Showing papers on "TRPV published in 2004"

TRPV4 calcium entry channel: a paradigm for gating diversity.

Abstract: The vanilloid receptor-1 (VR1, now TRPV1) was the founding member of a subgroup of cation channels within the TRP family. The TRPV subgroup contains six mammalian members, which all function as Ca2...

Two Interdependent TRPV Channel Subunits, Inactive and Nanchung, Mediate Hearing in Drosophila

Abstract: Hearing in Drosophila depends on the transduction of antennal vibration into receptor potentials by ciliated sensory neurons in Johnston's organ, the antennal chordotonal organ. We previously found that a Drosophila protein in the vanilloid receptor subfamily (TRPV) channel subunit, Nanchung (NAN), is localized to the chordotonal cilia and required to generate sound-evoked potentials (Kim et al., 2003). Here, we show that the only other Drosophila TRPV protein is mutated in the behavioral mutant inactive (iav). The IAV protein forms a hypotonically activated channel when expressed in cultured cells; in flies, it is specifically expressed in the chordotonal neurons, localized to their cilia and required for hearing. IAV and NAN are each undetectable in cilia of mutants lacking the other protein, indicating that they both contribute to a heteromultimeric transduction channel in vivo. A functional green fluorescence protein-IAV fusion protein shows that the channel is restricted to the proximal cilium, constraining models for channel activation.

A TRPV2-PKA signaling module for transduction of physical stimuli in mast cells.

Abstract: Cutaneous mast cell responses to physical (thermal, mechanical, or osmotic) stimuli underlie the pathology of physical urticarias. In vitro experiments suggest that mast cells respond directly to these stimuli, implying that a signaling mechanism couples functional responses to physical inputs in mast cells. We asked whether transient receptor potential (vanilloid) (TRPV) cation channels were present and functionally coupled to signaling pathways in mast cells, since expression of this channel subfamily confers sensitivity to thermal, osmotic, and pressure inputs. Transcripts for a range of TRPVs were detected in mast cells, and we report the expression, surface localization, and oligomerization of TRPV2 protein subunits in these cells. We describe the functional coupling of TRPV2 protein to calcium fluxes and proinflammatory degranulation events in mast cells. In addition, we describe a novel protein kinase A (PKA)–dependent signaling module, containing PKA and a putative A kinase adapter protein, Acyl CoA binding domain protein (ACBD)3, that interacts with TRPV2 in mast cells. We propose that regulated phosphorylation by PKA may be a common pathway for TRPV modulation.

The Transient Receptor Potential Superfamily of Ion Channels

Abstract: . The transient receptor potential (TRP) superfamily of proteins is cation-selective ion channels with six predicted transmembrane segments and intracellularly localized amino and carboxyl termini. Members of the TRP superfamily are identified on the basis of amino acid sequence and structural similarity and are classified into TRPC, TRPV, TRPM, TRPP, TRPN, and TRPML subfamilies. TRP channels are widespread and have diverse functions, ranging from thermal, tactile, taste, osmolar, and fluid flow sensing to transepithelial Ca2+ and Mg2+ transport. Mutations of TRP proteins produce many renal diseases, including Mg2+ wasting, hypocalcemia, and polycystic kidney diseases. This review focuses on recent advances in the understanding of their functions.

Caenorhabditis elegans TRPV ion channel regulates 5HT biosynthesis in chemosensory neurons.

