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Full-Text Articles in Medical Anatomy
Gating Charge Immobilization In Kv4.2 Channels: The Basis Of Closed-State Inactivation., Kevin Dougherty, Jose A De Santiago-Castillo, Manuel Covarrubias
Gating Charge Immobilization In Kv4.2 Channels: The Basis Of Closed-State Inactivation., Kevin Dougherty, Jose A De Santiago-Castillo, Manuel Covarrubias
Department of Pathology, Anatomy, and Cell Biology Faculty Papers
Kv4 channels mediate the somatodendritic A-type K+ current (I(SA)) in neurons. The availability of functional Kv4 channels is dynamically regulated by the membrane potential such that subthreshold depolarizations render Kv4 channels unavailable. The underlying process involves inactivation from closed states along the main activation pathway. Although classical inactivation mechanisms such as N- and P/C-type inactivation have been excluded, a clear understanding of closed-state inactivation in Kv4 channels has remained elusive. This is in part due to the lack of crucial information about the interactions between gating charge (Q) movement, activation, and inactivation. To overcome this limitation, we engineered a charybdotoxin …
Functionally Active T1-T1 Interfaces Revealed By The Accessibility Of Intracellular Thiolate Groups In Kv4 Channels., Guangyu Wang, Mohammad Shahidullah, Carmen A Rocha, Candace Strang, Paul J Pfaffinger, Manuel Covarrubias
Functionally Active T1-T1 Interfaces Revealed By The Accessibility Of Intracellular Thiolate Groups In Kv4 Channels., Guangyu Wang, Mohammad Shahidullah, Carmen A Rocha, Candace Strang, Paul J Pfaffinger, Manuel Covarrubias
Department of Pathology, Anatomy, and Cell Biology Faculty Papers
Gating of voltage-dependent K(+) channels involves movements of membrane-spanning regions that control the opening of the pore. Much less is known, however, about the contributions of large intracellular channel domains to the conformational changes that underlie gating. Here, we investigated the functional role of intracellular regions in Kv4 channels by probing relevant cysteines with thiol-specific reagents. We find that reagent application to the intracellular side of inside-out patches results in time-dependent irreversible inhibition of Kv4.1 and Kv4.3 currents. In the absence or presence of Kv4-specific auxiliary subunits, mutational and electrophysiological analyses showed that none of the 14 intracellular cysteines is …