The transient receptor potential (TRP) superfamily contains a large number of proteins encoding cation permeable channels that are further divided into TRPC (canonical), TRPM (melastatin), and TRPV (vanilloid) subfamilies. Among the six TRPV members, TRPV1, TRPV2, TRPV3, and TRPV4 form heat-activated cation channels, which serve diverse functions ranging from nociception to osmolality regulation. Although chemical activators for TRPV1 and TRPV4 are well documented, those for TRPV2 and TRPV3 are lacking. Here we show that in the absence of other stimuli, 2-aminoethoxydiphenyl borate (2APB) activates TRPV1, TRPV2, and TRPV3, but not TRPV4, TRPV5, and TRPV6 expressed in HEK293 cells. In contrast, 2APB inhibits the activity of TRPC6 and TRPM8 evoked by 1-oleolyl-2-acetyl-sn-glycerol and menthol, respectively. In addition, low levels of 2APB strongly potentiate the effect of capsaicin, protons, and heat on TRPV1 as well as that of heat on TRPV3 expressed in Xenopus oocytes. In dorsal root ganglia neurons, supra-additive stimulations were evoked by 2APB and capsaicin or 2APB and acid. Our data suggest the existence of a common activation mechanism for TRPV1, TRPV2, and TRPV3 that may serve as a therapeutic target for pain management and treatment for diseases caused by hypersensitivity and temperature misregulation. The transient receptor potential (TRP)1 superfamily of cation channels consists of a large number of recently identified molecules that share sequence homology with the Drosophila protein named after a phototransduction mutant called trp. According to sequence similarities, the TRP channels are further divided into subfamilies, such as TRPC (canonical), TRPM (melastatin), and TRPV (vanilloid) (see reviews in Refs. 1 and 2). These channels are involved in diverse cellular functions including receptor and store-operated Ca 2ϩ entry (3), Ca 2ϩ transport (4, 5), trace metal detection (6), and temperature (7-9) and osmolality (10, 11) sensations. The activation mechanisms for most of the TRP channels remain to be elucidated. Specific ligands have been found for TRPC3, TRPC6, TRPC7, TRPV1, TRPV4, TRPM2, TRPM4, TRPM5, TRPM7, and TRPM8. These include endogenous substances, such as lipids (diacylglycerol (12), anandamide (13, 14), and phosphatidylinositol 4,5-bisphosphate (15)), nucleotides (ADP-ribose (16) (23,24), 2APB was soon found to directly block native store-operated channels (25-27), sarco/ endoplasmic reticulum Ca 2ϩ -ATPase pumps (28), mitochondrial permeability transition pore (29), and a few other ion channels (30). The mechanism of action for 2APB is likely to be complex. In addition to inhibition, low concentrations of 2APB enhanced the activity of store-operated channels (26). At greater than 50 M, 2APB activated a Ca 2ϩ -permeable nonselective cation channel with a 50-picosiemens single channel conductance and very low open probability in rat basophilic leukemia cells (31).2APB has been perceived as a general inhibitor of TRP channels (1). However, except for TRPC3 (24,32), the effects of this drug...
Slow synaptic excitation (slow EPSP) in enteric neurones is recorded as a slowly activating depolarization of the membrane potential in specific populations of enteric neurones when neurotransmitters are released experimentally by focal electrical stimulation of presynaptic axons in the myenteric and submucosal plexuses (reviewed by Surprenant, 1989;Wood, 1994;Galligan, 1998;Gershon, 1998). Mediators released to the enteric nervous system in paracrine fashion from non-neuronal cell types (e.g. histamine and cytokines from enteric mast cells) can evoke responses that mimic slow synaptic excitation (Wood, 1992;Liu et al. 2003). Two kinds of slow EPSPs are recorded in enteric neurones. An increase in input resistance is associated with the depolarization and augmented excitability for one kind of slow EPSP. The input resistance decreases or remains unchanged during the depolarization and augmented excitability of the second kind. Slow EPSPs with increased input resistance are found generally in AH-type neurones with multipolar Dogiel Type II morphology. Most evidence suggests that the principal ionic mechanism for this type of slow EPSP is suppression of resting Ca 2+ -dependent K + conductance that accounts for the membrane depolarization, increased input resistance, and suppression of the Ca 2+ component of the rising phase of the action potential (e.g. Grafe et al. 1980). Signal transduction for the slow EPSP with increased input resistance involves coupling of metabotropic receptors through heterotrimeric G proteins to adenylate cyclase, and elevation of intraneuronal cyclic adenosine monophosphate (Palmer et al. 1986(Palmer et al. , 1987.Whereas slow EPSPs characterized by increased input resistance during the depolarizing response predominate in AH-type neurones in the myenteric plexus, slow EPSPs characterized by decreased input resistance are routinely found in S-type uniaxonal neurones in the small and large intestinal submucosal plexus. Likewise, application of putative neurotransmitters and paracrine mediators (e.g. serotonin, ATP and substance P) evoke slowly activating depolarizing responses associated with decreased input resistance in S-type neurones in the submucosal plexus.This report presents evidence that synaptically released ATP acts at P2Y 1 purinergic receptors to evoke slow EPSPs that are characterized by decreased input resistance in the submucosal plexus. The evidence suggests that the signal transduction cascade for the submucosal P2Y 1 receptor includes activation of phospholipase C, release of inositol 1,4,5-trisphosphate and elevation of cytosolic free Ca
