pH Receptors: Peptides and Nociception

Acid-sensing ion channels (ASIC) are involved in a variety of sensory functions, including mechanoreception, nociception, and perception of acid taste, thus being considerably involved in the control of smooth musculature. It is suggested that FMRFa-related peptides can be endogenous regulators of these channels, primarily by modulating the rate of ASIC desensitization. Here we present two our findings. (I) The effect is strongly pH-dependent: The lower the pH used to activate ASIC, the greater the modulatory effect of RFa-related peptides, and (ii) in the small (nociceptive), but not in the large (mechanoceptive) primary somatosensory neurons, RFa-related peptides shift steady-state desensitization toward more acidic levels. We suggest that the pH dependence of the modulatory action of RFa-related peptides can be associated with the presence of positively charged arginine residues and their possible interactions with histidine residues in ASIC. The second effect should result in strongly increased phasic activity of nociceptors under conditions of moderate ischemia. Our results show that the RFa-related peptides are capable of changing the sensitivity of nociceptors to protons, as well as the temporal pattern of their activity. Short neuropeptides are usually the products of proteolysis of larger prohormone molecules. Interestingly, chronic pain is accompanied by a significant activation of proteases in dorsal root ganglion neurons, and RFa peptides have been found in the spinal dorsal horn of mammals. They may play a role in the modulation of the mammalian sensory inputs.     

The effect of neighboring amino acid residues and solution environment on the oxidative stability of tyrosine in small peptides

The effects of neighboring residues and formulation variables on tyrosine oxidation were investigated in model dipeptides (glysyl tyrosine, N-acetyl tyrosine, glutamyl tyrosine, and tyrosyl arginine) and tripeptide (lysyl tyrosyl lysine). The tyrosyl peptides were oxidized by light under alkaline conditions by a zero-order reaction. The rate of the photoreaction was dependent on tyrosyl pK(a), which was perturbed by the presence of neighboring charged amino acid residues. The strength of light exposure, oxygen headspace, and the presence of cationic surfactant, cetyltrimethylammonia chloride had a significant effect on the kinetics of tyrosyl photo-oxidation. Tyrosine and model tyrosyl peptides were also oxidized by hydrogen peroxide/metal ions at neutral pH. Metal-catalyzed oxidation followed first-order kinetics. Adjacent negatively charged amino acids accelerated tyrosine oxidation owing to affinity of the negative charges to metal-ions, whereas positively charged amino acid residues disfavored the reaction. The oxidation of tyrosine in peptides was greatly affected by the presence of adjacent charged residues, and the extent of the effect depended on the solution environment.     

Modulation of HERG gating by a charge cluster in the N-terminal proximal domain

Human ether-a-go-go-related gene (HERG) potassium channels contribute to the repolarization of the cardiac action potential and display unique gating properties with slow activation and fast inactivation kinetics. Deletions in the N-terminal 'proximal' domain (residues 135-366) have been shown to induce hyperpolarizing shifts in the voltage dependence of activation, suggesting that it modulates activation. However, we did not observe a hyperpolarizing shift with a subtotal deletion designed to preserve the local charge distribution, and other deletions narrowed the region to the KIKER containing sequence 362-372. Replacing the positively charged residues of this sequence by negative ones (EIEEE) resulted in a -45 mV shift of the voltage dependence of activation. The shifts were intermediate for individual charge reversals, whereas E365R resulted in a positive shift. Furthermore, the shifts in the voltage dependence were strongly correlated with the net charge of the KIKER region. The apparent speeding of the activation was attributable to the shifted voltage dependence of activation. Additionally, the introduction of negative charges accelerated the intermediate voltage-independent forward rate constant. We propose that the modulatory effects of the proximal domain on HERG gating are largely electrostatic, localized to the charged KIKER sequence.     

