Sustained currents through ASIC3 ion channels at the modest pH changes that occur during myocardial ischemia

Acid-sensing ion channel 3 (ASIC3) is highly expressed on sensory neurons that innervate heart and skeletal muscle and, therefore, is proposed to detect lactic acidosis and to transduce angina and muscle ischemic pain. A difficulty with this idea is that ASIC3 rapidly desensitizes. How can a desensitizing ion channel mediate a persisting sensation such as angina? Here, we show that rat ASIC3 produces a sustained current within the limited range of extracellular pH (7.3 to 6.7) that occurs during cardiac and skeletal muscle ischemia; experiments use patch clamp on transfected cell lines and on fluorescently tagged sensory neurons that innervate rat heart. No such sustained current occurs with ASIC1a (either as homomers or 1a/3 heteromers), whereas ASIC2a/3 heteromers give much larger currents than ASIC3 homomers. The sustained current persists even over tens of minutes because it is caused by a region of pH where there is overlap between inactivation and activation of the channel. Lactate, an anaerobic metabolite, allows the current to activate at slightly more basic pH. Surprisingly, amiloride, which blocks ASICs when they are activated at lower pH, increases ASIC3 current evoked at pH 7.0. Cardiac sensory neurons exhibit a small, perfectly sustained current when pH changes from 7.4 to 7.0. At least some of this current is carried by ASICs because the current is increased by both Zn(2+), an ASIC modulator, and amiloride. We suggest that this sustained mode is the most relevant form of ASIC3 gating for triggering angina and other ischemic pain.     

Acid-sensing ion channel 3 matches the acid-gated current in cardiac ischemia-sensing neurons

Cardiac afferents are sensory neurons that mediate angina, pain that occurs when the heart receives insufficient blood supply for its metabolic demand (ischemia). These neurons display enormous acid-evoked depolarizing currents, and they fire action potentials in response to extracellular acidification that accompanies myocardial ischemia. Here we show that acid-sensing ion channel 3 (ASIC3), but no other known acid-sensing ion channel, reproduces the functional features of the channel that underlies the large acid-evoked current in cardiac afferents. ASIC3 and the native channel are both especially sensitive to pH, interact similarly with Ca(2+), and gate rapidly between closed, open, and desensitized states. Particularly important is the ability of ASIC3 and the native channel to open at pH 7, a value reached in the first few minutes of a heart attack. The steep activation curve suggests that the channel opens when four protons bind. We propose that ASIC3, a member of the degenerin channel (of Caenorhabditis elegans)/epithelial sodium channel family of ion channels, is the sensor of myocardial acidity that triggers cardiac pain, and that it might be a useful pharmaceutical target for treating angina.     

Role of different proton-sensitive channels in releasing calcitonin gene-related peptide from isolated hearts of mutant mice

OBJECTIVE: Calcitonin gene-related peptide (CGRP), a potent vasodilator released from a subset of sensory Adelta- and C-fiber afferents, has been suggested to play a beneficial role in myocardial ischemia. The aim of the present study was to investigate some receptors possibly involved in the proton-mediated CGRP release from the heart. METHODS: CGRP release from freshly isolated hearts of mice lacking the capsaicin receptor (TRPV1-/-), the bradykinin receptor type 2 (B2-/-), or the acid-sensing ion channel type 3 (ASIC3-/-) and their wild-type littermates (TRPV1+/+, B2+/+, ASIC3+/+) were compared. Hearts were passed through a series of solutions based on oxygenated synthetic interstitial fluid (SIF). SIF buffered to pH 5.7 or 5.2 was used as an acidic test stimulus, and capsaicin (5x10(-7) M) was finally applied as a positive control. All eluates were processed using an enzyme immunoassay (EIA) for measurement of CGRP concentrations. RESULTS: SIF at pH 5.7 and 5.2 caused significant increases in CGRP release in TRPV1+/+ but not in mice lacking the TRPV1 receptor. The same acid stimuli caused no significant differences in CGRP release between ASIC3+/+ and ASIC3-/- or between B2+/+ and B2-/-, respectively. Capsaicin caused massive CGRP release in all mouse genotypes with the exception of TRPV1-/-. CONCLUSION: We conclude that cardiac acidosis is a strong stimulus to release CGRP from the mouse heart. This effect seems to be primarily mediated through activation of TRPV1 receptors that are known to be expressed by slowly conducting nociceptive primary afferent nerve fibers.     

