Mol. Cells

A Single Natural Variation Determines Cytosolic Ca2+-Mediated Hyperthermosensitivity of TRPA1s from Rattlesnakes and Boas

Eun Jo Du and KyeongJin Kang

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Transient receptor potential ankyrin 1 from rattlesnakes (rsTRPA1) and boas (bTRPA1) was previously proposed to underlie thermo-sensitive infrared sensing based on transcript enrichment in infrared-sensing neurons and hyper-thermosensitivity expressed in Xenopus oocytes. It is unknown how these TRPA1s show thermosensitivities that overwhelm other thermoreceptors, and why rsTRPA1 is more thermosensitive than bTRPA1. Here, we show that snake TRPA1s differentially require Ca2+ for hyper-thermosensitivity and that predisposition to cytosolic Ca2+ potentiation correlates with superior thermosensitivity. Extracellularly applied Ca2+ upshifted the temperature coefficients (Q10s) of both TRPA1s, for which rsTRPA1, but not bTRPA1, requires cytosolic Ca2+. Intracellular Ca2+ chelation and substitutive mutations of the conserved cytosolic Ca2+-binding domain lowered rsTRPA1 thermosensitivity comparable to that of bTRPA1. Thapsigargin-evoked Ca2+ or calmodulin little affected rsTRPA1 activity or thermosensitivity, implying the importance of precise spatiotemporal action of Ca2+. Remarkably, a single rattlesnake-mimicking substitution in the conserved but presumably dormant cytosolic Ca2+-binding domain of bTRPA1 substantially enhanced thermosensitivity through cytosolic Ca2+ like rsTRPA1, indicating the capability of this single site in the determination of both cytosolic Ca2+ dependence and thermosensitivity. Collectively, these data suggest that Ca2+ is essential for the hyper-thermosensitivity of these TRPA1s, and cytosolic potentiation by permeating Ca2+ may contribute to the natural variation of infrared senses between rattlesnakes and boas.

Keywords: Ca2+ binding, nonsynonymous substitution, pit vipers, Q10 scanning, snake infrared sense, TRPA1


The ability of snakes to sense infrared radiation is mediated by facial sensory organs such as the rattlesnake pit organ located between the eye and the nostril, which harbors the infrared-receiving pit membrane densely innervated by trigeminal nerve endings (Bakken and Krochmal, 2007; Bullock and Fox, 1957). By contrast, the pit organs of the boa have a simpler design with or without shallow depression in the labial scales (Noble and Schmidt, 1937; Warren and Proske, 1968). Transient receptor potential ankyrin 1 (TRPA1) has been attributed to the molecular basis of infrared sensing observed in pit-bearing snakes, as its transcripts were heavily expressed compared with other genes in trigeminal neurons but not in dorsal root ganglia, only when the snakes are associated with an infrared-sensing capacity (Gracheva et al., 2010). Heterologously expressed rattlesnake and boa TRPA1s (rs- and bTRPA1s, respectively) were activated by increases in temperature, supporting the thermosensitive hypothesis that temperature increases in the pit membrane by infrared irradiation stimulate thermosensitive neurons for infrared imaging in the brain. The photochemical hypothesis, in which photochemical reactions enable detection of infrared radiation as found with visible light utilizing photoisomerization of opsin-bound 11-cis-retinal, was further ruled out by a subsequent study showing that temperature coefficients (Q10s) of rsTRPA1 and bTRPA1 reach as high as ~100,000 and ~3,000, respectively, when heterologously assessed in Xenopus oocytes (Kang, 2016a). Q10 is a popular measure of ion channel thermosensitivity defined to represent a fold current increase by a temperature increase of 10°C (Kang, 2016a; Kang et al., 2012; Liu et al., 2003). Typical ion channels unrelated to thermal sensation show Q10s between 1 and 3. Interestingly, the heterologous study also found that Q10s of snake TRPA1s were higher when the amplitudes of thermally evoked currents were large. This positive Q10/amplitude relationship was much more evident in rsTRPA1 than bTRPA1. For large rsTRPA1 currents, the thermosensitivity/amplitude relationship was dramatically shifted from a slope of 473 to 6,725 (Q10/µA). In contrast, the slope of the thermosensitivity/amplitude relationship obtained from bTRPA1 was low (Q10 of 64/µA) compared with that of rsTRPA1 and remained monotonous throughout a wide range of current amplitudes, implying that activity-dependent regulation of rsTRPA1 is more complex and impactful than that of bTRPA1. Such thermosensitivities/amplitude relationships different between the two snake TRPA1s were coherently seen by means of various analyses such as Q10 scanning, Arrhenius plots (Kang, 2016a; Liu et al., 2003), Boltzmann slope factors, and the molar heat capacity changes (Clapham and Miller, 2011; Kang, 2016b). Thus, previous analyses on the snake TRPA1s suggest that the differential abilities of infrared detection between rattlesnakes and boas (Campbell et al., 2002; de Cock Buning, 1983) may be attributed to the difference in thermosensitivity of TRPA1 (Kang, 2016a; 2016b) in addition to their anatomical differences described above. Despite this, it remains unknown why the two TRPA1 channels show such distinct thermal responses.