Protonation controls ASIC1a activity via coordinated movements in multiple domains

Acid-sensing ion channels (ASICs) are neuronal Na⁺-conducting channels activated by extracellular acidification. ASICs are involved in pain sensation, expression of fear, and neurodegeneration after ischemic stroke. Functional ASICs are composed of three identical or homologous subunits, whose extracellular part has a handlike structure. Currently, it is unclear how protonation of residues in extracellular domains controls ASIC activity. Knowledge of these mechanisms would allow a rational development of drugs acting on ASICs. Protonation may induce conformational changes that control the position of the channel gate. We used voltage-clamp fluorometry with fluorophores attached to residues in different domains of ASIC1a to detect conformational changes. Comparison of the timing of fluorescence and current signals identified residues involved in movements that preceded desensitization and may therefore be associated with channel opening or early steps leading to desensitization. Other residues participated in movements intimately linked to desensitization and recovery from desensitization. Fluorescence signals of all mutants were detected at more alkaline pH than ionic currents. Their midpoint of pH dependence was close to that of steady-state desensitization, whereas the steepness of the pH fluorescence relationship was closer to that of current activation. A sequence of movements was observed upon acidification, and its backward movements during recovery from desensitization occurred in the reverse order, indicating that the individual steps are interdependent. Furthermore, the fluorescence signal of some labeled residues in the finger domain was strongly quenched by a Trp residue in the neighboring β-ball domain. Upon channel activation, their fluorescence intensity increased, indicating that the finger moved away from the β ball. This extensive analysis of activity-dependent conformational changes in ASICs sheds new light on the mechanisms by which protonation controls ASIC activity.     

Characterization of acid signaling in rat vagal pulmonary sensory neurons

Local tissue acidosis frequently occurs in airway inflammatory and ischemic conditions. The effect of physiological/pathophysiological-relevant low pH (7.0-5.5) on isolated rat vagal pulmonary sensory neurons was investigated using whole cell perforated patch-clamp recordings. In voltage-clamp recordings, vagal pulmonary sensory neurons exhibited distinct pH sensitivities and different phenotypes of inward current in responding to acidic challenge. The current evoked by lowering the pH of extracellular solution to 7.0 consisted of only a transient, rapidly inactivating component with small amplitude. The amplitude of this transient current increased when the proton concentration was elevated. In addition, a slow, sustained inward current began to emerge when pH was reduced to <6.5. The current-voltage curve indicated that the transient component of acid-evoked current was carried predominantly by Na+. This transient component was dose-dependently inhibited by amiloride, a common blocker of acid-sensing ion channels (ASICs), whereas the sustained component was significantly attenuated by capsazepine, a selective antagonist of transient receptor potential vanilloid receptor subtype-1 (TRPV1). The two components of acid-evoked current also displayed distinct recovery kinetics from desensitization. Furthermore, in current-clamp recordings, transient extracellular acidification depolarized the membrane potential and generated action potentials in these isolated neurons. In summary, our results have demonstrated that low pH can stimulate rat vagal pulmonary sensory neurons through the activation of both ASICs and TRPV1. The relative roles of these two current species depend on the range of pH and vary between neurons.     

Endogenous arginine-phenylalanine-amide-related peptides alter steady-state desensitization of ASIC1a

The acid-sensing ion channels (ASICs) are proton-gated, voltage-insensitive cation channels expressed throughout the nervous system. ASIC1a plays a role in learning, pain, and fear-related behaviors. In addition, activation of ASIC1a during prolonged acidosis following cerebral ischemia induces neuronal death. ASICs undergo steady-state desensitization, a characteristic that limits ASIC1a activity and may play a prominent role in the prevention of ASIC1a-evoked neuronal death. In this study, we found exogenous and endogenous arginine-phenylalanine-amide (RF-amide)-related peptides decreased the pH sensitivity of ASIC1a steady-state desensitization. During conditions that normally induced steady-state desensitization, these peptides profoundly enhanced ASIC1a activity. We also determined that human ASIC1a required more acidic pH to undergo steady-state desensitization compared with mouse ASIC1a. Surprisingly, steady-state desensitization of human ASIC1a was also affected by a greater number of peptides compared with mouse ASIC1a. Mutation of five amino acids in a region of the extracellular domain changed the characteristics of human ASIC1a to those of mouse ASIC1a, suggesting that this region plays a pivotal role in neuropeptide and pH sensitivity of steady-state desensitization. Overall, these experiments lend vital insight into steady-state desensitization of ASIC1a and expand our understanding of the structural determinants of RF-amide-related peptide modulation. Furthermore, our finding that endogenous peptides shift steady-state desensitization suggests that RF-amides could impact the role of ASIC1a in both pain and neuronal damage following stroke and ischemia.     

