The conformational wave in capsaicin activation of transient receptor potential vanilloid 1 ion channel

Yang, Fan; Xiao, Xian; Lee, Bo Hyun; Vu, Simon; Yang, Wei; Yarov‐Yarovoy, Vladimir; Zheng, Jie

doi:10.1038/s41467-018-05339-6

Cited by 65 publications

(78 citation statements)

References 67 publications

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“…Therefore, voltage activation cannot be carried out through the same transition promoted by capsaicin, i.e., if Scenario B is true, capsaicin cannot be stimulus X . Indeed, as capsaicin induces TRPV1 activation by linking S4 to the S4-S5 linker 42-44 , these results offered further supports for the conclusion that voltage activation does not involve S4. Furthermore, the observation of a voltage-independent, elevated P o in the presence of capsaicin also validated the conclusion that voltage cannot work through the C↔O transition to open the channel, i.e., Scenario A is invalid.…”

Section: Identifying the Voltage-dependent Transitionsupporting

confidence: 61%

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An unorthodox mechanism underlying voltage sensitivity of TRPV1 ion channel

Yang

Lee

et al. 2020

Preprint

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14While the capsaicin receptor TRPV1 channel is a polymodal nociceptor for heat, 15 capsaicin, and proton, the channel's responses to each of these stimuli are 16 profoundly regulated by membrane potential, damping or even prohibiting its 17 response at negative voltages and amplifying its response at positive voltages. 18 Though voltage sensitivity plays an important role is shaping pain responses, 19 how voltage regulates TRPV1 activation remains unknown. Here we showed that 20 the voltage sensitivity of TRPV1 does not originate from the S4 segment like 21 classic voltage-gated ion channels; instead, outer pore acidic residues directly 22 partake in voltage-sensitive activation, with their negative charges collectively 23 constituting the observed gating charges. Voltage-sensitive outer pore movement 24 is titratable by extracellular pH and is allosterically coupled to channel 25 activation, likely by influencing the upper gate in the ion selectivity 26 filter. Elucidating this unorthodox voltage-gating process provides a mechanistic 27 foundation for understanding polymodal gating and opens the door to novel 28 approaches regulating channel activity for pain managements. 29 30When the lipid bilayer emerged to enclose living cells more than three billion years 31 ago 1 , this diffusion barrier between cytoplasmic milieu and external environment 32 allowed the establishment of transmembrane ion concentration gradients, which in 33 turn yielded a transmembrane electric potential. Such a membrane potential (Vm) has 34 been widely utilized in cellular signaling: voltage-gated ion channels alter Vm to elicit 35 electric signals for rapid communications 2,3 ; voltage-sensitive enzymes, e.g., Ci-VSP 4 , 36 couple changes in Vm to the regulation of enzymatic activities and intracellular 37 signaling. For these "classic" voltage-sensing proteins, high sensitivity to voltage (5-38 fold/mV) has been attributed to a conserved, densely charged "voltage-sensor" 39 domain in the transmembrane region 5 . Other membrane proteins-including G 40 protein-coupled receptors 6 , ion channels and transporters 7 -have also evolved to take 41 cues from Vm to perform their biological functions. Understanding the origin and 42 operation of voltage sensitivity in these membrane proteins is of fundamental 43 importance. 44 to estimate q, for which voltage dependence was measured at low open probabilities. 89 However, the voltage-driven transition of TRPV1 is allosterically coupled to 90 activation gating 22 , with the channel open probability approaching a stable level at 91 deep hyperpolarization (Fig. 1e and Extended Data Fig. 1) that reflected the 92 equilibrium of activation gate between the closed and open state 23 . To better estimate 93 q, we first calculated the derivative of the mean log open probability with respect to 94 voltage and fitted the Boltzmann smoothing function of voltage dependence of mean 95 log open probability (see Methods for details) (Fig. 1f), as was previously performed 96 on the allosteric large co...

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Section: Identifying the Voltage-dependent Transitionsupporting

confidence: 61%

“…Small cations such as proton, Na + and Mg 2+ /Ba 2+ /Ni 2+ /Gd 3+ , as well as large peptide toxins such as DkTx, RhTx and BmP01 all bind to this region to exert their strong gating effects 48 . Capsaicin activation has been recently found to affect the outer pore 44 . Heat also induces large conformational changes of the outer pore 50 .…”