A hypothesis was previously proposed to address this unique observation on these snake TRPA1s (Kang, 2016a). The cation influx through the channel may potentiate thermal rsTRPA1 activation, leading to a high Q10/amplitude relationship. Consistent with this view, we here show that rsTRPA1 and bTRPA1 require extracellular Ca2+ to enhance their thermosensitivities. In particular, extracellularly applied Ca2+ appears to be necessary to flow in to the cytosol for robust thermal sensitivity of rsTRPA1 but not that of bTRPA1. Given that TRPA1s are generally known to conduct cations in a nonselective manner, we provide several lines of experimental evidence to elucidate that Ca2+ influx through rsTRPA1 leads to potentiation of thermosensitivity through cytosolic Ca2+. Therefore, Ca2+ elevates thermal sensitivities of snake TRPA1s, further promoting the thermosensitive hypothesis of snake infrared sensing, and our data illustrating TRPA1 potentiation by permeating Ca2+ address how rattlesnakes are equipped with a much more sensitive ability of infrared detection than boas at the molecular level of thermoreceptors.



EDTA (ED1041) and CaCl2 (CC1080) were purchased from GeorgiaChem (USA). Sigma-Aldrich (USA) supplied BaCl2 (202738), thapsigargin (T9033), BAPTA (14513), EGTA (E3889), and other essential chemicals.

Two-electrode voltage clamping on Xenopus oocytes

Thermally evoked current recordings in Xenopus laevis oocytes were acquired as described with minor modifications (Kang et al., 2010; 2012). Briefly, ovaries were surgically obtained from oocyte-positive X. laevis females commercially available from the Korean Xenopus Resource Center for Research in Korea ( The ovaries were then placed under collagenase treatment at 1.5 mg/ml of collagenase type II (Worthington, USA) for 90 min with gentle rocking. Capped RNA (cRNA) was prepared by in vitro transcription with the use of mMessage mMachine T7 kit (Ambion, USA) to express snake TRPA1s (pMO rsTRPA1 and pMO bTRPA1 plasmids [Gracheva et al., 2010], gifts from Dr. David Julius at UCSF). Drosophila TRPA1 (TRPA1(B)) has been described in our recent studies (Du et al., 2016a; 2016b; 2019; Hamada et al., 2008; Kang, 2016a; Kang et al., 2010; 2012). Before in vitro transcription, the plasmids of snake TRPA1s were linearized with HpaI, and that of dTRPA1 was with SacII for run-off transcription termination. Following injection of 50 nl of TrpA1 cRNA, oocytes were incubated for one day at 18°C in the Barth’s solution (100 NaCl, 1 KCl, 1 MgCl2, 0.5 CaCl2, 0.33 Ca(NO3)2, 5 HEPES, pH 7.6 in mM). For temperature-evoked current recordings, cells were perfused in the recording solution (100 NaCl, 1 KCl, 1 MgCl2, 5 HEPES, pH 7.6, 0.01 MONNA, and 0.01 flufenamic acid in mM), which was varied to provide different divalent cation conditions by including either 0.25 mM EDTA, 0.1 or 0.8 mM CaCl2, or 2 mM BaCl2. Typically, oocytes exhibited resting membrane potentials below –10 mV in these buffers and were analyzed only when the leak current at the beginning is below 500 nA. Voltage was initially held at –60 mV and ramped to +60 mV for 300 ms every second. The current was registered at 2,000 Hz by the GeneClamp 500B amplifier (Molecular Devices, USA) and subjected to data acquisition (Digidata 1440A; Molecular Devices). Temperature of the perfusion buffer was controlled to rise at ~0.5°C/s by SC-20 in-line heater/cooler (Warner Instruments, USA) with a CL100 biopolar temperature controller (Warner Instruments). Handling of the oocytes-donating frogs was conducted in accordance with the guideline which was approved by the Institutional Animal Care and Use Committee at Sungkyunkwan University in Korea (SKKUIACUC-20140036).