Different contributions of ASIC channels 1a, 2, and 3 in gastrointestinal mechanosensory function

AIMS: Members of the acid sensing ion channel (ASIC) family are strong candidates as mechanical transducers in sensory function. The authors have shown that ASIC1a has no role in skin but a clear influence in gastrointestinal mechanotransduction. Here they investigate further ASIC1a in gut mechanoreceptors, and compare its influence with ASIC2 and ASIC3. METHODS AND RESULTS: Expression of ASIC1a, 2, and 3 mRNA was found in vagal (nodose) and dorsal root ganglia (DRG), and was lost in mice lacking the respective genes. Recordings of different classes of splanchnic colonic afferents and vagal gastro-oesophageal afferents revealed that disruption of ASIC1a increased the mechanical sensitivity of all afferents in both locations. Disruption of ASIC2 had varied effects: increased mechanosensitivity in gastro-oesophageal mucosal endings, decreases in gastro-oesophageal tension receptors, increases in colonic serosal endings, and no change in colonic mesenteric endings. In ASIC3-/- mice, all afferent classes had markedly reduced mechanosensitivity except gastro-oesophageal mucosal receptors. Observations of gastric emptying and faecal output confirmed that increases in mechanosensitivity translate to changes in digestive function in conscious animals. CONCLUSIONS: These data show that ASIC3 makes a critical positive contribution to mechanosensitivity in three out of four classes of visceral afferents. The presence of ASIC1a appears to provide an inhibitory contribution to the ion channel complex, whereas the role of ASIC2 differs widely across subclasses of afferents. These findings contrast sharply with the effects of ASIC1, 2, and 3 in skin, suggesting that targeting these subunits with pharmacological agents may have different and more pronounced effects on mechanosensitivity in the viscera.     

Heteromultimers of DEG/ENaC subunits form H+-gated channels in mouse sensory neurons

Acidic extracellular solution activates transient H(+)-gated currents in dorsal root ganglion (DRG) neurons. The biophysical properties of three degenerin/epithelial sodium (DEG/ENaC) channel subunits (BNC1, ASIC, and DRASIC), and their expression in DRG, suggest that they might underlie these H(+)-gated currents and function as sensory transducers. However, it is uncertain which of these DEG/ENaC subunits generate the currents, and whether they function as homomultimers or heteromultimers. We found that the biophysical properties of transient H(+)-gated currents from medium to large mouse DRG neurons differed from BNC1, ASIC, or DRASIC expressed individually, but were reproduced by coexpression of the subunits together. To test the contribution of each subunit, we studied DRG from three strains of mice, each bearing a targeted disruption of BNC1, ASIC, or DRASIC. Deletion of any one subunit did not abolish H(+)-gated currents, but altered currents in a manner consistent with heteromultimerization of the two remaining subunits. These data indicate that combinations of two or more DEG/ENaC subunits coassemble as heteromultimers to generate transient H(+)-gated currents in mouse DRG neurons.     

Acid‐Sensing Ion Channel 3 Deficiency Increases Inflammation but Decreases Pain Behavior in Murine Arthritis

Objective

Through its location on nociceptors, acid‐sensing ion channel 3 (ASIC‐3) is activated by decreases in pH and plays a significant role in musculoskeletal pain. We recently showed that decreases in pH activate ASIC‐3 located on fibroblast‐like synoviocytes (FLS), which are key cells in the inflammatory process. The purpose of this study was to test whether ASIC‐3–deficient mice with arthritis have altered inflammation and pain relative to controls.

Methods

Collagen antibody–induced arthritis (CAIA) was generated by injection of an anti–type II collagen antibody cocktail. Inflammation and pain parameters in ASIC‐3^−/− and ASIC‐3^+/+ mice were assessed. Disease severity was assessed by determining clinical arthritis scores, measuring joint diameters, analyzing joint histology, and assessing synovial gene expression by quantitative polymerase chain reaction analysis. Cell death was assessed with a Live/Dead assay of FLS in response to decreases in pH. Pain behaviors in the mice were measured by examining withdrawal thresholds in the joints and paws and by measuring their physical activity levels.