Section: Discussionmentioning

confidence: 99%

An unorthodox mechanism underlying voltage sensitivity of TRPV1 ion channel

Yang

Lee

et al. 2020

Preprint

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“…Key atomic interactions include two hydrogen bonds-formed between the amide group in the capsaicin neck and the hydroxyl group of T551 on the S4 segment of the TRPV1 channel (using mTRPV1 amino acid number) and between the hydroxyl group in the capsaicin head and the carboxyl group of E571 on the S4-S5 linker-as well as extensive van der Waals (VDW) interactions including those by the capsaicin tail. Accuracy of the current capsaicin binding model has been satisfactorily confirmed by studies of the structural correlates of deactivation kinetics (Kumar et al, 2016), the activation conformational wave in TRPV1 channels triggered by capsaicin binding (Yang et al, 2018), the evolutionary drive for the tree shrew's insensitivity to spiciness (Han et al, 2018), and the rational designs of vanilloid-sensitive TRPV2 channel mutants (Yang, Vu, Yarov-Yarovoy, & Zheng, 2016;Zhang et al, 2016).…”

Section: Introductionmentioning

confidence: 82%

“…Indeed, the average Rosetta energy for hydrogen bond of the top models was substantial at this position(Figure 6c, bottom panel). This interaction, if formed, would contribute to the stabilization of ligand binding and, given the role played by the S6 segment in activation of the TRPV1 channel(Yang et al, 2018;Zheng & Ma, 2014), may even represent a new way to stabilize the channel's open conformation. Overall, our structural modelling results confirmed that zingerone is much less stable inside the ligand-binding pocket and, as a result, a weak agonist for the TRPV1 channel.…”

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confidence: 99%

Structural mechanisms underlying activation of TRPV1 channels by pungent compounds in gingers

Yin

Dong

et al. 2019

British J Pharmacology

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Background and Purpose Like chili peppers, gingers produce pungent stimuli by a group of vanilloid compounds that activate the nociceptive transient receptor potential vanilloid 1 (TRPV1) ion channel. How these compounds interact with TRPV1 remains unclear. Experimental Approach We used computational structural modelling, functional tests (electrophysiology and calcium imaging), and mutagenesis to investigate the structural mechanisms underlying ligand–channel interactions. Key Results The potency of three principal pungent compounds from ginger —shogaol, gingerol, and zingerone—depends on the same two residues in the TRPV1 channel that form a hydrogen bond with the chili pepper pungent compound, capsaicin. Computational modelling revealed binding poses of these ginger compounds similar to those of capsaicin, including a “head‐down tail‐up” orientation, two specific hydrogen bonds, and important contributions of van der Waals interactions by the aliphatic tail. Our study also identified a novel horizontal binding pose of zingerone that allows it to directly interact with the channel pore when bound inside the ligand‐binding pocket. These observations offer a molecular level explanation for how unique structures in the ginger compounds affect their channel activation potency. Conclusions and Implications Mechanistic insights into the interactions of ginger compounds and the TRPV1 cation channel should help guide drug discovery efforts to modulate nociception.

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“…In addition to the identifying topological features, a number of TRPV1 structures in different states have been determined, which have provided significant insight into the molecular basis for TRPV1 chemical activation (19)(20)(21). Canonical TRPV1 vanilloid compounds, like the pungent agonist capsaicin, bind to the S1-S4 domain which couples with the PD to open the lower and upper gates of the channel (22), thereby initiating signal transduction. The cryo-EM determined vanilloid binding site (19)(20)(21) is consistent with previous studies (23)(24)(25)(26)(27)(28), which identified residues in the S3 and S4 helices of the TRPV1 S1-S4 domain as central for capsaicin activation.…”

Section: Introductionmentioning

confidence: 99%

Evidence that the TRPV1 S1-S4 Membrane Domain Contributes to Thermosensing

Kim

Sisco

Hilton

et al. 2019

Preprint

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Sensing and responding to temperature is crucial in biology. The TRPV1 ion channel is a well-studied heat-sensing receptor that is also activated by vanilloid compounds including capsaicin. Despite significant interest, the molecular underpinnings of thermosensing have remained elusive. The TRPV1 S1-S4 membrane domain couples chemical ligand binding to the pore domain during channel gating.However, the role of the S1-S4 domain in thermosensing is unclear. Evaluation of the isolated human TRPV1 S1-S4 domain by solution NMR, Far-UV CD, and intrinsic fluorescence shows that this domain undergoes a non-denaturing temperature-dependent transition with a high thermosensitivity. Further NMR characterization of the temperature-dependent conformational changes suggests the contribution of the S1-S4 domain to thermosensing shares features with known coupling mechanisms between this domain with ligand and pH activation. Taken together, this study shows that the TRPV1 S1-S4 domain contributes to TRPV1 temperature-dependent activation.

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The conformational wave in capsaicin activation of transient receptor potential vanilloid 1 ion channel

Cited by 65 publications

References 67 publications

An unorthodox mechanism underlying voltage sensitivity of TRPV1 ion channel

An unorthodox mechanism underlying voltage sensitivity of TRPV1 ion channel

Structural mechanisms underlying activation of TRPV1 channels by pungent compounds in gingers

Evidence that the TRPV1 S1-S4 Membrane Domain Contributes to Thermosensing

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