Abstract
The capsaicin-, heat-, and proton-activated ion channel TRPV1, a member of the transient receptor potential cation channel family is a polymodal nociceptor. For almost a decade, TRPV1 has been explored by the pharmaceutical industry as a potential target for example for pain conditions. Antagonists which block TRPV1 activation by capsaicin, heat, and protons were developed by a number of pharmaceutical companies. The unexpected finding of hyperthermia as an on-target side effect in clinical studies using polymodal TRPV1 antagonists has prompted companies to search for ways to circumvent hyperthermia, for example by the development of modality-selective antagonists. The significant lack of consistency of the pharmacology of many TRPV1 antagonists across different species has been a further obstacle. JYL-1421 for example was shown to block capsaicin and heat responses in human and monkey TRPV1 while it was largely ineffective in blocking heat responses in rat TRPV1. These findings suggested structural dissimilarities between different TRPV1 species relevant for small compound antagonism for example of heat activation. Using a chimeric approach (human and rat TRPV1) in combination with a novel FLIPR-based heat activation assay and patch-clamp electrophysiology we have identified the pore region as being strongly linked to the observed species differences. We demonstrate that by exchanging the pore domains JYL-1421, which is modality-selective in rat can be made modality-selective in human TRPV1 and vice-versa.
Highlights
Species-dependent pharmacology is an obstacle for TRPV1 antagonist development
Using a chimeric approach in combination with a novel FLIPR-based heat activation assay and patchclamp electrophysiology we have identified the pore region as being strongly linked to the observed species differences
Development and Validation of FLIPR Heat Activation Assay for TRPV1—As a consequence of the development of hyperthermia in clinical trials using polymodal TRPV1 antagonists, the pharmaceutical industry has started to search for “non-hyperthermic” antagonists
Summary
Species-dependent pharmacology is an obstacle for TRPV1 antagonist development. Results: By exchanging the pore domains TRPV1 antagonist JYL-1421, which is modality-selective in rTRPV1 can be made modality-selective in hTRPV1 and vice-versa. The capsaicin-, heat-, and proton-activated ion channel TRPV1, a member of the transient receptor potential cation channel family is a polymodal nociceptor. Antagonists which block TRPV1 activation by capsaicin, heat, and protons were developed by a number of pharmaceutical companies. JYL-1421 for example was shown to block capsaicin and heat responses in human and monkey TRPV1 while it was largely ineffective in blocking heat responses in rat TRPV1 These findings suggested structural dissimilarities between different TRPV1 species relevant for small compound antagonism for example of heat activation. Using a chimeric approach (human and rat TRPV1) in combination with a novel FLIPR-based heat activation assay and patchclamp electrophysiology we have identified the pore region as being strongly linked to the observed species differences. The superfamily of transient receptor potential (TRP) cation channels plays a major role in sensory transduction includ-
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