Results

Surprisingly, ASIC‐3^−/− mice with CAIA demonstrated significantly increased joint inflammation, joint destruction, and expression of interleukin‐6 (IL‐6), matrix metalloproteinase 3 (MMP‐3), and MMP‐13 in joint tissue as compared to ASIC‐3^+/+ mice. ASIC‐3^+/+ FLS showed enhanced cell death when exposed to pH 6.0 in the presence of IL‐1β, which was abolished in ASIC‐3^−/− FLS. Despite enhanced disease severity, ASIC‐3^−/− mice did not develop mechanical hypersensitivity of the paw and showed greater levels of physical activity.

Conclusion

Our findings are consistent with the hypothesis that ASIC‐3 plays a protective role in the inflammatory arthritides by limiting inflammation through enhanced synoviocyte cell death, which reduces disease severity, and through the production of pain, which reduces joint use.

     

Ion channels gated by heat

All animals need to sense temperature to avoid hostile environments and to regulate their internal homeostasis. A particularly obvious example is that animals need to avoid damagingly hot stimuli. The mechanisms by which temperature is sensed have until recently been mysterious, but in the last couple of years, we have begun to understand how noxious thermal stimuli are detected by sensory neurons. Heat has been found to open a nonselective cation channel in primary sensory neurons, probably by a direct action. In a separate study, an ion channel gated by capsaicin, the active ingredient of chili peppers, was cloned from sensory neurons. This channel (vanilloid receptor subtype 1, VR1) is gated by heat in a manner similar to the native heat-activated channel, and our current best guess is that this channel is the molecular substrate for the detection of painful heat. Both the heat channel and VR1 are modulated in interesting ways. The response of the heat channel is potentiated by phosphorylation by protein kinase C, whereas VR1 is potentiated by externally applied protons. Protein kinase C is known to be activated by a variety of inflammatory mediators, including bradykinin, whereas extracellular acidification is characteristically produced by anoxia and inflammation. Both modulatory pathways are likely, therefore, to have important physiological correlates in terms of the enhanced pain (hyperalgesia) produced by tissue damage and inflammation. Future work should focus on establishing, in molecular terms, how a single ion channel can detect heat and how the detection threshold can be modulated by hyperalgesic stimuli.     

A sensory subpopulation depends on vesicular glutamate transporter 2 for mechanical pain, and together with substance P, inflammatory pain

Ablating or functionally compromising sets of sensory neurons has provided important insights into peripheral modality-specific wiring in the somatosensory system. Inflammatory hyperalgesia, cold pain, and noxious mechanosensation have all been shown to depend upon Na(v)1.8-positive sensory neurons. The release of fast-acting neurotransmitters, such as glutamate, and more slowly released neuropeptides, such as substance P (SP), contribute to the diversified responses to external stimuli. Here we show that deleting Vglut2 in Na(v)1.8(Cre)-positive neurons compromised mechanical pain and NGF-induced thermal hyperalgesia, whereas tactile-evoked sensation, thermal, formalin-evoked, and chronic neuropathic pain were normal. However, when Vglut2(f/f);Na(v)1.8(Cre) mice were injected with a SP antagonist before the formalin test, the second phase pain response was nearly completely abolished, whereas in control mice, the pain response was unaffected. Our results suggest that VGLUT2-dependent signaling originating from Na(v)1.8-positive neurons is a principal sensing mechanism for mechanical pain and, together with SP, inflammatory pain. These data define sets of primary afferents associated with specific modalities and provide useful genetic tools with which to analyze the pathways that are activated by functionally distinct neuronal populations and transmitters.     

Functional implications of the localization and activity of acid-sensitive channels in rat peripheral nervous system

Acid-sensitive ion channels (ASIC) are proton-gated ion channels expressed in neurons of the mammalian central and peripheral nervous systems. The functional role of these channels is still uncertain, but they have been proposed to constitute mechanoreceptors and/or nociceptors. We have raised specific antibodies for ASIC1, ASIC2, ASIC3, and ASIC4 to examine the distribution of these proteins in neurons from dorsal root ganglia (DRG) and to determine their subcellular localization. Western blot analysis demonstrates that all four ASIC proteins are expressed in DRG and sciatic nerve. Immunohistochemical experiments and functional measurements of unitary currents from the ASICs with the patch-clamp technique indicate that ASIC1 localizes to the plasma membrane of small-, medium-, and large-diameter cells, whereas ASIC2 and ASIC3 are preferentially in medium to large cells. Neurons coexpressing ASIC2 and ASIC3 form predominantly heteromeric ASIC2-3 channels. Two spliced forms, ASIC2a and ASIC2b, colocalize in the same population of DRG neurons. Within cells, the ASICs are present mainly on the plasma membrane of the soma and cellular processes. Functional studies indicate that the pH sensitivity for inactivation of ASIC1 is much higher than the one for activation; hence, increases in proton concentration will inactivate the channel. These functional properties and localization in DRG have profound implications for the putative functional roles of ASICs in the nervous system.     