Q10 scanning

Q10 scanning was performed as established previously (Kang, 2016a) with minor modification. From the current recorded with voltage ramps, the current points at –60 mV were extracted using Clampfit 10.3 and transferred to Microsoft Excel. In this way, noise reduction or data smoothening processes could be omitted unlike the previous report (Kang, 2016a). In turn, Q10 was calculated by its definition Q10 = (I2 / I1)10/(t2-t1) with the use of two current and temperature data points apart from each other by 5 s corresponding to 2.5°C. The series of calculated Q10 at 1 Hz was plotted as function of the temperature t1.

Site-directed mutagenesis

Mutagenesis was performed as described previously (Kang et al., 2005a; 2005b). Substitutions in TRPA1s were made by swapping a region of wild-type (WT) cDNA sequence with a mutated cassette. A pair of mutually complementary oligonucleotide primers with a desired mutation were purchased, and each of them was paired with either upstream or downstream primers for the first two polymerase chain reaction (PCR) fragments, which overlap in the mutant primer-annealing region that contains the replaced codons, and served as template for the second PCR reaction amplified only with the upstream and downstream primers. The upstream and downstream primers were 40 base pairs away from unique restriction endonuclease target sites used to clone the second PCR products back in the WT cDNA background sequence. The 40 bp space between upstream and downstream primers and the restriction sites permits utilization of the primers for nucleotide sequencing reactions reading through the restriction site sequences. The fragments amplified by PCR were confirmed by sequencing after cloning to make sure that only desired mutations were introduced in the final cDNA constructs.

Statistical analysis

Statistical analyses were performed with Sigmaplot14.0 (SYSTAT Software, USA). For parametric tests, normality and homoscedasticity were examined by Shapiro–Wilk and Brown–Forsythe tests, respectively. When normality and equal variance were established, unpaired t-tests (two-sided) or ANOVA/Tukey post-hoc tests were performed. When normality or homoscedasticity tests failed, rank tests were used; Mann–Whitney U tests and Kruskal–Wallis one-way ANOVA with Dunn’s tests were performed. Unless otherwise indicated, *, **, and *** are P < 0.05, 0.01, and 0.001 for parametric tests, respectively, and #, ##, and ### represent P < 0.05, 0.01, and 0.001, respectively, for nonparametric tests. In some instances, letters were used to indicate statistical differences between groups: a, b, c… for parametric tests and p, q, r… for nonparametric tests.


