Acute pain represents a crucial alarm signal to protect us from injury1. Whereas the nociceptive neurons that convey pain signals were described more than a century ago2, the molecular sensors that detect noxious thermal or mechanical insults have yet to be fully identified3,4,5,6. Here we show that acute noxious heat sensing in mice depends on a triad of transient receptor potential (TRP) ion channels: TRPM3, TRPV1, and TRPA1. We found that robust somatosensory heat responsiveness at the cellular and behavioural levels is observed only if at least one of these TRP channels is functional. However, combined genetic or pharmacological elimination of all three channels largely and selectively prevents heat responses in both isolated sensory neurons and rapidly firing C and Aδ sensory nerve fibres that innervate the skin. Strikingly, Trpv1−/−Trpm3−/−Trpa1−/− triple knockout (TKO) mice lack the acute withdrawal response to noxious heat that is necessary to avoid burn injury, while showing normal nociceptive responses to cold or mechanical stimuli and a preserved preference for moderate temperatures. These findings indicate that the initiation of the acute heat-evoked pain response in sensory nerve endings relies on three functionally redundant TRP channels, representing a fault-tolerant mechanism to avoid burn injury.
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Pflügers Archiv - European Journal of Physiology Open Access 22 July 2022
Thermal gradient ring reveals different temperature-dependent behaviors in mice lacking thermosensitive TRP channels
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We thank all members of the Laboratories of Ion Channel Research and Experimental Gynecology and Obstetrics for comments and discussion, and K. Luyten for assistance with histological and in situ staining. This work was supported by grants from the KU Leuven Research Council (PF-TRPLe and C1-TRPLe to Tho.V. and R.V.), the Research Foundation-Flanders (FWO G.084515N to J.V. and Tho.V. and G.099114N to Tho.V. and Thi.V.), the Queen Elisabeth Medical Foundation for Neurosciences (to Tho.V.), the Belgian Foundation Against Cancer (to J.V. and Tho.V.) and the Planckaert-De Waele fund (to J.V.). K.D.C. and K.H. are holders of a doctoral fellowship of the FWO Belgium.
The authors declare no competing financial interests.
Reviewer Information Nature thanks J. Wood and the other anonymous reviewer(s) for their contribution to the peer review of this work.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Extended data figures and tables
Extended Data Figure 1 Heat sensitivity is preserved in Trpm3−/−Trpv1−/− double knockout (DKOM3/V1) mice.
a, Percentages of wild-type (296 neurons from 6 mice) and DKOM3/V1 (1,353 neurons from 9 mice) trigeminal neurons responding to the indicated stimuli. b, Single-fibre nerve recording of a mechano- and heat-sensitive C fibre innervating the skin of a DKOM3/V1 mouse. c, Withdrawal latencies of wild-type (N = 10) and DKOM3/V1 (N = 7) mice in the tail-flick (at 57 °C) and hot-plate (at 50 °C) assays. Dotted lines indicate the cut-off time. Horizontal lines indicate mean. d, Venn diagram showing the level of functional coexpression of TRPM3, TRPV1 and TRPA1 in wild-type trigeminal neurons, based on responsiveness to PS, Caps and AITC (n = 662 neurons from 6 mice).
a, In situ hybridization using a TRPM8-specific probe in trigeminal ganglia of wild-type and TKO mice. b, Example of a sensory neuron from a TKO mouse responding to cold (15 °C) and the TRPM8 agonists menthol (50 μM) and icilin (1 μM). Scale bar, 6s/100 nM. c, Percentages of cold-responding and menthol-responding neurons in wild-type (n = 225 from 3 mice) and TKO mice (n = 189 from 3 mice). **P = 0.0089; Fisher’s exact test. d, Transcriptome-wide comparison of mRNA expression between wild-type and TKO mice. Several ion channels that have been previously implicated in heat sensing are indicated. e, Heat map showing the differential expression levels in single, double and triple knockout mice of a set of about 200 genes implicated in somatosensation20. Expression levels are defined as the log2 fold change compared to the wild type. Except for Trpm3, Trpv1 and Trpa1, no genes showed more than 50% up- or downregulation of expression in TKO compared to wild-type mice.
a, Representative examples of responses to heat, in the absence and presence of H2O2, in an AITC-sensitive and an AITC-insensitive sensory neuron from DKOM3/V1 mice. b, Example of the suppression of heat responses in an AITC-sensitive DKOM3/V1 neuron by the TRPA1 antagonist HC030031 (100 μM). c, Heat-insensitive TKO sensory neurons are also insensitive to H2O2 (n = 147 from 4 mice). d, e, Heat responses in TKO sensory neurons (which occur in only about 2% of the total population) are neither potentiated by H2O2 (400 μM; n = 147 from 4 mice) nor inhibited by 2-APB (250 μM; n = 150 from 4 mice). Scale bars in a–e, 60s/100 nM. f, Average heat-induced increases in intracellular calcium during the three consecutive heat responses in the protocol shown in a–d, for the indicated subtypes of neurons. Number of tested trigeminal neurons for the data in f: DKOM3/V1, n = 308 from 6 mice; DKOM3/V1 + HC030031, n = 104 from 4 mice; TKO, n = 147 from 4 mice. Group data are represented as mean ± s.e.m.
