Abstract
The surveillance of acid-base homeostasis is concerted by diverse mechanisms, including an activation of sensory afferents. Proton-evoked activation of rodent sensory neurons is mainly mediated by the capsaicin receptor TRPV1 and acid-sensing ion channels. In this study, we demonstrate that extracellular acidosis activates and sensitizes the human irritant receptor TRPA1 (hTRPA1). Proton-evoked membrane currents and calcium influx through hTRPA1 occurred at physiological acidic pH values, were concentration-dependent, and were blocked by the selective TRPA1 antagonist HC030031. Both rodent and rhesus monkey TRPA1 failed to respond to extracellular acidosis, and protons even inhibited rodent TRPA1. Accordingly, mouse dorsal root ganglion neurons lacking TRPV1 only responded to protons when hTRPA1 was expressed heterologously. This species-specific activation of hTRPA1 by protons was reversed in both mouse and rhesus monkey TRPA1 by exchange of distinct residues within transmembrane domains 5 and 6. Furthermore, protons seem to interact with an extracellular interaction site to gate TRPA1 and not via a modification of intracellular N-terminal cysteines known as important interaction sites for electrophilic TRPA1 agonists. Our data suggest that hTRPA1 acts as a sensor for extracellular acidosis in human sensory neurons and should thus be taken into account as a yet unrecognized transduction molecule for proton-evoked pain and inflammation. The species specificity of this property is unique among known endogenous TRPA1 agonists, possibly indicating that evolutionary pressure enforced TRPA1 to inherit the role as an acid sensor in human sensory neurons.
Highlights
Extracellular acidosis mediates pain and inflammation by activating sensory afferent neurons
Because this effect might be due to an inhibition of open TRPA1 channels, we further explored this effect by applying pH 5.4 on inward currents induced by acrolein or carvacrol on either human irritant receptor TRPA1 (hTRPA1) or Mouse TRPA1 (mTRPA1)
When comparing the data obtained with patch clamp recordings as compared with those obtained with calcium imaging, the only relevant difference seems to be the finding that the majority of cells expressing hTRPA1 failed to evoked a detectable proton-evoked response in Ca2ϩ imaging experiments
Summary
Extracellular acidosis mediates pain and inflammation by activating sensory afferent neurons. Proton-evoked membrane currents and calcium influx through hTRPA1 occurred at physiological acidic pH values, were concentration-dependent, and were blocked by the selective TRPA1 antagonist HC030031 Both rodent and rhesus monkey TRPA1 failed to respond to extracellular acidosis, and protons even inhibited rodent TRPA1. Our data suggest that hTRPA1 acts as a sensor for extracellular acidosis in human sensory neurons and should be taken into account as a yet unrecognized transduction molecule for proton-evoked pain and inflammation. Protons interact with and modulate numerous membrane proteins within the peripheral and central nervous system and can act as excitatory or inhibitory cotransmitters regulating neuronal activity Both ischemia and inflammation are often accompanied by pain, and the activation and sensitization of peripheral sensory neurons in both of these conditions are largely evoked by protons [1, 2]. By employing patch clamp and ratiometric calcium imaging in combination with site-directed mutagenesis, we obtained data revealing the molecular basis for an unambiguous species specificity of proton-evoked activation of human TRPA1
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