To examine whether thermal activation of TRPA1s can be modulated by extracellular Ca2+, Xenopus oocytes expressing TRPA1s were subjected to two-electrode voltage clamping, during which time the temperature of the perfusion buffer was increased by approximately 0.5°C/s (Fig. 1A-1I, upper and middle panels). Q10 was extracted from the current/temperature recordings with the use of the Q10 scanning method (Fig. 1A-1I, bottom panels) established in our previous studies (Kang, 2016a; 2016b). Similar to Q10 acquisition by the Arrhenius analysis (Kang, 2016a; Liu et al., 2003), Q10 scanning yields a value representing the highest thermosensitivity point called peak Q10 (Q10p) (Fig. 1A-1J). As Q10s were acquired by exponential calculations (see Materials and Methods section), the data were log-transformed to attempt to achieve normal distribution and subsequently analyzed and plotted. When Ca2+-chelated (containing 0.25 mM EDTA) extracellular recording solution (100 mM NaCl, 1 mM KCl, 1 mM MgCl2, 5 mM HEPES, pH 7.6) was perfused, rsTRPA1 and bTRPA1 showed mean logQ10ps ± SEM of 3.53 ± 0.14 (Q10 of 3,388.4) and 1.85 ± 0.11 (Q10 of 70.8), respectively. Interestingly, addition of 0.1 mM Ca2+ in the recording buffer (without EDTA) dramatically increased their logQ10ps to 4.60 ± 0.21 (Q10 of 39,810.7) and 2.44 ± 0.10 (Q10 of 275.4), respectively (Fig. 1J), while current amplitudes were comparable between experimental groups (Fig. 1L). The thermosensitivity of rsTRPA1 but not bTRPA1 was also stimulated to reach mean logQ10p ± SEM of 4.86 ± 0.10 (Q10 of 72,443.6) by 2 mM Ba2+ in the perfusion solution, suggesting distinct characteristics of the putative cation-binding pockets of the two TRPA1s. In contrast, indicative of snake-specific Q10 potentiation by Ca2+, Q10p of the thermosensitive Drosophila TRPA1(B) isoform (dTRPA1) (8) was little shifted by the additional divalent cations. The temperature point producing Q10p was denoted as the peak temperature (Tp) (Fig. 1K) to compare temperatures at which the channels exhibit robust thermal sensitivity. Addition of either Ca2+ or Ba2+ slightly yet significantly lowered the Tp of rsTRPA1, but not those of the other two TRPA1s. Note that the endogenous Ca2+-activated chloride current (CaCC) was suppressed by a combination of potent Xenopus anoctamin 1 inhibitors, N-((4-methoxy)-2-naphthyl)-5-nitroanthranilic acid (MONNA) (Oh et al., 2013) and flufenamate (Guinamard et al., 2013), and that contamination of much less temperature-sensitive currents like CaCC in the tested temperature range lead to underestimation of Q10 caused by larger fractional increase of the current denominator in exponential Q10 calculation. In addition, CaCC in X. laevis oocytes is not provoked by Ba2+ (Oh et al., 2008). After a temperature drop from the highest point on the temperature ramp to room temperature, cells perfused with 2 mM Ba2+ often left relatively large residual currents of rsTRPA1 with increased time constants of the slow deactivation component (Fig. 1C, Supplementary Fig. S1A), indicating that Ba2+ interferes with cooling-induced fast deactivation of rsTRPA1.

Figure F1
(A-I) Representative temperature-dependent current recordings and Q10 scanning analyses of rsTRPA1 (A-C), bTRPA1 (D-F), and dTRPA1 (G-I) in Xenopus oocytes. Upper trace: current recordings at 1 Hz at –60 mV. ...

As TRPA1s are non-selective cation channels that readily conduct Ca2+, mammalian TRPA1s have been reported to be under modulation by permeating Ca2+ (Hasan et al., 2017; Wang et al., 2008; Zurborg et al., 2007). To test this possibility, oocytes expressing Ca2+-modulated TRPA1, rsTRPA1, or bTRPA1, were microinjected with chelators, while the normal Barth’s solution containing 0.8 mM Ca2+ was used for perfusion. Injection of either 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (BAPTA) or ethylene glycol-bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid (EGTA) to a final concentration of 1 mM or 2.5 mM, respectively, resulted in dramatic decreases of Q10p in rsTRPA1-expressing cells (Fig. 2A-2C, Supplementary Fig. S1B). Consistent with the faster chelation kinetics of BAPTA than EGTA (You et al., 1997), BAPTA-injected rsTRPA1 cells showed a severe drop from 0.8 mM-Ca2+-evoked logQ10p of 5.79 ± 0.30 (Q10 of 616,595.0) to 2.06 ± 0.27 (Q10 of 114.8) compared with those injected with EGTA that caused a decrement to logQ10p of 3.64 ± 0.20 (Q10 of 4,365.2). The two chelators are similar in Ca2+ affinities at steady state-127 and 149 nM at pH 7.2, respectively (You et al., 1997). The differential effects of these chelators suggest the fast action of intracellular Ca2+ in the potentiation of rsTRPA1 thermosensitivity. This result was recapitulated with 2 mM of external Ba2+ (Figs. 2A, 2D-2F), although BAPTA-induced Tp increase was not (Figs. 2B and 2E). We suspected that counteraction of intracellular BAPTA against Ba2+-provoked Q10s of rsTRPA1 may be artifactual because the current amplitudes expressed in the experiment were particularly low (Fig. 2F). Nevertheless, the BAPTA-uninjected and Ba2+-perfused control group binned with cells registering current amplitudes similar to those of the BAPTA/Ba2+ experiment supported a dramatic drop of Q10s in rsTRPA1-expressing cells by intracellular BAPTA (Fig. 2G). In contrast to rsTRPA1-expressing cells, Q10s of bTRPA1 or dTRPA1-expressing oocytes were little affected by BAPTA injections (Figs. 2H and 2I), indicating bTRPA1 Q10 potentiation only by extracellular Ca2+. Interestingly, BAPTA-injected rsTRPA1-expressing oocytes showed Q10s similar to BAPTA-uninjected bTRPA1-expressing cells (Figs. 2A and 2H), implying that intracellular potentiation by permeating Ca2+ substantially contributes to the higher thermosensitivity of rsTRPA1 than that of bTRPA1. Unlike mammalian TRPA1s regulated by calmodulin (CaM) (Hasan et al., 2017), rsTRPA1-expressing oocytes showed Q10p values similar to those concomitantly overexpressing either CaM WT or the CaM1234 mutant (Chang et al., 2018) lacking the Ca2+-binding ability (Fig. 2J) in the presence of 0.1 mM extracellular Ca2+, suggesting that there is little CaM-dependent potentiation/inhibition of rsTRPA1 thermosensitivity. Also, unlike a previous report on the activation of human TRPA1 (hTRPA1) by thapsigargin-induced Ca2+ release (Zurborg et al., 2007), Ca2+ from the endoplasmic reticulum (ER) by either a 1 or 5 min application of 1 µM thapsigargin failed to show significant current increases before or shifts in Q10s during temperature ramps (Fig. 2K-2M). The inability of Ca2+ from the ER to activate rsTRPA1 or modulate its thermosensitivity proposes that the precise spatiotemporal action of permeating Ca2+ is crucial for and probably limited to rsTRPA1 thermosensitivity rather than direct activation.

