TRP channel proteins constitute a large and diverse family of proteins that are expressed in many tissues and cell types. This family was designated TRP because of a spontaneously occurring Drosophila mutant lacking TRP that responded to a continuous light with a transient receptor potential (hence TRP). In addition to responses to light, TRPs mediate responses to nerve growth factor, pheromones, olfaction, mechanical, chemical, temperature, pH, osmolarity, vasorelaxation of blood vessels, and metabolic stress. Furthermore, mutations in several members of TRP-related channel proteins are responsible for several diseases, such as several tumors and neurodegenerative disorders. TRP-related channel proteins are found in a variety of organisms, tissues, and cell types, including nonexcitable, smooth muscle, and neuronal cells. The large functional diversity of TRPs is also reflected in their diverse permeability to ions, although, in general, they are classified as nonselective cationic channels. The molecular domains that are conserved in all members of the TRP family constitute parts of the transmembrane domains and in most members also the ankyrin-like repeats at the NH2 terminal of the protein and a "TRP domain" at the COOH terminal, which is a highly conserved 25-amino acid stretch with still unknown function. All of the above features suggest that members of the TRP family are "special assignment" channels, which are recruited to diverse signaling pathways. The channels' roles and characteristics such as gating mechanism, regulation, and permeability are determined by evolution according to the specific functional requirements.
Transduction of mechanical stimuli by receptor neurons is essential for senses such as hearing, touch, and pain1–4. Ion channels play a role in neuronal mechanotransduction in invertebrates1; however, functional conservation of these ion channels in mammalian mechanotransduction is not observed. For example, NOMPC, a TRP ion channel, acts as a mechanotransducer in Drosophila melanogaster5 and Caenorhabditis elegans6,7; however, it has no orthologues in mammals. DEG/ENaC family members are mechanotransducers in C. elegans8 and potentially in D. melanogaster9; however, a direct role of its mammalian homologues in sensing mechanical force is not shown. Recently, Piezo1 and Piezo2 were identified as components of mechanically activated (MA) channels in mammals10. Piezos represent an evolutionary conserved family of transmembrane proteins. It is unknown whether Piezos function in mechanical sensing in vivo, and if they do, which mechanosensory modalities they mediate. Here, we study the physiological role of the single Piezo member in D. melanogaster (dpiezo). dpiezo expression in human cells induces mechanically activated currents, similar to its mammalian counterparts [Coste et al., accompanying paper11]. Behavioral responses to noxious mechanical stimuli were severely reduced in dpiezo knockout larvae, while responses to another noxious stimulus or touch were not affected. Knocking down dpiezo in sensory neurons that mediate nociception and express the DEG/ENaC ion channel pickpocket (ppk) was sufficient to impair responses to noxious mechanical stimuli. Furthermore, expression of dpiezo in these same neurons rescued the phenotype of the constitutive dpiezo knockout larvae. Accordingly, electrophysiological recordings from ppk-positive neurons revealed a dpiezo dependent, mechanically-activated current. Finally, we found that dpiezo and ppk function in parallel pathways in ppk-positive cells, and that mechanical nociception is abolished in the absence of both channels. These data demonstrate physiological relevance of Piezo family in mechanotransduction in vivo, supporting a role of Piezo proteins in mechanosensory nociception.
Mammals can taste a wide repertoire of chemosensory stimuli. Two unrelated families of receptors (T1Rs and T2Rs) mediate responses to sweet, amino acids, and bitter compounds. Here, we demonstrate that knockouts of TRPM5, a taste TRP ion channel, or PLCbeta2, a phospholipase C selectively expressed in taste tissue, abolish sweet, amino acid, and bitter taste reception, but do not impact sour or salty tastes. Therefore, despite relying on different receptors, sweet, amino acid, and bitter transduction converge on common signaling molecules. Using PLCbeta2 taste-blind animals, we then examined a fundamental question in taste perception: how taste modalities are encoded at the cellular level. Mice engineered to rescue PLCbeta2 function exclusively in bitter-receptor expressing cells respond normally to bitter tastants but do not taste sweet or amino acid stimuli. Thus, bitter is encoded independently of sweet and amino acids, and taste receptor cells are not broadly tuned across these modalities.
SUMMARY Background In most cells, the cilium is formed within a compartment separated from the cytoplasm. Entry into the ciliary compartment is regulated by a specialized gate located at the base of the cilium in a region known as the transition zone. The transition zone is closely associated with multiple structures of the ciliary base including the centriole, axoneme, and ciliary membrane. However, the contribution of these structures to the ciliary gate remains unclear. Results Here, we report that in Drosophila spermatids, a conserved module of transition zone proteins mutated in Meckel-Gruber Syndrome (MKS) including Cep290, Mks1, B9d1, and B9d2 comprise a ciliary gate that continuously migrates away from the centriole to compartmentalize the growing axoneme tip. We show that Cep290 is essential for transition zone composition, compartmentalization of the axoneme tip, and axoneme integrity, and find that MKS proteins also delimit a centriole-independent compartment in mouse spermatids. Conclusion Our findings demonstrate that the ciliary gate can migrate away from the base of the cilium, thereby functioning independently of the centriole and of a static interaction with the axoneme to compartmentalize the site of axoneme assembly.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.