insensitive phenotype in the nematode Caenorhabditis elegans have been the basis of studies on the specification of neuronal cell fate, inherited neurodegeneration, and the molecular nature of mechanosensory transduction. (C) 1993 John Wiley & sons, Inc.
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WormBook,
2014]
C. elegans detect and respond to diverse mechanical stimuli using neuronal circuitry that has been defined by decades of work by C. elegans researchers. In this WormMethods chapter, we review and comment on the techniques currently used to assess mechanosensory response. This methods review is intended both as an introduction for those new to the field and a convenient compendium for the expert. A brief discussion of commonly used mechanosensory assays is provided, along with a discussion of the neural circuits involved, consideration of critical protocol details, and references to the primary literature.
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Pflugers Arch - European Journal of Physiology,
2005]
Transient receptor potential vanilloid (TRPV) channels are widely expressed in both sensory and nonsensory cells. Whereas the channels display a broad diversity to activation by chemical and physical stimuli, activation by mechanical stimuli is common to many members of this group in both lower and higher organisms. Genetic screening in Caenorhabditis elegans has demonstrated an essential role for two TRPV channels in sensory neurons. OSM-9 and OCR-2, for example, are essential for both osmosensory and mechanosensory (nose-touch) behaviors. Likewise, two Drosophila TRPV channels, NAN and IAV, have been shown to be critical for hearing by the mechanosensitive chordotonal organs located in the fly''''s antennae. The mechanosensitive nature of the channels appears to be conserved in higher organisms for some TRPV channels. Two vertebrate channels, TRPV2 and TRPV4, are sensitive to hypotonic cell swelling, shear stress/fluid flow (TRPV4), and membrane stretch (TRPV2). In the osmosensing neurons of the hypothalamus (circumventricular organs), TRPV4 appears to function as an osmoreceptor, or part of an osmoreceptor complex, in control of vasopressin release, whereas in inner ear hair cells and vascular baroreceptors a mechanosensory role is suggestive, but not demonstrated. Finally, in many nonsensory cells expressing TRPV4, such as vascular endothelial cells and renal tubular epithelial cells, the channel exhibits well-developed local mechanosensory transduction processes where both cell swelling and shear stress/fluid flow lead to channel activation. Hence, many TRPV channels, or combinations of TRPV channels, display a mechanosensitive nature that underlies multiple mechanosensitive processes from worms to mammals.
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Genetics,
2018]
Sleep is crucial for survival and well-being. This behavioral and physiological state has been studied in all major genetically accessible model animals, including rodents, fish, flies, and worms. Genetic and optogenetic studies have identified several neurons that control sleep, making it now possible to compare circuit mechanisms across species. The "motor" of sleep across animal species is formed by neurons that depolarize at the onset of sleep to actively induce this state by directly inhibiting wakefulness. These sleep-inducing neurons are themselves controlled by inhibitory or activating upstream pathways, which act as the "drivers" of the sleep motor: arousal inhibits "sleep-active" neurons whereas various sleep-promoting "tiredness" pathways converge onto sleep-active neurons to depolarize them. This review provides the first overview of sleep-active neurons across the major model animals. The occurrence of sleep-active neurons and their regulation by upstream pathways in both vertebrate and invertebrate species suggests that these neurons are general and ancient components that evolved early in the history of nervous systems.
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Parasite,
1994]
Organelles and neurons of nematodes involved in sensing chemical signals present in the environment are described. Laser ablation of neurons has helped assign them a specific function. Genetic mutational analysis has led to the identification of genes controlling the behavior of the worms and/or some cellular properties of the chemosensory neurons. Some conclusions on the general organization and functioning of chemoreception in nematodes can be drawn.