Figure F2
(A-C) Dot plots of LogQ10ps (A), peak temperatures (B), and current amplitudes (C) of rsTRPA1 with extracellular Ca2+ at 0.8 mM. Chelators were microinjected into oocytes to be at 1 ...

A previous report (Zurborg et al., 2007) found that a small stretch of the primary sequence in the twelfth N-terminal ankyrin repeat is responsible for Ca2+ binding and Ca2+-dependent hTRPA1 activation. This EF-hand-like sequence is relatively well conserved in rsTRPA1 and bTRPA1 (Figs. 3A [red line] and 3B). Similarly to hTRPA1, size-conserved substitutions in the domain abolishing negative charges (D476N and D477N) resulted in insensitivity of rsTRPA1 to externally applied Ca2+ and Ba2+ (Figs. 3E, 3G, and 3I). However, distinctive to hTRPA1, rsTRPA1D485N retained thermosensitivity provoked by the divalent cations (Figs. 3A, 3H, and 3I, Supplementary Fig. S2), as opposed to the corresponding D477A variant of hTRPA1 (Fig. 3A, right gray arrowhead) previously characterized with severe impairment in Ca2+-dependent activation (Zurborg et al., 2007). Interestingly, rsTRPA1 with the charge-conservative replacements D476E and D477E did retain Ca2+-dependent, but not Ba2+-dependent Q10 boosts (Figs. 3D, 3F, and 3I, Supplementary Fig. S2). The elongated acidic side chains may sterically hinder physical accommodation of Ba2+ in the putative binding pocket composed of the EF-hand-like sequence, as Ba2+ is larger in diameter than Ca2+. Such persistent Ca2+-responding capability of rsTRPA1 variants with charge- but not size-conservative changes strongly argues that the conserved EF-hand-like sequences indeed form an intracellular binding structure of divalent cations which critically assists the thermal gating of rsTRPA1.

Figure F3
(A) Sequence alignment of the conserved Ca2+-binding domain sequence previously identified in human TRPA1 (red line) with those of snake and fruit fly TRPA1s. Gray and black lines mark ankyrin ...