Transient receptor potential vanilloid (TRPV) channels are polymodal detectors of multiple environmental factors, including temperature, pH, and pressure. Inflammatory mediators enhance TRPV function through multiple signaling pathways. The lipoxygenase and epoxygenase products of arachidonic acid (AA) metabolism have been shown to directly activate TRPV1 and TRPV4, respectively. TRPV3 is a thermosensitive channel with an intermediate temperature threshold of 31-39 degrees C. We have previously shown that TRPV3 is activated by 2-aminoethoxydiphenyl borate (2APB). Here we show that AA and other unsaturated fatty acids directly potentiate 2APB-induced responses of TRPV3 expressed in HEK293 cells, Xenopus oocytes, and mouse keratinocytes. The AA-induced potentiation is observed in intracellular Ca2+ measurement, whole-cell and two-electrode voltage clamp studies, as well as single channel recordings of excised inside-out and outside-out patches. The fatty acid-induced potentiation is not blocked by inhibitors of protein kinase C and thus differs from that induced by the kinase. The potentiation does not require AA metabolism but is rather mimicked by non-metabolizable analogs of AA. These results suggest a novel mechanism regulating the TRPV3 response to inflammation, which differs from TRPV1 and TRPV4, and involves a direct action of free fatty acids on the channel.
Transient receptor potential vanilloid 1 (TRPV1), or vanilloid receptor 1, is the founding member of the vanilloid type of TRP superfamily of nonselective cation channels. TRPV1 is activated by noxious heat, acid, and alkaloid irritants as well as several endogenous ligands and is sensitized by inflammatory factors, thereby serving important functions in detecting noxious stimuli in the sensory system and pathological states in different parts of the body. Whereas numerous studies have been carried out using the rat and human TRPV1 cDNA, the mouse TRPV1 cDNA has not been characterized. Here, we report molecular cloning of two TRPV1 cDNA variants from dorsal root ganglia of C57BL/6 mice. The deduced proteins are designated TRPV1␣ and TRPV1 and contain 839 and 829 amino acids, respectively. TRPV1 arises from an alternative intron recognition signal within exon 7 of the trpv1 gene. We found a predominant expression of TRPV1␣ in many tissues and significant expression of TRPV1 in dorsal root ganglia, skin, stomach, and tongue. When expressed in HEK 293 cells or Xenopus oocytes, TRPV1␣ formed a Ca 2؉ -permeable channel activated by ligands known to stimulate TRPV1. TRPV1 was not functional by itself but its coexpression inhibited the function of TRPV1␣. Furthermore, although both isoforms were synthesized at a similar rate, less TRPV1 than TRPV1␣ protein was found in cells and on the cell surface, indicating that the  isoform is highly unstable. Our data suggest that TRPV1 is a naturally occurring dominant-negative regulator of the responses of sensory neurons to noxious stimuli. Homologues of Drosophila transient receptor potential (TRP)1 protein form a rapidly growing family of non-selective cation channels known as the TRP superfamily. The TRP channels are involved in a large variety of cellular functions including receptor and store-operated Ca 2ϩ entry (1, 2), Ca 2ϩ transport (3, 4), temperature sensation (5, 6), and trace metal detection (7). The temperature-sensing TRP channels consist of at least 6 members with temperature thresholds ranging from as low as Ͻ17°C for extreme cold to Ͼ53°C for extreme heat (reviewed in Refs. 6 and 8). Among them, TRPV1 has received a great deal of attention because it was the first cloned channel that responded to pain-producing heat (Ͼ43°C) and acid stimuli and it is the receptor for capsaicin, the pungent ingredient of hot chili pepper (5, 9). These functional features and the predominant expression of TRPV1 mRNA in the small diameter neurons of the rat dorsal root ganglia (DRG) provide support for TRPV1 as a key player in nociception of primary afferent neurons. Subsequent studies showed that TRPV1 is activated by the endogenous cannabinoid receptor ligand anandamide, N-arachidonyldopamines, and several lipoxygenase products, such as 15-hydroxyeicosatetraenoic acid (10 -13) and its activity is strongly potentiated by inflammatory mediators (14), suggesting a role of TRPV1 besides nociception. Indeed, TRPV1 is expressed in non-sensory tissues (15). Detailed studies hav...