Trypsin cleaves acid-sensing ion channel 1a in a domain that is critical for channel gating

Acid-sensing ion channels (ASICs) are neuronal Na(+) channels that are members of the epithelial Na(+) channel/degenerin family and are transiently activated by extracellular acidification. ASICs in the central nervous system have a modulatory role in synaptic transmission and are involved in cell injury induced by acidosis. We have recently demonstrated that ASIC function is regulated by serine proteases. We provide here evidence that this regulation of ASIC function is tightly linked to channel cleavage. Trypsin cleaves ASIC1a with a similar time course as it changes ASIC1a function, whereas ASIC1b, whose function is not modified by trypsin, is not cleaved. Trypsin cleaves ASIC1a at Arg-145, in the N-terminal part of the extracellular loop, between a highly conserved sequence and a sequence that is critical for ASIC1a inhibition by the venom of the tarantula Psalmopoeus cambridgei. This channel domain controls the inactivation kinetics and co-determines the pH dependence of ASIC gating. It undergoes a conformational change during inactivation, which renders the cleavage site inaccessible to trypsin in inactivated channels.     

Histidine(118) in the S2-S3 linker specifically controls activation of the KAT1 channel expressed in Xenopus oocytes

The guard cell K(+) channel KAT1, cloned from Arabidopsis thaliana, is activated by hyperpolarization and regulated by a variety of physiological factors. Low internal pH accelerated the activation kinetics of the KAT1 channel expressed in Xenopus oocytes with a pK of approximately 6, similar to guard cells in vivo. Mutations of histidine-118 located in the putative cytoplasmic linker between the S2 and S3 segments profoundly affected the gating behavior and pH dependence. At pH 7.2, substitution with a negatively charged amino acid (glutamate, aspartate) specifically slowed the activation time course, whereas that with a positively charged amino acid (lysine, arginine) accelerated. These mutations did not alter the channel's deactivation time course or the gating behavior after the first opening. Introducing an uncharged amino acid (alanine, asparagine) at position 118 did not have any obvious effect on the activation kinetics at pH 7.2. The charged substitutions markedly decreased the sensitivity of the KAT1 channel to internal pH in the physiological range. We propose a linear kinetic scheme to account for the KAT1 activation time course at the voltages where the opening transitions dominate. Changes in one forward rate constant in the model adequately account for the effects of the mutations at position 118 in the S2-S3 linker segment. These results provide a molecular and biophysical basis for the diversity in the activation kinetics of inward rectifiers among different plant species.     

Responses Evoked in Afferent Fibers by Mechanostimulation of the Skin <Emphasis Type="Italic">in vitro</Emphasis>: Modulation by RFa-Like Peptides

In experiments in vitro on a skin patch-n. saphenous preparation, we studied the effects of RFa-like peptides on the responses of single slow-and fast-conducting afferent fibers evoked by mechanostimulation of the skin. RFa-like peptides were shown to exert modulatory influences on the mechanostimulation-evoked activity in a significant proportion of such units; a considerable proportion of the effects in the fibers of different types were of opposite direction. In most nociceptive thin C fibers, responses evoked by mechanostimulation of the skin were facilitated by the peptides, while those in A fibers were suppressed. It is supposed that RFa-like peptides are involved in the formation of the hyperalgesia state. The effect of these peptides on proton-activated ion channels (ASICs) is one of the possible mechanisms of an increase in the sensitivity of afferent fibers to mechanical stimuli. This modulatory effect was observed both in an acidified (pH 5.2) and in a normal (pH 7.4) media; this is why another mechanism exists that is not related to ASICs. A suppressory effect of RFa peptides on the mechanostimulation-evoked activity of primary afferents developed with a significant delay; probably, it is mediated by the effects of peptides on G proteins. Neirofiziologiya/Neurophysiology, Vol. 37, No. 2, pp. 134–141, March–April, 2005.     