Intriguingly, sequence comparison between the putative cytosolic Ca2+-binding domain of rs- and bTRPA1s reveals a natural variation at D476 in rsTRPA1 to be K475 in bTRPA1, which inverses the charge of a corresponding residue identified above to be functionally important for Ca2+-mediated thermosensitivity. If the conserved but putative EF-hand-like sequence of bTRPA1 contains the structural potential accommodating divalent cations, the rattlesnake-imitating substitution K475D may confer bTRPA1 with Ca2+- and Ba2+-dependent increases of thermosensitivity. Indeed, replacement of the basic with the acidic residue enhanced thermosensitivity of bTRPA1-expressing cells ~6.6 times from WT logQ10p of 2.76 ± 0.24 (Q10 of 575.4) to K475D 3.58 ± 0.14 (Q10 of 3801.9) in the presence of 0.8 mM extracellular Ca2+ (Fig. 4A-4D). Furthermore, Q10 of bTRPA1 K475D was improved ~120.2 times by the extracellular addition of 0.8 mM Ca2+ compared with extracellularly chelated Ca2+ containing 0.25 mM EDTA, while that of bTRPA1 WT was increased only ~8.1 times (Fig. 4D). This result is very interesting in that a single substitution in the dormant cytosolic Ca2+-binding domain rendered bTRPA1 to be potentiated by as large a margin as with rsTRPA1; rsTRPA1 thermosensitivity was facilitated ~182.0 times by external 0.8 mM Ca2+ compared with the Ca2+-chelated condition (Fig. 4D).

Figure F4
(A and B) Representative temperature-sensitive current recording and Q10 scanning of bTRPA1 WT (A) and bTRPA1 K475D (B). (C) Extracellularly applied Ca2+ raised thermosensitivity of bTRPA1 K475D higher than that ...

Next, by microinjecting BAPTA to a final concentration of 1 mM, we tested whether the dramatic promotion of bTRPA1 thermal responsiveness by the substitution K475D was caused by Ca2+ influx as observed above with rsTRPA1. Interestingly, the intracellular BAPTA in cells expressing bTRPA1 K475D accompanied a large reduction of Q10ps albeit in the presence of 0.8 mM extracellular Ca2+ (Fig. 4E), bolstering the idea that the majority of acquired Ca2+-mediated thermosensitivity stemmed from permeating Ca2+. The oocytes in this condition (with little intracellular Ca2+ due to BAPTA but 0.8 mM extracellular Ca2+), however, had slightly but significantly higher logQ10ps than the oocytes deprived only of extracellular Ca2+ (BAPTA-uninjected and perfused in the recording buffer with 0.25 mM EDTA) unlike rsTRPA1 WT (Supplementary Fig. S1B), indicating that the K475D variant retained the ability to be potentiated by extracellular Ca2+ as observed with bTRPA1 WT. The K475D replacement did not transform bTRPA1 to be thermally potentiated by Ba2+, implying that there are further structural requirements for bTRPA1 to accommodate Ba2+ in the conserved cytosolic Ca2+-binding domain.


Consistent with the thermosensitive model of infrared sense, we previously showed that thermosensitivities of TRPA1s from rattlesnakes and boas can be much higher than molecular thermoreceptors found in non-infrared-sensing animals including Drosophila (Kang, 2016a; 2016b). In this study, we found that thermosensitivities of the snake TRPA1s were upregulated by extracellularly applied Ca2+. Interestingly, the mechanisms of Ca2+ potentiation in thermal activation were disparate for rsTRPA1 and bTRPA1 in that they require Ca2+ at the opposite side of the plasma membrane. The cytosolic Ca2+ requirement was endowed by a single substitution in the conserved cytosolic Ca2+-binding domain of bTRPA1 (Supplementary Fig. S3A). Such cytosolic Ca2+ potentiation of thermal activation may explain the previously reported dramatic Q10/current amplitude relationship observed with rsTRPA1 (Kang, 2016a). Nominally Ca2+-free recording solutions without Ca2+-buffering reagents such as EDTA are typically used in two-electrode voltage clamping on Xenopus oocytes to minimize induction of endogenous CaCC. Nevertheless, free Ca2+ ions are often present in the recording solution due to contamination from various sources such as glassware and other chemicals. The physiologically low and thus unsaturating concentrations of Ca2+ contamination may then cause rsTRPA1-expressing cells to yield more robust Q10 via cytosolic potentiation of rsTRPA1, when thermosensitive currents through rsTRPA1 are larger to provide higher numbers of permeating Ca2+ ions. Thus, the steeply proportional Q10/current amplitude relationships previously obtained with rsTRPA1-expressing cells likely result from permeating-Ca2+-mediated potentiation of thermal activation.