A recent study has demonstrated that increasing the intrathoracic temperature from 36 degrees C to 41 degrees C induced a distinct stimulatory and sensitizing effect on vagal pulmonary C-fiber afferents in anesthetized rats (J Physiol 565: 295-308, 2005). We postulated that these responses are mediated through a direct activation of the temperature-sensitive transient receptor potential vanilloid (TRPV) receptors by hyperthermia. To test this hypothesis, we studied the effect of increasing temperature on pulmonary sensory neurons that were isolated from adult rat nodose/jugular ganglion and identified by retrograde labeling, using the whole cell perforated patch-clamping technique. Our results showed that increasing temperature from 23 degrees C (or 35 degrees C) to 41 degrees C in a ramp pattern evoked an inward current, which began to emerge after exceeding a threshold of approximately 34.4 degrees C and then increased sharply in amplitude as the temperature was further increased, reaching a peak current of 173 +/- 27 pA (n = 75) at 41 degrees C. The temperature coefficient, Q10, was 29.5 +/- 6.4 over the range of 35-41 degrees C. The peak inward current was only partially blocked by pretreatment with capsazepine (Delta I = 48.1 +/- 4.7%, n = 11) or AMG 9810 (Delta I = 59.2 +/- 7.8%, n = 8), selective antagonists of the TRPV1 channel, but almost completely abolished (Delta I = 96.3 +/- 2.3%) by ruthenium red, an effective blocker of TRPV1-4 channels. Furthermore, positive expressions of TRPV1-4 transcripts and proteins in these neurons were demonstrated by RT-PCR and immunohistochemistry experiments, respectively. On the basis of these results, we conclude that increasing temperature within the normal physiological range can exert a direct stimulatory effect on pulmonary sensory neurons, and this effect is mediated through the activation of TRPV1, as well as other subtypes of TRPV channels.
The P2X(7) purinergic receptor subtype has been cloned and emphasized as a prototypic P2Z receptor involved in neurotransmission in the central nervous system and ATP-mediated lysis of macrophages in the immune system. Less is known about the neurobiology of P2X(7) receptors in the enteric nervous system (ENS). We studied the distribution of the receptor with indirect immunofluorescence and used selective agonists and antagonists to analyze pharmacologic aspects of its electrophysiologic behavior as determined with intracellular "sharp" microelectrodes and patch-clamp recording methods in neurons identified morphologically by biocytin injection in the ENS. Application of ATP or 2'- (or-3'-) O-(4-benzoylbenzoyl) adenosine 5'-triphosphate (BzBzATP) activated an inward current in myenteric neurons. Brilliant blue G, a selective P2X(7) antagonist, suppressed the responses to both agonists. Potency of the antagonist was greatest (smaller IC(50)) for the current evoked by BzBzATP. The P2X(7) antagonists 1-[N,O-bis (1,5-isoquinolinesulfonyl)-N-methyl-l-tyrosyl]-4-piperazine (KN-62) and oxidized ATP also suppressed the BzBzATP-activated current. Micropressure application of BzBzATP evoked rapidly activating depolarizing responses in intracellular studies with "sharp" microelectrodes. Oxidized-ATP suppressed these responses in both myenteric and submucosal neurons. Rapidly activating depolarizing responses evoked by application of nicotinic, serotonergic 5-HT(3), or gamma-aminobutyric acid A (GABA(A)) receptor agonists were unaffected by brilliant blue G. Immunoreactivity for the P2X(7) receptor was widely distributed surrounding ganglion cell bodies and associated with nerve fibers in both myenteric and submucous plexuses. P2X(7) immunoreactivity was colocalized with synapsin and synaptophysin and surrounded ganglion cells that contained either calbindin, calretinin, neuropeptide Y, substance P, or nitric oxide synthase. The mucosa, submucosal blood vessels, and the circular muscle coat also showed P2X(7) receptor immunoreactivity.
