TRPV1 activation power can switch an action mode for its polypeptide ligands

Nikolaev, Maxim V.; Дорофеева, Н. А.; Komarova, Margarita S.; Korolkova, Yuliya V.; Andreev, Yaroslav A.; Мошарова, И. В.; Grishin, Eugene V.; Tikhonov, Denis B.; Kozlov, Sergey A.

doi:10.1371/journal.pone.0177077

Cited by 32 publications

(49 citation statements)

References 39 publications

(48 reference statements)

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“…All three toxins were shown to be partial, but potent, antagonists, with APHC3 displaying the highest level of inhibition (71% of 3 µM capsaicin), and the lowest IC 50 value (18 nM) [ 78 ]. As is common with molecules presenting with partial antagonistic characteristics, a bimodal mechanism of action of APHC on TRPV1 activity was recently described [ 79 ]. In the presence of saturating concentrations of capsaicin (3 µM), APHC acts as an inhibitor, whereas current produced by very low concentrations (3 nM) of capsaicin are potentiated in the presence of the toxin [ 79 ].…”

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

“…As is common with molecules presenting with partial antagonistic characteristics, a bimodal mechanism of action of APHC on TRPV1 activity was recently described [ 79 ]. In the presence of saturating concentrations of capsaicin (3 µM), APHC acts as an inhibitor, whereas current produced by very low concentrations (3 nM) of capsaicin are potentiated in the presence of the toxin [ 79 ]. Interestingly, APHC1 showed the highest levels of potentiation, showing an increase of 250% of the capsaicin - evoked current [ 79 ].…”

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

“…In the presence of saturating concentrations of capsaicin (3 µM), APHC acts as an inhibitor, whereas current produced by very low concentrations (3 nM) of capsaicin are potentiated in the presence of the toxin [ 79 ]. Interestingly, APHC1 showed the highest levels of potentiation, showing an increase of 250% of the capsaicin - evoked current [ 79 ]. Furthermore, APHC3 potentiated TRPV1 activation in response to slightly acidic (pH 6.2) solution, whereas no inhibition was observed at highly acidic (pH 4.5) solutions [ 79 ].…”

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

“…Interestingly, APHC1 showed the highest levels of potentiation, showing an increase of 250% of the capsaicin - evoked current [ 79 ]. Furthermore, APHC3 potentiated TRPV1 activation in response to slightly acidic (pH 6.2) solution, whereas no inhibition was observed at highly acidic (pH 4.5) solutions [ 79 ]. Likewise, low concentrations of the synthetic molecule 2-aminoethoxydiphenyl borate (2APB) were subject to APHC potentiation, while high concentrations were unaffected [ 79 ].…”

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

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Animal Toxins Providing Insights into TRPV1 Activation Mechanism

Geron

Hazan

Priel

2017

Toxins

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Beyond providing evolutionary advantages, venoms offer unique research tools, as they were developed to target functionally important proteins and pathways. As a key pain receptor in the nociceptive pathway, transient receptor potential vanilloid 1 (TRPV1) of the TRP superfamily has been shown to be a target for several toxins, as a way of producing pain to deter predators. Importantly, TRPV1 is involved in thermoregulation, inflammation, and acute nociception. As such, toxins provide tools to understand TRPV1 activation and modulation, a critical step in advancing pain research and the development of novel analgesics. Indeed, the phytotoxin capsaicin, which is the spicy chemical in chili peppers, was invaluable in the original cloning and characterization of TRPV1. The unique properties of each subsequently characterized toxin have continued to advance our understanding of functional, structural, and biophysical characteristics of TRPV1. By building on previous reviews, this work aims to provide a comprehensive summary of the advancements made in TRPV1 research in recent years by employing animal toxins, in particular DkTx, RhTx, BmP01, Echis coloratus toxins, APHCs and HCRG21. We examine each toxin’s functional aspects, behavioral effects, and structural features, all of which have contributed to our current knowledge of TRPV1. We additionally discuss the key features of TRPV1’s outer pore domain, which proves to be the target of the currently discussed toxins.