An arginine residue in the outer segment of hASIC1a TM1 affects both proton affinity and channel desensitization

Acid-sensing ion channels (ASICs) respond to changes in pH in the central and peripheral nervous systems and participate in synaptic plasticity and pain perception. Understanding the proton-mediated gating mechanism remains elusive despite the of their structures in various conformational states. We report here that R64, an arginine located in the outer segment of the first transmembrane domain of all three isoforms of mammalian ASICs, markedly impacts the apparent proton affinity of activation and the degree of desensitization from the open and preopen states. Rosetta calculations of free energy changes predict that substitutions of R64 in hASIC1a by aromatic residues destabilize the closed conformation while stabilizing the open conformation. Accordingly, F64 enhances the efficacy of proton-mediated gating of hASIC1a, which increases the apparent pH₅₀ and facilitates channel opening when only one or two subunits are activated. F64 also lengthens the duration of opening events, thus keeping channels open for extended periods of time and diminishing low pH-induced desensitization. Our results indicate that activation of a proton sensor(s) with pH₅₀ equal to or greater than pH 7.2–7.1 opens F64hASIC1a, whereas it induces steady-state desensitization in wildtype channels due to the high energy of activation imposed by R64, which prevents opening of the pore. Together, these findings suggest that activation of a high-affinity proton-sensor(s) and a common gating mechanism may mediate the processes of activation and steady-state desensitization of hASIC1a.     

Mechanisms of non-steroid anti-inflammatory drugs action on ASICs expressed in hippocampal interneurons

The inhibitory action of non-steroid anti-inflammatory drugs was investigated on acid-sensing ionic channels (ASIC) in isolated hippocampal interneurons and on recombinant ASICs expressed in Chinese hamster ovary (CHO) cells. Diclofenac and ibuprofen inhibited proton-induced currents in hippocampal interneurons (IC₅₀ were 622 ± 34 μM and 3.42 ± 0.50 mM, respectively). This non-competitive effect was fast and fully reversible for both drugs. Aspirin and salicylic acid at 500 μM were ineffective. Diclofenac and ibuprofen decreased the amplitude of proton-evoked currents and slowed the rates of current decay with a good correlation between these effects. Simultaneous application of acid solution and diclofenac was required for its inhibitory effect. Unlike amiloride, the action of diclofenac was voltage-independent and no competition between two drugs was found. Analysis of the action of diclofenac and ibuprofen on activation and desensitization of ASICs showed that diclofenac but not ibuprofen shifted the steady-state desensitization curve to more alkaline pH values. The reason for this shift was slowing down the recovery from desensitization of ASICs. Thus, diclofenac may serve as a neuroprotective agent during pathological conditions associated with acidification.     

Effect of lysine side chain length on intra-helical glutamate--lysine ion pairing interactions