Extracellular acidosis increases neuronal cell calcium by activating acid-sensing ion channel 1a

Acid-sensing ion channel (ASIC) 1a subunit is expressed in synapses of central neurons where it contributes to synaptic plasticity. However, whether these channels can conduct Ca(2+) and thereby raise the cytosolic Ca(2+) concentration, [Ca(2+)](c), and possibly alter neuronal physiology has been uncertain. We found that extracellular acidosis opened ASIC1a channels, which provided a pathway for Ca(2+) entry and elevated [Ca(2+)](c) in wild-type, but not ASIC1(-/-), hippocampal neurons. Acid application also raised [Ca(2+)](c) and evoked Ca(2+) currents in heterologous cells expressing ASIC1a. Although ASIC2a is also expressed in central neurons, neither ASIC2a homomultimeric channels nor ASIC1a/2a heteromultimers showed H(+)-activated [Ca(2+)](c) elevation or Ca(2+) currents. Because extracellular acidosis accompanying cerebral ischemia contributes to neuronal injury, we tested the effect of acidosis on cell death measured as lactate dehydrogenase release. Eliminating ASIC1a from neurons or treating ASIC1a-expressing cells with the ASIC blocker amiloride attenuated acidosis-induced cell injury. These results indicate that ASIC1a provides a non-voltage-gated pathway for Ca(2+) to enter neurons. Thus, it may provide a target for modulation of [Ca(2+)](c).     

Acid-sensing ion channels interact with and inhibit BK K+ channels

Acid-sensing ion channels (ASICs) are neuronal non-voltage-gated cation channels that are activated when extracellular pH falls. They contribute to sensory function and nociception in the peripheral nervous system, and in the brain they contribute to synaptic plasticity and fear responses. Some of the physiologic consequences of disrupting ASIC genes in mice suggested that ASIC channels might modulate neuronal function by mechanisms in addition to their H(+)-evoked opening. Within ASIC channel's large extracellular domain, we identified sequence resembling that in scorpion toxins that inhibit K(+) channels. Therefore, we tested the hypothesis that ASIC channels might inhibit K(+) channel function by coexpressing ASIC1a and the high-conductance Ca(2+)- and voltage-activated K(+) (BK) channel. We found that ASIC1a associated with BK channels and inhibited their current. Reducing extracellular pH disrupted the association and relieved the inhibition. BK channels, in turn, altered the kinetics of ASIC1a current. In addition to BK, ASIC1a inhibited voltage-gated Kv1.3 channels. Other ASIC channels also inhibited BK, although acidosis-dependent relief of inhibition varied. These results reveal a mechanism of ion channel interaction and reciprocal regulation. Finding that a reduced pH activated ASIC1a and relieved BK inhibition suggests that extracellular protons may enhance the activity of channels with opposing effects on membrane voltage. The wide and varied expression patterns of ASICs, BK, and related K(+) channels suggest broad opportunities for this signaling system to alter neuronal function.     

Overexpression of acid-sensing ion channel 1a in transgenic mice increases acquired fear-related behavior

The acid-sensing ion channel 1a (ASIC1a) is abundantly expressed in the amygdala complex and other brain regions associated with fear. Studies of mice with a disrupted ASIC1 gene suggested that ASIC1a may contribute to learned fear. To test this hypothesis, we generated mice overexpressing human ASIC1a by using the pan-neuronal synapsin 1 promoter. Transgenic ASIC1a interacted with endogenous mouse ASIC1a and was distributed to the synaptosomal fraction of brain. Transgenic expression of ASIC1a also doubled neuronal acid-evoked cation currents. The amygdala showed prominent expression, and overexpressing ASIC1a enhanced fear conditioning, an animal model of acquired anxiety. These data raise the possibility that ASIC1a and H(+)-gated currents may contribute to the development of abnormal fear and to anxiety disorders in humans.     