Abstract: Serotonin (5HT) is a pivotal signaling molecule that modulates behavioral and endocrine responses to diverse chemical and physical stimuli. We report cell-specific regulation of 5HT biosynthesis by transient receptor potential V (TRPV) ion channels in C. elegans. Mutations in the TRPV genes osm-9 or ocr-2 dramatically downregulate the expression of the gene encoding the 5HT synthesis enzyme tryptophan hydroxylase (tph-1) in the serotonergic chemosensory neurons ADF, but neither the mutation nor the double mutation of both channel genes affects other types of serotonergic neurons. The TRPV genes are expressed in the ADF neurons but not in other serotonergic neurons, and act cell-autonomously to regulate a neuron-specific transcription program. Whereas in olfactory neurons OSM-9 and OCR-2 function is dependent on ODR-3 Galpha, the activity of ODR-3 or two other Galpha proteins expressed in the ADF neurons is not required for upregulating tph-1 expression, thus the TRPV ion channels in different neurons may be regulated by different mechanisms. A gain-of-function mutation in CaMKII UNC-43 partially suppresses the downregulation of tph-1 in the TRPV mutants, thus CaMKII may be an effector of the TRPV signaling. Mutations in the TRPV genes cause worms developmentally arrest at the Dauer stage. This developmental defect is due in part to reduced 5HT inputs into daf-2/insulin neuroendocrine signaling.

Diversity of TRP channel activation

Abstract: Calcium entry controls a plethora of short- and long-term cell functions. With respect to the activation mechanisms of Ca2+ entry channels they are subdivided in the thoroughly characterized voltage-gated Ca2+ channels and the non-voltage gated Ca2+ channels. The latter group includes cation channels of the 'transient receptor potential' (TRP) superfamily, which consists of three subfamilies (TRPC, TRPV, TRPM). Activation of TRP channels is not yet completely understood, but examples of activation mechanisms of TRP channels from all three subfamilies will be discussed. The main focus is on the members of the TRPV subfamily, among which the TRPV4 channel shows a surprising gating promiscuity. It can be activated by cell swelling, heat and phorbol esters. Endogenous activators of the channel have not yet been described. It will be shown that lipid messengers related to arachidonic acid are endogenous TRPV4 activators. For TRPV5 and 6, the only highly Ca2+ selective channels within the TRP super-family, a voltage-dependent gating mechanism will be discussed, which includes an open pore block by Mg2+ and a highly Ca2+-sensitive mechanism of inactivation. Regulation of channel availability by interaction with a protein bound to a site at the C-terminus of both channels will be demonstrated. Functional consequences of these different mechanisms of gating will be discussed.

Nociceptin inhibits vanilloid TRPV-1-mediated neurosensitization induced by fenoterol in human isolated bronchi

Abstract: Chronic exposure to β2-adrenoceptor agonists, especially fenoterol, has been shown to increase smooth muscle contraction to endothelin-1 in human bronchi partly through tachykinin-mediated pathways. The purpose of this work was to further investigate the role of sensory nerves in fenoterol-induced sensitization of human airways and the effect of nociceptin, a nociceptin/orphanin FQ (NOP) receptor agonist, on the increase in contraction after fenoterol exposure. Human bronchi from 62 patients were sensitized to endothelin-1 by prolonged incubation with fenoterol (0.1 μM, 15 h). The sensitizing effect of fenoterol was inhibited by high concentration of capsaicin (10 μM, 30 min before fenoterol sensitization), which induces depletion of mediators from sensory nerves, or co-incubation of fenoterol and capsazepine (1 μM), a vanilloid TRPV-1 receptor antagonist. Moreover, short pretreatment of bronchi with capsaicin (10 μM) or capsazepine (1 μM) after sensitization by fenoterol decreased the rise in smooth muscle contraction to endothelin-1. Nociceptin (1 μM) also inhibited the increased contraction in fenoterol-sensitized bronchi. Tertiapin (10 μM), an inhibitor of the inward-rectifier K+ channels, but not naloxone (0.1 μM), a DOP/KOP/MOP receptor antagonist, prevented the inhibitory effect of nociceptin. In conclusion, fenoterol induces sensitization of human isolated bronchi to endothelin-1 in part through the stimulation of the vanilloid TRPV-1 receptor on tachykininergic sensory nerves. Nociceptin inhibits airway hyperresponsiveness via NOP receptor activation. This effect involves inward-rectifier K+ channels.