Ion-pairing interactions are important for protein stabilization. Despite the apparent electrostatic nature of these interactions, natural positively charged amino acids Lys and Arg have multiple methylenes linking the charged functionality to the backbone. Interestingly, the amino acids Lys and Orn have positively charged side chains that differ by only one methylene. However, only Lys is encoded and incorporated into proteins. To investigate the effect of side chain length of Lys on ion-pairing interactions, a series of 12 monomeric alpha-helical peptides containing potential Glu-Xaa (i, i+3), (i, i+4) and (i, i+5) (Xaa = Lys, Orn, Dab, Dap) interactions were studied by circular dichroism (CD) spectroscopy at pH 7 and 2. At pH 7, no Glu-Xaa (i, i+5) interaction was observed, regardless of the Xaa side chain length. Furthermore, only Lys was capable of supporting Glu-Xaa (i, i+3) interactions, whereas any Xaa side chain length supported Glu-Xaa (i, i+4) interactions. Side chain conformational analysis by molecular mechanics calculations showed that the side chain length of Lys enables the Glu-Xaa (i, i+3) interaction with lower energy conformations compared to residues with side chain lengths shorter than that of Lys. Furthermore, these calculated low energy conformers were consistent with conformations of intra-helical Glu-Lys salt bridges in a non-redundant protein structure database. Importantly, the CD spectra for peptides with Glu-Lys interactions did not alter significantly upon changing the pH because of a greater contribution to these interactions by forces other than electrostatics. Incorporating side chains just one methylene shorter (Orn) resulted in significant pH dependence or lack of interaction, suggesting that nature has chosen Lys to form durable interactions with negatively charged functional groups.     

PAP and NT5E inhibit nociceptive neurotransmission by rapidly hydrolyzing nucleotides to adenosine

Background

Acid-sensing ion channels (ASICs) have a significant role in the sensation of pain and constitute an important target for the search of new antinociceptive drugs. In this work we studied the antinociceptive properties of the BM-21 extract, obtained from the sea grass Thalassia testudinum, in chemical and thermal models of nociception in mice. The action of the BM-21 extract and the major phenolic component isolated from this extract, a sulphated flavone glycoside named thalassiolin B, was studied in the chemical nociception test and in the ASIC currents of the dorsal root ganglion (DRG) neurons obtained from Wistar rats.

Results

Behavioral antinociceptive experiments were made on male OF-1 mice. Single oral administration of BM-21 produced a significant inhibition of chemical nociception caused by acetic acid and formalin (specifically during its second phase), and increased the reaction time in the hot plate test. Thalassiolin B reduced the licking behavior during both the phasic and tonic phases in the formalin test. It was also found that BM-21 and thalassiolin B selectively inhibited the fast desensitizing (τ < 400 ms) ASIC currents in DRG neurons obtained from Wistar rats, with a nonsignificant action on ASIC currents with a slow desensitizing time-course. The action of thalassiolin B shows no pH or voltage dependence nor is it modified by steady-state ASIC desensitization or voltage. The high concentration of thalassiolin B in the extract may account for the antinociceptive action of BM-21.

Conclusions

To our knowledge, this is the first report of an ASIC-current inhibitor derived of a marine-plant extract, and in a phenolic compound. The antinociceptive effects of BM-21 and thalassiolin B may be partially because of this action on the ASICs. That the active components of the extract are able to cross the blood-brain barrier gives them an additional advantage for future uses as tools to study pain mechanisms with a potential therapeutic application.     

The twin arginine consensus motif of Tat signal peptides is involved in Sec-independent protein targeting in Escherichia coli

In Escherichia coli a subset of periplasmic proteins is exported through the Tat pathway to which substrates are directed by an NH(2)-terminal signal peptide containing a consensus SRRXFLK "twin arginine" motif. The importance of the individual amino acids of the consensus motif for in vivo Tat transport has been assessed by site-directed mutagenesis of the signal peptide of the Tat substrate pre-SufI. Although the invariant arginine residues are crucial for efficient export, we find that slow transport of SufI is still possible if a single arginine is conservatively substituted by a lysine residue. Thus, in at least one signal peptide context there is no absolute dependence of Tat transport on the arginine pair. The consensus phenylalanine residue was found to be a critical determinant for efficient export but could be functionally substituted by leucine, another amino acid with a highly hydrophobic side chain. Unexpectedly, the consensus lysine residue was found to retard Tat transport. These observations and others suggest that the sequence conservation of the Tat consensus motif is a reflection of the functional importance of the consensus residues. Tat signal peptides characteristically have positively charged carboxyl-terminal regions. However, changing the sign of this charge does not affect export of SufI.     