One interesting aspect of our results is that cytosolic potentiation by Ca2+ correlates with superior thermosensitivities as observed with rsTRPA1 and bTRPA1 K475D: for example, mean Q10ps of ~600,000 and ~575 for intracellularly regulated rsTRPA1 and extracellularly modulated bTRPA1 WT, respectively, and mean Q10ps of ~3,800 and ~575 for intracellularly potentiated bTRPA1 K475D and extracellularly modulated bTRPA1 WT, respectively. This finding suggests that cytosolic potentiation is more effective in promoting thermal activation of TRPA1s than extracellular regulation. A possible explanation for this observation is that the cytosolic Ca2+-binding domain may be closely linked with the temperature-sensing domain, so that the two positively regulating pathways intimately work together with synergistic cooperation. Systematic structural mapping, previously conducted by thermally examining various chimeras between rsTRPA1 and hTRPA1 with and without warmth sensitivity, respectively, indeed attributed the capability of thermal activation to two major areas of N-terminal ankyrin repeat domains (Cordero-Morales et al., 2011). Therefore, it is very likely that Ca2+ binding to the cytosolic domain greatly affects thermal sensitivity of these domains, as the ankyrin repeat 12 responsible for the cytosolic Ca2+ binding in rsTRPA1 is strategically positioned to be a part of or in proximity to the rsTRPA1 domains conferring hTRPA1 with thermal sensitivity. By contrast, chimeric investigation between dTRPA1 and hTRPA1 reported the extracellular pore region as the key area essential for thermal sensitivity (Wang et al., 2013). These inconsistent outcomes may be because of different TRPA1s used in the studies, implying that several areas of the TRPA1 structure operate together to execute the temperature-sensing function, and/or that d- and rsTRPA1 may have divergently evolved to harbor distinct temperature-sensing mechanisms for the sensation of warmth.

Acquisition of cytosolic Ca2+ sensitivity by a single substitution in bTRPA1 suggests that the loss of cytosolic Ca2+-mediated potentiation may be a recent evolutionary event in boas, as bTRPA1 retains other structural features required for the Ca2+-mediated potentiation. Supporting this possibility, sequence alignments show that the amino acid residue corresponding to K475 in bTRPA1 is mostly conserved with an acid residue in a wide range of snake species as well as Erys tataricus, another species in the boidae (Supplementary Fig. S3B). However, because TRPA1s from pythons, another group of pit-bearing snakes considered to be ancient like boas (Gracheva et al., 2010), have single prolines in this site with charge-neutralizing characteristics similar to our rsTRPA1 D476N mutant and thus supposedly removing intracellular Ca2+ binding, it cannot be excluded that other snake TRPA1s have recently acquired the acidic residue for cytosolic potentiation. Further functional and systemic investigations with TRPA1s from various snake species will be necessary for a clear picture on the molecular evolution of cytosolic Ca2+-mediated potentiation in snake TRPA1s. It is also interesting to discover the evolutionary driving force for the wide adaptation of cytosolic Ca2+-mediated potentiation to the snakes unrelated to infrared senses. Conversely, if TRPA1s from infrared-sensing boa and pythons have recently lost cytosolic potentiation by Ca2+, there must have been an environmental pressure against hyper-thermosensitivity of the TRPA1s, of which ecological significances would be a subject of interest.

Contribution of permeating Ca2+ to channel modulation has been known for many sensory functions of TRP channels (Hasan and Zhang, 2018). Mammalian TRPA1s require cytosolic Ca2+ to be robustly activated by hydrogen peroxide (Andersson et al., 2008) and cold temperatures (Zurborg et al., 2007) as well as to be negatively regulated (Wang et al., 2008), while Ca2+ alone can trigger channel activation (Zurborg et al., 2007). Similarly, activation of TRPM8 by icilin needs to coincide with intracellular Ca2+ induced by either channel permeation or release from the intracellular Ca2+ storage (Chuang et al., 2004). In the case of rsTRPA1, Ca2+ only serves as a positive regulator rather than a requirement for thermal activation, which may widen the dynamic range of thermosensitivity that rsTRPA1 can exhibit. As cytosolic potentiation by permeating Ca2+ is an intrinsic property of rsTRPA1 embedded by the simple conserved sequence stretch as observed here and necessarily associated with the opening of Ca2+-conducting rsTRPA1 in physiological conditions, our findings in the heterologous expression system likely have relevance to in vivo settings in the rattlesnake pit membrane.

