Proline substitutions in the ASIC1 β11-12 linker slow desensitization.

Desensitization is a prominent feature of nearly all ligand-gated ion channels. Acid-sensing ion channels (ASICs) undergo desensitization within hundreds of milliseconds to seconds upon continual extracellular acidification. The ASIC mechanism of desensitization is primarily due to the isomerization or "flipping" of a short linker joining the 11th and 12th β sheets in the extracellular domain. In the resting and active states this β11-12 linker adopts an "upward" conformation while in the desensitized conformation the linker assumes a "downward" state. It is unclear if a single linker adopting the downward state is sufficient to desensitize the entire channel, or if all three are needed or some more complex scheme. To accommodate this downward state, specific peptide bonds within the linker adopt either trans-like or cis-like conformations. Since proline-containing peptide bonds undergo cis-trans isomerization very slowly, we hypothesized that introducing proline residues in the linker may slow or even abolish ASIC desensitization, potentially providing a valuable research tool. Proline substitutions in the chicken ASIC1 β11-12 linker (L414P and Y416P) slowed desensitization decays approximately 100- to 1000-fold as measured in excised patches. Both L414P and Y416P shifted the steady-state desensitization curves to more acidic pH values while activation curves and ion selectivity were largely unaffected (except for a left-shifted activation pH of L414P). To investigate the functional stoichiometry of desensitization in the trimeric ASIC, we created families of L414P and Y416P concatemers with zero, one, two, or three proline substitutions in all possible configurations. Introducing one or two L414P or Y416P substitutions only slightly attenuated desensitization, suggesting that conformational changes in the single remaining faster wild-type subunits were sufficient to desensitize the channel. These data highlight the unusual cis-trans isomerization mechanism of ASIC desensitization and support a model where ASIC desensitization requires only a single subunit.