Multiple Interactions between Cytoplasmic Domains Regulate Slow Deactivation of Kv11.1 Channels

The intracellular domains of many ion channels are important for fine-tuning their gating kinetics. In Kv11.1 channels, the slow kinetics of channel deactivation, which are critical for their function in the heart, are largely regulated by the N-terminal N-Cap and Per-Arnt-Sim (PAS) domains, as well as the C-terminal cyclic nucleotide-binding homology (cNBH) domain. Here, we use mutant cycle analysis to probe for functional interactions between the N-Cap/PAS domains and the cNBH domain. We identified a specific and stable charge-charge interaction between Arg⁵⁶ of the PAS domain and Asp⁸⁰³ of the cNBH domain, as well an additional interaction between the cNBH domain and the N-Cap, both of which are critical for maintaining slow deactivation kinetics. Furthermore, we found that positively charged arginine residues within the disordered region of the N-Cap interact with negatively charged residues of the C-linker domain. Although this interaction is likely more transient than the PAS-cNBD interaction, it is strong enough to stabilize the open conformation of the channel and thus slow deactivation. These findings provide novel insights into the slow deactivation mechanism of Kv11.1 channels.     

Modulation of acid-sensing ion channel currents, acid-induced increase of intracellular Ca2+, and acidosis-mediated neuronal injury by intracellular pH

Acid-sensing ion channels (ASICs), activated by lowering extracellular pH (pH(o)), play an important role in normal synaptic transmission in brain and in the pathology of brain ischemia. Like pH(o), intracellular pH (pH(i)) changes dramatically in both physiological and pathological conditions. Although it is known that a drop in pH(o) activates the ASICs, it is not clear whether alterations of pH(i) have an effect on these channels. Here we demonstrate that the overall activities of ASICs, including channel activation, inactivation, and recovery from desensitization, are tightly regulated by pH(i). In cultured mouse cortical neurons, bath perfusion of the intracellular alkalizing agent quinine increased the amplitude of the ASIC current by approximately 50%. In contrast, intracellular acidification by withdrawal of NH(4)Cl or perfusion of propionate inhibited the current. Increasing pH buffering capacity in the pipette solution with 40 mm HEPES attenuated the effects of quinine and NH(4)Cl. The effects of intracellular alkalizing/acidifying agents were mimicked by using intracellular solutions with pH directly buffered at high/low values. Increasing pH(i) induced a shift in H(+) dose-response curve toward less acidic pH but a shift in the steady state inactivation curve toward more acidic pH. In addition, alkalizing pH(i) induced an increase in the recovery rate of ASICs from desensitization. Consistent with its effect on the ASIC current, changing pH(i) has a significant influence on the acid-induced increase of intracellular Ca(2+), membrane depolarization, and acidosis-mediated neuronal injury. Our findings suggest that changes in pH(i) may play an important role in determining the overall function of ASICs in both physiological and pathological conditions.     

Fast and slow voltage sensor movements in HERG potassium channels

HERG encodes an inwardly-rectifying potassium channel that plays an important role in repolarization of the cardiac action potential. Inward rectification of HERG channels results from rapid and voltage-dependent inactivation gating, combined with very slow activation gating. We asked whether the voltage sensor is implicated in the unusual properties of HERG gating: does the voltage sensor move slowly to account for slow activation and deactivation, or could the voltage sensor move rapidly to account for the rapid kinetics and intrinsic voltage dependence of inactivation? To probe voltage sensor movement, we used a fluorescence technique to examine conformational changes near the positively charged S4 region. Fluorescent probes attached to three different residues on the NH₂-terminal end of the S4 region (E518C, E519C, and L520C) reported both fast and slow voltage-dependent changes in fluorescence. The slow changes in fluorescence correlated strongly with activation gating, suggesting that the slow activation gating of HERG results from slow voltage sensor movement. The fast changes in fluorescence showed voltage dependence and kinetics similar to inactivation gating, though these fluorescence signals were not affected by external tetraethylammonium blockade or mutations that alter inactivation. A working model with two types of voltage sensor movement is proposed as a framework for understanding HERG channel gating and the fluorescence signals.     

