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. 2004 May 1;556(Pt 3):691-710.
doi: 10.1113/jphysiol.2003.058693. Epub 2004 Feb 27.

Acid-sensing ion channels ASIC2 and ASIC3 do not contribute to mechanically activated currents in mammalian sensory neurones

Liam J Drew  1 Daniel K RohrerMargaret P PriceKaren E BlaverDebra A CockaynePaolo CesareJohn N Wood
Affiliations

Acid-sensing ion channels ASIC2 and ASIC3 do not contribute to mechanically activated currents in mammalian sensory neurones

Liam J Drew et al. J Physiol. .

Abstract

The molecular basis of mechanosensory transduction by primary sensory neurones remains poorly understood. Amongst candidate transducer molecules are members of the acid-sensing ion channel (ASIC) family; nerve fibre recordings have shown ASIC2 and ASIC3 null mutants have aberrant responses to suprathreshold mechanical stimuli. Using the neuronal cell body as a model of the sensory terminal we investigated if ASIC2 or 3 contributed to mechanically activated currents in dorsal root ganglion (DRG) neurones. We cultured neurones from ASIC2 and ASIC3 null mutants and compared response properties with those of wild-type controls. Neuronal subpopulations [categorized by cell size, action potential duration and isolectin B4 (IB4) binding] generated distinct responses to mechanical stimulation consistent with their predicted in vivo phenotypes. In particular, there was a striking relationship between action potential duration and mechanosensitivity as has been observed in vivo. Putative low threshold mechanoreceptors exhibited rapidly adapting mechanically activated currents. Conversely, when nociceptors responded they displayed slowly or intermediately adapting currents that were smaller in amplitude than responses of low threshold mechanoreceptor neurones. No differences in current amplitude or kinetics were found between ASIC2 and/or ASIC3 null mutants and controls. Ruthenium red (5 microm) blocked mechanically activated currents in a voltage-dependent manner, with equal efficacy in wild-type and knockout animals. Analysis of proton-gated currents revealed that in wild-type and ASIC2/3 double knockout mice the majority of putative low threshold mechanoreceptors did not exhibit ASIC-like currents but exhibited a persistent current in response to low pH. Our findings are consistent with another ion channel type being important in DRG mechanotransduction.