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Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

Section: Analgesic Polypeptide Heteractis Crispa mentioning

confidence: 99%

See 2 more Smart Citations

Animal Toxins Providing Insights into TRPV1 Activation Mechanism

Geron

Hazan

Priel

2017

Toxins

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“…The list of hypothermia‐inducing compounds includes several small‐molecule antagonists, viz., 5′‐iodo‐resiniferatoxin (5′‐I‐RTX), Amgen's AMG7905 and AMG8562, Abbott Laboratories’ A‐425619, AbbVie's Compound 3 and Schwarz Pharma's JYL1421, as well as at least 1 polypeptide antagonist, APHC3 . In agreement with the fact that TRPV1 agonists also cause hypothermia, several hypothermia‐causing TRPV1 antagonists, viz., 5′‐I‐RTX and Compound 3, were found to be partial agonists, whereas the partial antagonist APHC3 was found to potentiate the effects of low concentrations of capsaicin . However, several other hypothermia‐inducing TRPV1 antagonists, viz., A‐425619, AMG7905 and AMG8562 and JYL1421, showed no TRPV1 agonistic or capsaicin‐potentiating activity.…”

Section: Introductionmentioning

confidence: 99%

TRPV1 antagonists that cause hypothermia, instead of hyperthermia, in rodents: Compounds’ pharmacological profiles, in vivo targets, thermoeffectors recruited and implications for drug development

et al. 2018

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AimThermoregulatory side effects hinder the development of transient receptor potential vanilloid‐1 (TRPV1) antagonists as new painkillers. While many antagonists cause hyperthermia, a well‐studied effect, some cause hypothermia. The mechanisms of this hypothermia are unknown and were studied herein.MethodsTwo hypothermia‐inducing TRPV1 antagonists, the newly synthesized A‐1165901 and the known AMG7905, were used in physiological experiments in rats and mice. Their pharmacological profiles against rat TRPV1 were studied in vitro.ResultsAdministered peripherally, A‐1165901 caused hypothermia in rats by either triggering tail‐skin vasodilation (at thermoneutrality) or inhibiting thermogenesis (in the cold). A‐1165901‐induced hypothermia did not occur in rats with desensitized (by an intraperitoneal dose of the TRPV1 agonist resiniferatoxin) sensory abdominal nerves. The hypothermic responses to A‐1165901 and AMG7905 (administered intragastrically or intraperitoneally) were absent in Trpv1 −/− mice, even though both compounds evoked pronounced hypothermia in Trpv1 +/+ mice. In vitro, both A‐1165901 and AMG7905 potently potentiated TRPV1 activation by protons, while potently blocking channel activation by capsaicin.Conclusion TRPV1 antagonists cause hypothermia by an on‐target action: on TRPV1 channels on abdominal sensory nerves. These channels are tonically activated by protons and drive the reflectory inhibition of thermogenesis and tail‐skin vasoconstriction. Those TRPV1 antagonists that cause hypothermia further inhibit these cold defences, thus decreasing body temperature.SignificanceTRPV1 antagonists (of capsaicin activation) are highly unusual in that they can cause both hyper‐ and hypothermia by modulating the same mechanism. For drug development, this means that both side effects can be dealt with simultaneously, by minimizing these compounds’ interference with TRPV1 activation by protons.

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Potentiation and Block of ASIC1a by Memantine

et al. 2017

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Acid-sensing ion channels (ASICs) are modulated by various classes of ligands, including the recently described hydrophobic monoamines, which inhibit and potentiate ASICs in a subunit-specific manner. In particular, memantine inhibits ASIC1a and potentiates ASIC2a homomers. The aim of the present work was to characterize action mechanism of memantine on recombinant ASIC1a expressed in CHO (Chinese hamster ovary) cells. We have demonstrated that effect of memantine on ASIC1a strongly depends on membrane voltage, conditioning pH value and application protocol. When applied simultaneously with activating acidification at hyperpolarized voltages, memantine caused the strongest inhibition. Surprisingly, application of memantine between ASIC1a activations at zero voltage caused significant potentiation. Analysis of the data suggests that memantine produces two separate effects, voltage-dependent open-channel block and shift of steady-state desensitization curve to more acidic values. Putative binding sites are discussed based on the computer docking of memantine to the acidic pocket and the pore region.

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TRPV1 activation power can switch an action mode for its polypeptide ligands

Cited by 32 publications

References 39 publications

Animal Toxins Providing Insights into TRPV1 Activation Mechanism

Animal Toxins Providing Insights into TRPV1 Activation Mechanism

TRPV1 antagonists that cause hypothermia, instead of hyperthermia, in rodents: Compounds’ pharmacological profiles, in vivo targets, thermoeffectors recruited and implications for drug development

Potentiation and Block of ASIC1a by Memantine

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