pH-Activated fusogenic transmembrane LV-peptides

LV-peptides mimic the in vitro fusogenicity of synthetic fusion protein transmembrane domains. The original versions of these peptides consist of a variable hydrophobic core (containing leucine and/or valine residues (LV)) that is flanked by invariant lysine triplets at both termini. Previously, peptide fusogenicity was correlated with the structural plasticity of their hydrophobic cores. Here, we examined the functional importance of positively charged flanking residues. To this end, we determined the fusogenicities of peptide variants that contain terminal His and/or Lys triplets. Interestingly, liposome fusion by peptides with His triplets was triggered by acidic pH. The pH dependence of fusion is reflected by a sigmoidal titration curve whose midpoint is close to the pKa value of histidine. Thus, only peptides with positively charged residues at both termini are fusogenic. The previously established dependence of fusogenicity on the sequence of the hydrophobic peptide core of Lys-flanked LV-peptides was preserved with the His-flanked versions at low pH. We propose that the structural flexibility of the core region as well as positive terminal charges are required for LV-peptide function in lipid mixing. In a potential practical application, the pH-dependent LV-peptides might prove to be useful in the lipofection of eukaryotic cells.     

A conformation change in the extracellular domain that accompanies desensitization of acid-sensing ion channel (ASIC) 3

Acid-sensing ion channels (ASICs) are thought to trigger some forms of acid-induced pain and taste, and to contribute to stroke-induced neural damage. After activation by low extracellular pH, different ASICs undergo desensitization on time scales from 0.1 to 10 s. Consistent with a substantial conformation change, desensitization slows dramatically when temperature drops (Askwith, C.C., C.J. Benson, M.J. Welsh, and P.M. Snyder. 2001. PNAS. 98:6459-6463). The nature of this conformation change is unknown, but two studies showed that desensitization rate is altered by mutations on or near the first transmembrane domain (TM1) (Coric, T., P. Zhang, N. Todorovic, and C.M. Canessa. 2003. J. Biol. Chem. 278:45240-45247; Pfister, Y., I. Gautschi, A.-N. Takeda, M. van Bemmelen, S. Kellenberger, and L. Schild. 2006. J. Biol. Chem. 281:11787-11791). Here we show evidence of a specific conformation change associated with desensitization. When mutated from glutamate to cysteine, residue 79, which is some 20 amino acids extracellular to TM1, can be altered by cysteine-modifying reagents when the channel is closed, but not when it is desensitized; thus, desensitization appears to conceal the residue from the extracellular medium. D78 and E79 are a pair of adjacent acidic amino acids that are highly conserved in ASICs yet absent from epithelial Na(+) channels, their acid-insensitive relatives. Despite large effects on desensitization by mutations at positions 78 and 79-including a shift to 10-fold lower proton concentration with the E79A mutant-there are not significant effects on activation.     

Differences in kinetics between GABAC and GABAA receptors on carp retinal bipolar cells

The present work was undertaken to characterize kinetics, including activation, desensitization and deactivation, of responses mediated by GABAA and GABAC receptors on carp retinal bipolar cells, using the whole-cell patch-clamp technique. It was revealed that the GABAC response was generally slower in kinetics than the GABAA response. Activation kinetics of both the receptors could be well fit by monoexponential functions with time constants τ, being 44.57 ms (GABAC) and 10.86 ms (GABAA) respectively. Desensitization of the GABAA response was characterized by a fast and a slow exponential component with time constants of τfast = 2.16 s and τslow = 19.78 s respectively, whereas desensitization of the GABAC response was fit by a monoexponential function of the time constant τ = 6.98 s. Deactivation at both the receptors was adequately described by biexponential functions with time constants being much higher for the GABAC response (τfast = 674.8 ms; τslow = 2 090 ms) than those for the GABAA response (τfast = 42.07 ms; τslow = 275.1 ms). These differences in kinetics suggest that GABAC and GABAA receptors may be involved in processing signals in different frequency domains.