Supplemental Materials

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Article information

Mol. Cells.Jun 30, 2020; 43(6): 572-580.
Published online 2020-06-2. doi:  10.14348/molcells.2020.0036
1Department of Anatomy and Cell Biology and Samsung Biomedical Research Institute, Samsung Medical Center, Sungkyunkwan University School of Medicine, Suwon 16419, Korea
Received February 2, 2020; Accepted May 11, 2020.
Articles from Mol. Cells are provided here courtesy of Mol. Cells


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Figure 1

(A-I) Representative temperature-dependent current recordings and Q10 scanning analyses of rsTRPA1 (A-C), bTRPA1 (D-F), and dTRPA1 (G-I) in Xenopus oocytes. Upper trace: current recordings at 1 Hz at –60 mV. The extracellular divalent cation conditions are indicated. Middle: temperature change, ~0.5°C/s. The two sets of data points of currents and temperatures producing the maximum Q10 in the recordings are marked with colored circles linked between upper and middle panels. Bottom: Q10 changes throughout the tested temperature range calculated with the interval of 2.5°C. Peak Q10s and Peak Q10-yielding temperatures are indicated. (J) Dot plots of maximum Q10s in the log scale with indicated TRPA1s and extracellular divalent cation conditions. (K) Dot plots of temperatures exhibiting the maximum Q10s (peak temperatures). (L) Dot plots of peak current amplitudes of indicated experiments. *P < 0.05 and ***P < 0.001, Tukey’s test. #P < 0.05, Dunn’s test.

Figure 2

(A-C) Dot plots of LogQ10ps (A), peak temperatures (B), and current amplitudes (C) of rsTRPA1 with extracellular Ca2+ at 0.8 mM. Chelators were microinjected into oocytes to be at 1 and 2.5 mM for BAPTA and EGTA in the cytosol. (D-F) Dot plots of LogQ10ps (D), peak temperatures (E), and current amplitudes (F) of rsTRPA1 with extracellular Ba2+ at 0.8 mM indicated conditions. Chelators were microinjected as done in Figs. 2A-2C. (G) Cells with small current amplitudes were compared as BAPTA/Ba2+ experiments yielded low amplitudes (F). (H and I) Thermosensitivities and associated parameters of cells expressing bTRPA1 (H) or dTRPA1 (I) were not affected by BAPTA microinjection. (J) Overexpression of calmodulin WT and the CaM1234 mutant did not change rsTRPA1 thermosensitivity. (K-M) Short (K) and long (L) application of 1 µM thapsigargin did not activate rsTRPA1 before temperature ramps or shift its thermosensitivity. Letters indicate statistically distinct groups (Tukey’s test): P < 0.01 (A), P < 0.001 (D). ***P < 0.001, Tukey’s test; #P < 0.05, Dunn’s test.

Figure 3

(A) Sequence alignment of the conserved Ca2+-binding domain sequence previously identified in human TRPA1 (red line) with those of snake and fruit fly TRPA1s. Gray and black lines mark ankyrin repeats. Gray arrowheads: acidic residues previously characterized to be important for Ca2+ binding. Black arrowheads: acidic residues tested in this study. (B) Scheme for location of the conserved Ca2+-binding domain in the secondary structure of TRPA1. (C-H) Typical Q10 analyses of rsTRPA1 variants with varying extracellular divalent cation conditions as indicated. Peak Q10s and peak temperatures are presented as numbers. (I) Summary of thermosensitivities exhibited by cells expressing indicated rsTRPA1 variants. *P < 0.05, Tukey’s test; #P < 0.05, Dunn’s test.

Figure 4

(A and B) Representative temperature-sensitive current recording and Q10 scanning of bTRPA1 WT (A) and bTRPA1 K475D (B). (C) Extracellularly applied Ca2+ raised thermosensitivity of bTRPA1 K475D higher than that of bTRPA1 WT. (D) Comparison of fold Q10 increases by extracellular Ca2+ among bTRPA1s and rsTRPA1. (E) Substantial portion of extracellularly applied Ca2+-dependent thermosensitivity is via the cytosol as probed with BAPTA, but unobservable with extracellularly applied Ba2+. Letters mark statistically different groups (Tukey’s test): P < 0.01 (C), P < 0.05 (E).