Likewise, nose-touch-evoked calcium transients in FLP were signif

Likewise, nose-touch-evoked calcium transients in FLP were significantly reduced, resembling in magnitude the responses in the RIH-ablated animals ( Figure S7); FLP harsh head touch responses, in contrast, were unaffected ( Figure S7). unc-7 loss-of-function

mutants showed partial defects in nose touch escape behavior ( Figures S7 and S8). These nose touch defects were rescued when a functional unc-7(+) transgene was expressed in the nose touch circuit using the cat-1 (expressed in the CEPs, RIH, and few other neurons) and egl-46 www.selleckchem.com/products/epacadostat-incb024360.html (expressed in FLP and PVD) promoters ( Figure 6B; Figures S7 and S8). unc-7(+) expression using either promoter alone did not result in phenotypic rescue (data not shown), suggesting that gap junction formation requires production of the innexin protein in both connected neurons. In contrast, mutations in unc-13, which impair synaptic transmission, did not detectably impair RIH nose touch responses ( Figure 6B). Together, these results support the hypothesis that signaling in the RIH-centered nose touch circuit is predominantly, if not exclusively, mediated by gap junctions. If signaling in the nose touch circuit is mediated primarily by gap junctions, information flow through RIH might be bidirectional: just as activation of neurons such as OLQ can indirectly excite FLP,

FLP activation could be able to excite OLQ. We examined this possibility by imaging OLQ calcium dynamics in response to mechanical stimuli sensed by FLP. We observed that harsh touch applied to the side of the head led to robust calcium transients in OLQ as well as RIH http://www.selleckchem.com/products/blz945.html (Figures 8B and 8C; Figure S7E). Mutations in the mechanosensory channel mec-10 eliminated OLQ and RIH responses to harsh head touch, and these responses could be rescued by FLP-specific expression of mec-10 ( Figures 8B and 8C; Figure S7E). Moreover,

ablation of RIH eliminated the harsh head-touch-evoked calcium transients in OLQ ( Figures 8B and 8C), indicating that the FLPs indirectly activate the OLQs through the RIH-centered network. We also tested the effect of the network on nose touch responses in OLQ. Interestingly, a mec-10 mutation significantly impaired OLQ and RIH calcium responses to nose touch; oxyclozanide these defects were rescued by mec-10(+) expression in FLP ( Figures 8B and 8D). Furthermore, ablation of RIH significantly reduced the responses of the OLQ neurons to nose touch ( Figures 8B and 8D). These results indicate that just as the nose touch responses of the FLPs depend on a combination of RIH-mediated network activity and cell-autonomous MEC-10 function, OLQ nose touch responses depend on both RIH-mediated network activity and cell-autonomous OSM-9 function. We have shown here how a network of interacting mechanosensory neurons detects nose touch stimuli and in response evokes escape behavior.

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