Increased acid-sensing ion channel ASIC-3 in inflamed human intestine

OBJECTIVES: Acid-sensing ion channels (ASICs) are expressed by rat sensory neurons and may mediate pain associated with tissue acidosis after inflammation or injury. Our aim was to examine the molecular forms and localization of ASICs in human intestine and dorsal root ganglia using immunochemical techniques, and to measure the effects of inflammation and injury. DESIGN AND METHODS: Inflamed Crohn's disease intestine and injured human dorsal root ganglia, with appropriate controls, were studied by Western blotting and immunohistochemistry, using specific affinity-purified ASIC antibodies. RESULTS: In the Western blot, there was a significant three-fold increase in the mean relative optical density of the ASIC-3 55-kDa band (but not ASIC-1 or ASIC-2) in full-thickness inflamed intestine, as well as in separated muscle and mucosal layers. There was a corresponding trend for an increased immunoreactive density and increased number of ASIC-3-positive neurons in the myenteric and sub-mucous plexus of inflamed intestine. In dorsal root ganglia, immunoreactivity for all ASICs was restricted to a sub-population (about 50%) of small-diameter (nociceptor) sensory neurons, and was generally less intense after injury. CONCLUSIONS: Increased ASIC-3 in inflamed intestine suggests a role in pain or dysmotility, for which ASICs represent new therapeutic targets.     

VGLUT2 expression in primary afferent neurons is essential for normal acute pain and injury-induced heat hypersensitivity

Dorsal root ganglia (DRG) neurons, including the nociceptors that detect painful thermal, mechanical, and chemical stimuli, transmit information to spinal cord neurons via glutamatergic and peptidergic neurotransmitters. However, the specific contribution of glutamate to pain generated by distinct sensory modalities or injuries is not known. Here we generated mice in which the vesicular glutamate transporter 2 (VGLUT2) is ablated selectively from DRG neurons. We report that conditional knockout (cKO) of the Slc17a6 gene encoding VGLUT2 from the great majority of nociceptors profoundly decreased VGLUT2 mRNA and protein in these neurons, and reduced firing of lamina I spinal cord neurons in response to noxious heat and mechanical stimulation. In behavioral assays, cKO mice showed decreased responsiveness to acute noxious heat, mechanical, and chemical (capsaicin) stimuli, but responded normally to cold stimulation and in the formalin test. Strikingly, although tissue injury-induced heat hyperalgesia was lost in the cKO mice, mechanical hypersensitivity developed normally. In a model of nerve injury-induced neuropathic pain, the magnitude of heat hypersensitivity was diminished in cKO mice, but both the mechanical allodynia and the microgliosis generated by nerve injury were intact. These findings suggest that VGLUT2 expression in nociceptors is essential for normal perception of acute pain and heat hyperalgesia, and that heat and mechanical hypersensitivity induced by peripheral injury rely on distinct (VGLUT2 dependent and VGLUT2 independent, respectively) primary afferent mechanisms and pathways.     

Genetic variation in the ASIC3 gene influences blood pressure levels in Taiwanese

BACKGROUND: The acid-sensing ion channel 3 (ASIC3) is a ligand-gated cation channel activated by extracellular protons, and is associated with an exercise-induced pressor reflex and possibly autonomic imbalance. METHODS: To test the statistical association between genetic polymorphisms of the ASIC3 gene and blood pressure (BP) variations in Taiwanese, 551 unrelated individuals (286 men and 265 women) were recruited from a routine health examination. The participants had no prior history of cardiovascular disease or medication use for hypertension. RESULTS: Six ASIC3 gene polymorphisms were genotyped; three were polymorphic, and only the rs2288646 polymorphism was associated with variations in BP among participants. Significantly higher systolic, diastolic, and mean BP were observed in participants carrying the rs2288646-A allele (P=0.034, 0.023, and 0.010, respectively). Significantly higher frequencies of the rs2288646-A-containing genotype were observed in normotensive, prehypertensive, and hypertensive subgroups (P for trend=0.026); and in those with higher systolic and diastolic BPs (P for trend=0.005 and P for trend=0.002, respectively). The association between the rs2288646-A allele and BP persisted even after adjustment for age, sex, BMI, and other metabolic factors. When a second independent group of 403 individuals was combined with the first group of 551 (n=954), a significantly higher frequency of the rs2288646-A-containing genotype was observed in participants with hypertension (9.7 vs. 4.0%, P=0.003). CONCLUSION: Our data showed an independent association between an ASIC3 genetic polymorphism and BP variations in Taiwanese. These results suggest that the ASIC3 may be involved in BP regulation.     