This study was carried out to determine the effect of 2-aminoethoxydiphenyl borate (2-APB), a common activator of transient receptor potential vanilloid (TRPV) type 1, 2, and 3 channels, on cardiorespiratory reflexes, pulmonary C fiber afferents, and isolated pulmonary capsaicin-sensitive neurons. In anesthetized, spontaneously breathing rats, intravenous bolus injection of 2-APB elicited the pulmonary chemoreflex responses, characterized by apnea, bradycardia, and hypotension. After perineural treatment of both cervical vagi with capsaicin to block the conduction of C fibers, 2-APB no longer evoked any of these reflex responses. In open-chest and artificially ventilated rats, 2-APB evoked an abrupt and intense discharge in vagal pulmonary C fibers in a dose-dependent manner. The stimulation of C fibers by 2-APB was attenuated but not abolished by capsazepine, a selective antagonist of the TRPV1, which completely blocked the response to capsaicin in these C fiber afferents. In isolated pulmonary capsaicinsensitive neurons, 2-APB concentration dependently evoked an inward current that was partially inhibited by capsazepine but almost completely abolished by ruthenium red, an effective blocker of all TRPV channels. In conclusion, 2-APB evokes a consistent and distinct stimulatory effect on pulmonary C fibers in vivo and on isolated pulmonary capsaicin-sensitive neurons in vitro. These results establish the functional evidence demonstrating that TRPV1, V2, and V3 channels are expressed on these sensory neurons and their terminals. pulmonary chemoreflex; vagal C fiber; pulmonary sensory neuron; transient receptor potential channels THE TRANSIENT RECEPTOR POTENTIAL (TRP) superfamily is a novel and rapidly expanding group of ion channel proteins. Mammalian homologs of the TRP channel gene encode a family of Ͼ20 related ion channels that are further divided into TRPC (canonical), TRPV (vanilloid), and TRPM (melastatin) subfamilies (12,32,33). These channels are widely distributed in a variety of mammalian organisms, tissues, and cell types and sense local changes in stimuli ranging from light, olfaction, temperature, pH, and osmolarity to mechanical, chemical, and metabolic stress (31, 43). Currently, the TRPV subfamily has six members. Like members in other TRP subfamilies, they are all cation channels; however, they vary substantially in their selectivity and mode of activation (32,33). Except temperature as the common stimulus of thermosensitive TRPV channels, namely TRPV1-4, most TRPV channels can be activated by nonthermal stimuli (11,16,20,40). For example, TRPV1 can be activated by capsaicin, protons, or endocannabinoids (8,10,21,22,27). TRPV4 can be activated by 4␣-phorbol 12,13-didecanoate and several arachidonic acid metabolites (11,35,44,45). 2-Aminoethoxydiphenyl borate (2-APB), which has been used extensively to investigate the effects of inositol 1,4,5-trisphosphate (IP 3 )-induced Ca 2ϩ release and Ca 2ϩ influx in a variety of cell types (15, 30, 46), was recently found to be a common and potent activato...
The canonical transient receptor potential (TRPC) family of ion channels is implicated in many neuronal processes including calcium homeostasis, membrane excitability, synaptic transmission and axon guidance. TRPC channels are postulated to be important in the functional neurobiology of the enteric nervous system (ENS); nevertheless, details for expression in the ENS are lacking. RT-PCR, Western blotting, and immunohistochemistry were used to study the expression and localization of TRPC channels. We found mRNA transcripts, protein on Western blots and immunoreactivity (IR) for TRPC1/3/4/6 expressed in the small intestinal ENS of adult guinea pigs. TRPC1/3/4/6-IR was localized to distinct subpopulations of enteric neurons and was differentially distributed between the myenteric and submucosal divisions of the ENS. TRPC1-IR was widely distributed and localized to neurons with cholinergic, calretinin, and nitrergic neuronal immunochemical codes in the myenteric plexus. It was localized to both cholinergic and non-cholinergic secretomotor neurons in the submucosal plexus. TRPC3-IR was found only in the submucosal plexus and was expressed exclusively by neuropeptide Y-IR neurons. TRPC4/6-IR was expressed in only a small population of myenteric neurons, but was abundantly expressed in the submucosal plexus. TRPC4/6-IR was coexpressed with both cholinergic and nitrergic neurochemical codes in the myenteric plexus. In the submucosal plexus, TRPC4/6-IR was expressed exclusively in non-cholinergic secretomotor neurons. No TRPC1/3/4/6-IR was found in calbindin-IR neurons. TRPC3/4/6-IR was widely expressed along varicose nerve fibers and colocalized with synaptophysin-IR at putative neurotransmitter release sites. Our results suggest important roles for TRPC channels in ENS physiology and neuronal regulation of gut function.
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