Abstract
TRPA1 (transient receptor potential ankyrin 1) is an ion channel expressed in the termini of sensory neurons and is activated in response to a broad array of noxious exogenous and endogenous thiol-reactive compounds, making it a crucial player in chemical nociception. A number of conserved cysteine residues on the N-terminal domain of the channel have been identified as critical for sensing these electrophilic pungent chemicals, and our recent EM structure with modeled domains predicts that these cysteines form a ligand-binding pocket, allowing for the possibility of disulfide bonding between the cysteine residues. Here, we present a comprehensive mass spectrometry investigation of the in vivo disulfide bonding conformation and in vitro reactivity of 30 of the 31 cysteine residues in the TRPA1 ion channel. Four disulfide bonds were detected in the in vivo TRPA1 structure: Cys-666-Cys-622, Cys-666-Cys-463, Cys-622-Cys-609, and Cys-666-Cys-193. All of the cysteines detected were reactive to N-methylmaleimide (NMM) in vitro, with varying degrees of labeling efficiency. Comparison of the ratio of the labeling efficiency at 300 μM versus 2 mM NMM identified a number of cysteine residues that were outliers from the mean labeling ratio, suggesting that protein conformation changes rendered these cysteines either more or less protected from labeling at the higher NMM concentrations. These results indicate that the activation mechanism of TRPA1 may involve N-terminal conformation changes and disulfide bonding between critical cysteine residues.
Highlights
The TRPA1 ion channel is activated by electrophilic compounds and plays a role in chemical nociception
The yeast expression system is ideal for this experiment because 1) TRP channels can be overexpressed in amounts adequate for obtaining a high sequence coverage in MS experiments, 2) the system preserves the function of TRP channels similar to those seen for mammalian cell lines and is appropriate for probing activation and gating mechanisms [19, 20], 3) S. cerevisiae cells have significant homology to mammalian cells with regard to redox signaling and regulation and have been widely used as a model system for redox-related studies [21,22,23,24,25], and 4) structural analysis of the TRPV1 and TRPA1 ion channels by electron microscopy has confirmed the structural integrity of the proteins after expression in yeast [12, 26]
TRPA1 migrated on the nonreducing gel in a single band at a molecular weight expected for a monomer, ruling out the possibility of intersubunit disulfide bonds
Summary
The TRPA1 ion channel is activated by electrophilic compounds and plays a role in chemical nociception. Comparison of the ratio of the labeling efficiency at 300 M versus 2 mM NMM identified a number of cysteine residues that were outliers from the mean labeling ratio, suggesting that protein conformation changes rendered these cysteines either more or less protected from labeling at the higher NMM concentrations These results indicate that the activation mechanism of TRPA1 may involve N-terminal conformation changes and disulfide bonding between critical cysteine residues. We present evidence for ligand-induced conformational changes that alter the susceptibility of portions of the channel’s N terminus to covalent modification These results provide a structural and regulatory framework for understanding the activation of the TRPA1 channel in response to electrophilic and oxidizing agonists
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
