Abstract
BackgroundAny organism depends on its ability to sense temperature and avoid noxious heat. The nematode Caenorhabditis elegans responds to noxious temperatures exceeding ∼35°C and also senses changes in its environmental temperature in the range between 15 and 25°C. The neural circuits and molecular mechanisms involved in thermotaxis have been successfully studied, whereas details of the thermal avoidance behavior remain elusive. In this work, we investigate neurological and molecular aspects of thermonociception using genetic, cell biological and physiological approaches.Methodology/Principal FindingsWe show here that the thermosensory neurons AFD, in addition to sensing temperature within the range within which the animals can thrive, also contribute to the sensation of noxious temperatures resulting in a reflex-like escape reaction. Distinct sets of interneurons are involved in transmitting thermonociception and thermotaxis, respectively. Loss of AFD is partially compensated by the activity of a pair of multidendritic, polymodal neurons, FLP, whereas laser ablation of both types of neurons abrogated the heat response in the head of the animals almost completely. A third pair of heat sensory neurons, PHC, is situated in the tail. We find that the thermal avoidance response requires the cell autonomous function of cGMP dependent Cyclic Nucleotide-Gated (CNG) channels in AFD, and the heat- and capsaicin-sensitive Transient Receptor Potential Vanilloid (TRPV) channels in the FLP and PHC sensory neurons.Conclusions/SignificanceOur results identify distinct thermal responses mediated by a single neuron, but also show that parallel nociceptor circuits and molecules may be used as back-up strategies to guarantee fast and efficient responses to potentially detrimental stimuli.
Highlights
Noxious environmental stimuli, such as heat, trigger a survival response in animals resulting in reflexive escape reactions
We directly examined a possible role of the AFD thermosensory neurons in sensing noxious heat by eliminating these and other neurons using microsurgery
The head Tav response is mediated by a cGMP signaling pathway in the AFD neurons In the search for candidate proteins sensing heat or transmitting heat-induced stimuli in the AFD neurons, we focused on the Cyclic Nucleotide-Gated (CNG) proteins that are expressed in several sensory neurons including AFD but not FLP [11,34,35]
Summary
Noxious environmental stimuli, such as heat, trigger a survival response in animals resulting in reflexive escape reactions. The nematode C. elegans responds to a wide variety of external stimuli, involving noxious chemicals, high osmolarities, acidic pH, noxious mechanical stimuli, harmful light (UV) and noxious heat [5,6,7,8,9], and senses temperature range within which the animals can thrive. C. elegans perceives temperatures in the range between 15 and 25uC preferably by using a pair of sensory neurons AFD These are connected to the AIY interneurons via chemical synapses [10]. This thermotaxis behavior is mediated by a cGMP signaling pathway activating the downstream tax-2 and tax-4 CNG channels [11,12]. We investigate neurological and molecular aspects of thermonociception using genetic, cell biological and physiological approaches
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