a, Representative examples of responses to heat (45 °C), AITC (50 μM) and the ionophore ionomycin (2 μM) in CHO cells stably expressing mouse TRPA1. b, c, Potentiation of the heat response by H2O2 (100 μM) and inhibition by HC030031 (100 μM). d, Population analysis of all tested cells corresponding to the experiments in a–c. Control, n = 394; H2O2, n = 560; H2O2 + HC030031, n = 103 cells. As a conservative estimate of TRPA1-dependent heat responses, cells with a heat response larger than 5 s.d. above the mean of responses in the presence of HC030031 (dotted red line) were counted. Corresponding percentages are indicated. The H2O2 group was significantly different from the two other groups (***P < 0.00001; two-sided Mann–Whitney test with Bonferroni correction).
Histogram showing the peak firing rate of all tested heat-sensitive C fibres. Solid line shows the sum of two Gaussians (dotted lines) fit to the data. On the basis of these data, fibres were classified as either low frequency (LF; peak firing rate <23 Hz) or high frequency (HF; peak firing rate >23 Hz).
a, PGP9.5 staining of the plantar hind paw skin, representative of wild-type (N = 5) and TKO (N = 5) mice. Scale bar, 20 μm. Black arrows indicate nerve bundles. b, For each mouse, the nerve bundle areas of 20 sections were evaluated with an average distance of 0.1 mm between the cross sections. No significant difference was found between the two genotypes. P = 0.08; two-sided Student’s t-test. Group data are represented as mean ± s.e.m.
a–d, Withdrawal latencies for male mice of different genotypes in the tail-immersion assay at the indicated temperatures. The cut-off (dashed line) was set at four times the mean withdrawal latency of wild-type mice. Number of tested animals: wild-type, N = 10; DKOM3/A1, N = 6; DKOV1/A1, N = 9; DKOM3/V1, N = 7; TKO, N = 9. Horizontal lines indicate means. e, P values for pair-wise comparisons of the withdrawal latencies of the different genotypes. A two-way ANOVA was performed with genotype and bath temperature as factors. P values represent the result of Tukey’s post-hoc tests for the factor genotype, and thus quantify global statistical differences in latency over the five tested temperatures (45, 48, 50, 52 and 57 °C). Similar results, yielding P < 10−4 for the comparison of TKO mice with either wild-type mice or mice of the different DKO genotypes, were obtained with a second independent cohort of male mice (5–6 mice per genotype).
a, Withdrawal latencies of female wild-type (N = 10) and TKO (N = 10) mice in the tail-immersion assay at the indicated temperatures. The cut-off (dashed line) was set at four times the mean withdrawal latency of wild-type mice. Indicated P values were obtained using a two-sided Student’s t-test. b, Withdrawal latencies of female wild-type (N = 10) and TKO (N = 10) mice in the hot-plate assay at the indicated temperatures. The cut-off (dashed line) was set at three times the mean withdrawal latency of wild-type mice. Indicated P values were obtained using two-sided Student’s t-tests. c, Sensitivity of female wild-type (N = 10) and TKO (N = 10) mice to calibrated von Frey hairs (P = 0.86; two-sided Student’s t-test). d, e, Photograph of the tails of male mice of the indicated genotypes (d) and close-up of the tails of five TKO mice (e) taken 3 days after a 57 °C tail-flick experiment. f, Percentage of mice of the indicated genotypes exhibiting visual signs of burn injury 3 days after a 57 °C tail-flick experiment (five mice per genotype).
a, Preference index for the blue (<10 °C) versus the red zone (>45 °C) on the thermal gradient. Preference index was calculated as (tblue zone − tred zone)/(tblue zone + tred zone). ***P = 2.2 × 10−6, **P = 7.2 × 10−5, *P = 0.026, two-way ANOVA with Tukey’s post-hoc test for the factor genotype. Wild-type, N = 13; DKOM3/A1, N = 5; DKOV1/A1, N = 7; DKOM3/V1, N = 10; TKO, N = 10. b, Duration of the longest uninterrupted visit to the test plate. ***P = 7.7 × 10−5, **P = 0.0029, ##P = 0.0013, *P = 0.0072; one-way ANOVA with Tukey’s post-hoc test. c, Parameters describing thermal preference behaviour in the thermal gradient and two-plate preference tests. Number of tested animals: wild-type, N = 9; DKOM3/A1, N = 6; DKOV1/A1, N = 6; DKOM3/V1, N = 10; TKO, N = 9.
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Vandewauw, I., De Clercq, K., Mulier, M. et al. A TRP channel trio mediates acute noxious heat sensing. Nature 555, 662–666 (2018). https://doi.org/10.1038/nature26137
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