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Figures

Figure 1
Figure 1. Disruption of the ASIC3 gene in mice
A, the wild-type ASIC3 gene has 11 identified exons (rectangles). The wild-type ASIC3 locus is bounded by two Xba I sites, ∼20 kb apart (X =Xba I, R = EcoR I). The middle panel shows the ASIC3 gene targeting vector that deletes most of exon 1 and all of exon 2. Targeted constructs acquired a new Xba I site, 3.6 kb upstream from the endogenous 3′Xba I site. B, Southern blot analysis of ASIC3 gene-targeted embryonic stem cells. Wild-type and gene-targeted fragment sizes are indicated. C, RT-PCR analysis of mRNA expression in wild-type and ASIC3 null mice. Separate reactions were carried out for GAPDH and ASIC3, under identical amplification conditions. Amplification products were electrophoresed, Southern blotted, and probed with 32P cDNA probes. W = wild-type, K = ASIC3 null, −= no RNA.
Figure 2
Figure 2. Action potentials and mechanically activated currents of large, wild-type DRG neurones
A, examples of narrow (top) and wide (bottom) action potentials of large DRG neurones. Action potential traces are shown on the left and the differentials of these waveforms, which allow inflections to be more easily observed, are on the right. B, frequency histograms indicating the proportion of neurones with narrow and wide action potentials that respond to mechanical stimulation with rapidly adapting (RA), slowly adapting (SA), intermediately adapting (IA) or no (No Res) currents. C, example traces of MA currents (only suprathreshold traces shown). Left, rapidly adapting current from a narrow action potential neurone. Right, intermediately adapting current from a neurone with a wide action potential. D, relationship between stimulus size and MA current amplitude in neurones with narrow (□) and wide (•) action potentials. E, example traces showing the lack of effect of 300 nm TTX on rapidly adapting MA currents in neurones with narrow action potentials; left, control current; centre, current in the presence of 300 nm TTX; and right, current following washing in control solution. Currents in TTX were 99.1 ± 1.4% of control values (n = 3).
Figure 3
Figure 3. Decay of rapidly adapting MA currents is well described by two exponentials
A, example of the fitting of two exponentials (continuous line) to the decay of a MA current (dashed line). B and C, graphs show the relationship between peak current amplitude and the duration of τ1 (B) and τ2 (C) for RA MA currents evoked by a 16 μm stimulus (n = 46). In both cases there is a significant positive correlation between each variable for τ1, r = 0.40 (Pearson's product moment, P < 0.01) and for τ2, r = 0.88 (P < 0.001).
Figure 4
Figure 4. Comparison of MA currents in large neurones from wild-type and ASIC2 and/or 3 null mutants
A, graphs showing stimulus–response relationships for ASIC2 (n = 21), 3 (n = 8) and 2/3 (n = 25) knockouts (KO) versus wild-type controls (n = 21, 8 and 25, respectively). B, example traces of RA MA currents from narrow action potential neurones (scale bar is 1 nA in each trace). Left, traces from null mutants and, right, from wild-types for ASIC2 (top), ASIC3 (middle) and ASIC2/3 (bottom). C, frequency histograms for responses to mechanical stimulation of narrow (left) and wide (right) action potential neurones for null mutants (right) and wild-type controls (left). D, comparison of τ1 (left) and τ2 (right) values for RA MA currents between wild-type controls (open columns) and null mutants (filled columns): ASIC 2 (left), ASIC3 (centre) and ASIC2/3 (right).
Figure 5
Figure 5. RA MA currents are voltage dependently blocked by ruthenium red
A, inhibition of RA MA currents by 5 μm ruthenium red at a holding potential of −70 mV (left) and +70 mV (right) in wild-type (filled columns) and ASIC2/3 double knockouts (DKOs) (open columns). B, example traces of ruthenium red blockade of MA currents in a wild-type neurone held at −70 mV. C, example traces showing no effect of ruthenium red at +70 mV in an ASIC2/3 DKO neurone.
Figure 6
Figure 6. MA currents exhibited by wild-type and ASIC2/3 DKO IB4– small–medium DRG neurones
A, frequency histograms for responses of wild-type and ASIC2/3 DKO neurones; responses were of four types – slowly (SA), rapidly (RA) or intermediately (IA) adapting currents, or no response (No Res). B, comparison of stimulus–response relationships for pooled data from IA and SA currents of wild-type (•, n = 11) and ASIC2/3 DKO (○, n = 9) neurones. CE, example traces of RA, IA and SA currents, respectively, from wild-type (left) and ASIC2/3 DKO (right) neurones.
Figure 7
Figure 7. MA currents exhibited by adult rat, wild-type mouse and ASIC2/3 DKO mouse IB4+ DRG neurones
A, frequency histogram showing that approximately half of IB4+ neurones from wild-type (56.3%, left) and ASIC2/3 DKO (50.0%, centre) mice exhibited intermediately adapting MA currents whilst the remainder were unresponsive to mechanical stimulation. In the adult rat 56.3% of neurones did not respond; of those that did 6/7 had intermediately adapting kinetics and the seventh was slowly adapting. B, comparison of stimulus–response relationships for wild-type (•, n = 9) and ASIC2/3 DKO (○, n = 10) neurones from mice showing no significant difference between these populations. C, examples of MA current traces from a wild-type (left) and an ASIC2/3 DKO (centre) mouse neurone and an adult rat neurone (right).
Figure 8
Figure 8. Currents activated in large DRG neurones by pH 5.3; comparison of ASIC2/3 DKO and wild-type neurones
A, frequency histograms of the responses of different neuronal populations to pH 5.3. Left, large neurones with narrow action potentials; right, large neurones with wide action potentials; wild-type columns are on the left and nulls on the right. Responses were classified as Transient, Slow/TRPV1 (slowly activating persistent currents or currents probably mediated by TRPV1), Mixed (initial transient peak followed by slowly activating persistent current) or Negative (non-responsive). Mixed currents were absent from ASIC2/3 DKO neurones, otherwise the proportions of each type of response were similar in each subpopulation. B, example traces from wild-type (top) and ASIC2/3 DKO (bottom) large, narrow action potential neurones. C, mean peak current amplitudes of transient proton-gated currents. Currents generated by large neurones with narrow action potentials (left) and wide action potentials (right); wild-type (filled columns) and ASIC2/3 DKO (open columns). In wild-types, responses of wide action potential cells were significantly larger than those of narrow action potential cells (P < 0.05). ASIC2/3 DKOs had larger currents than wild-types in narrow action potential neurones (P < 0.05) and there was a similar trend between wide action potential neurones (P = 0.054). D, mean current amplitudes of persistent proton-gated currents in large neurones with narrow action potentials; wild-type (filled column) and ASIC2/3 DKO (open column).
Figure 9
Figure 9. Currents activated in small–medium DRG neurones by pH 5.3; comparison of ASIC2/3 DKO and wild-type neurones
A, frequency histograms of the responses of different neuronal populations to pH 5.3. Left, IB4– nociceptors, and right, IB4+ nociceptors; wild-type columns are on the left and nulls on the right. Responses were classified as Transient, Slow/TRPV1, Mixed or Negative. In IB4– neurones the proportion of cells displaying transient currents was similar between genotypes (wild-type, 50.0%; DKO, 43.8%); mixed currents were absent from ASIC2/3 DKO neurones. The majority of IB4+ neurones did not respond to acidification and transient proton-gated currents were not observed in these cells. No distinction between genotypes was seen. B, example traces from wild-type (top) and ASIC2/3 DKO (bottom) IB4– neurones with wide action potentials. C, mean peak amplitude of transient currents in wild-type (filled column) and ASIC2/3 DKO (open column) IB4– nociceptors; currents were significantly smaller in wild-type neurones (P < 0.01). D, mean amplitude of persistent currents in capsaicin-insensitive wild-type (filled column) and ASIC2/3 DKO (open column) IB4– nociceptors. No difference was found between genotypes.
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