A single sodium channel mutation produces hyper- or hypoexcitability in different types of neurons

Disease-producing mutations of ion channels are usually characterized as producing hyperexcitability or hypoexcitability. We show here that a single mutation can produce hyperexcitability in one neuronal cell type and hypoexcitability in another neuronal cell type. We studied the functional effects of a mutation of sodium channel Nav1.7 associated with a neuropathic pain syndrome, erythermalgia, within sensory and sympathetic ganglion neurons, two cell types where Nav1.7 is normally expressed. Although this mutation depolarizes resting membrane potential in both types of neurons, it renders sensory neurons hyperexcitable and sympathetic neurons hypoexcitable. The selective presence, in sensory but not sympathetic neurons, of the Nav1.8 channel, which remains available for activation at depolarized membrane potentials, is a major determinant of these opposing effects. These results provide a molecular basis for the sympathetic dysfunction that has been observed in erythermalgia. Moreover, these findings show that a single ion channel mutation can produce opposing phenotypes (hyperexcitability or hypoexcitability) in the different cell types in which the channel is expressed.     

Mammalian TRPV4 (VR-OAC) directs behavioral responses to osmotic and mechanical stimuli in Caenorhabditis elegans

All animals detect osmotic and mechanical stimuli, but the molecular basis for these responses is incompletely understood. The vertebrate transient receptor potential channel vanilloid subfamily 4 (TRPV4) (VR-OAC) cation channel has been suggested to be an osmo/mechanosensory channel. To assess its function in vivo, we expressed TRPV4 in Caenorhabditis elegans sensory neurons and examined its ability to generate behavioral responses to sensory stimuli. C. elegans ASH neurons function as polymodal sensory neurons that generate a characteristic escape behavior in response to mechanical, osmotic, or olfactory stimuli. These behaviors require the TRPV channel OSM-9 because osm-9 mutants do not avoid nose touch, high osmolarity, or noxious odors. Expression of mammalian TRPV4 in ASH neurons of osm-9 worms restored avoidance responses to hypertonicity and nose touch, but not the response to odorant repellents. Mutations known to reduce TRPV4 channel activity also reduced its ability to direct nematode avoidance behavior. TRPV4 function in ASH required the endogenous C. elegans osmotic and nose touch avoidance genes ocr-2, odr-3, osm-10, and glr-1, indicating that TRPV4 is integrated into the normal ASH sensory apparatus. The osmotic and mechanical avoidance responses of TRPV4-expressing animals were different in their sensitivity and temperature dependence from the responses of wild-type animals, suggesting that the TRPV4 channel confers its characteristic properties on the transgenic animals' behavior. These results provide evidence that TRPV4 can function as a component of an osmotic/mechanical sensor in vivo.     

酸敏感离子通道3在胃食管反流大鼠中的表达和意义

目的检测酸敏感离子通道3(ASIC3)在胃食管反流大鼠食管黏膜及背根神经节(DRG)中的表达变化,探讨其在胃食管反流病(GERD)发病中的作用。方法将Sprague-Dawley雄性大鼠随机分为实验组(G组)和对照组(S组)。实验组采用限制幽门及结扎胃底方法建立GERD大鼠模型。于造模后15 d处死两组大鼠,通过HE染色对大鼠食管黏膜进行组织病理学检测,通过蛋白质印迹法(Western blotting)和实时定量聚合酶链反应(RT-PCR)检测大鼠食管黏膜及DRG中ASIC3蛋白及mRNA表达变化。结果HE染色显示G组大鼠食管黏膜慢性炎症改变,S组大鼠食管黏膜无异常;Western blotting显示G组大鼠DRG中ASIC3蛋白表达高于S组(6.75±0.74 vs 5.07±0.72)(P0.05),食管黏膜中ASIC3蛋白表达高于S组(8.04±0.67 vs 7.31±0.740)(P0.05);RT-PCR同样显示,G组大鼠DRG中ASIC3 mRNA表达高于S组(0.00030±0.00003 vs 0.00013±0.00002)(P0.05),食管黏膜中ASIC3 mRNA表达高于S组(0.01073±0.00231 vs 0.00088±0.0007)(P0.05)。结论 ASIC3在DRG及食管黏膜上表达上调可能是导致GERD食管内脏高敏感的原因之一。