RESUMO
Voltage-gated potassium channels are composed of four subunits. Voltage-dependent activation of these channels consists of a depolarization-triggered series of charge-carrying steps that occur in each subunit. These major charge-carrying steps are followed by cooperative step(s) that lead to channel opening. Unlike the late cooperative steps, the major charge-carrying steps have been proposed to occur independently in each of the channel subunits. In this paper, we examine this further. We showed earlier that the two major charge-carrying steps are associated with two sequential outward transmembrane movements of the charged S4 segment. We now use voltage clamp fluorometry to monitor these S4 movements in individual subunits of heterotetrameric channels. In this way, we estimate the influence of one subunit's S4 movement on another's when the energetics of their transmembrane movements differ. Our results show that the first S4 movement occurs independently in each subunit, while the second occurs cooperatively. At least part of the cooperativity appears to be intrinsic to the second S4 charge-carrying rearrangement. Such cooperativity in gating of voltage-dependent channels has great physiological relevance since it can affect both action potential threshold and rate of propagation.
Assuntos
Ativação do Canal Iônico/fisiologia , Canais de Potássio/química , Canais de Potássio/genética , Animais , Estimulação Elétrica , Eletroquímica , Fluorometria , Mutagênese Sítio-Dirigida , Oócitos/fisiologia , Técnicas de Patch-Clamp , Canais de Potássio/metabolismo , Conformação Proteica , Superfamília Shaker de Canais de Potássio , XenopusRESUMO
Voltage-gated ion channels underlie the generation of action potentials and trigger neurosecretion and muscle contraction. These channels consist of an inner pore-forming domain, which contains the ion permeation pathway and elements of its gates, together with four voltage-sensing domains, which regulate the gates. To understand the mechanism of voltage sensing it is necessary to define the structure and motion of the S4 segment, the portion of each voltage-sensing domain that moves charged residues across the membrane in response to voltage change. We have addressed this problem by using fluorescence resonance energy transfer as a spectroscopic ruler to determine distances between S4s in the Shaker K+ channel in different gating states. Here we provide evidence consistent with S4 being a tilted helix that twists during activation. We propose that helical twist contributes to the movement of charged side chains across the membrane electric field and that it is involved in coupling voltage sensing to gating.
Assuntos
Ativação do Canal Iônico , Canais de Potássio/química , Animais , Eletroquímica , Mutagênese Sítio-Dirigida , Canais de Potássio/genética , Canais de Potássio/metabolismo , Conformação Proteica , Superfamília Shaker de Canais de Potássio , Espectrometria de Fluorescência/métodos , XenopusRESUMO
We have acquired structural evidence that two components evident previously in the depolarization-evoked gating currents from voltage-gated Shaker K+ channels have their origin in sequential, two-step outward movements of the S4 protein segments. A point mutation greatly destabilizes the "fully retracted" state of S4 transmembrane translocation, causing instead an intermediate state to predominate at resting potentials. This state is distinguishable topologically and fluorometrically. That a point mutation effectively excludes half the range of S4 motion from physiological voltages suggests that the diverse sensitivities among voltage-gated channels might reflect not only differences in S4 valence, but also displacement. Existence of an intermediate subunit state helps explain why modeling channel activation has required positing greater than four closed states.
Assuntos
Ativação do Canal Iônico/fisiologia , Canais de Potássio/química , Canais de Potássio/genética , Sequência de Aminoácidos , Animais , Estimulação Elétrica , Metanossulfonato de Etila/análogos & derivados , Metanossulfonato de Etila/farmacologia , Corantes Fluorescentes , Indicadores e Reagentes/farmacologia , Ativação do Canal Iônico/efeitos dos fármacos , Mutagênese , Oócitos/fisiologia , Técnicas de Patch-Clamp , Conformação Proteica , Estrutura Terciária de Proteína , Superfamília Shaker de Canais de PotássioRESUMO
In response to membrane depolarization, voltage-gated ion channels undergo a structural rearrangement that moves charges or dipoles in the membrane electric field and opens the channel-conducting pathway. By combination of site-specific fluorescent labeling of the Shaker potassium channel protein with voltage clamping, this gating conformational change was measured in real time. During channel activation, a stretch of at least seven amino acids of the putative transmembrane segment S4 moved from a buried position into the extracellular environment. This movement correlated with the displacement of the gating charge, providing physical evidence in support of the hypothesis that S4 is the voltage sensor of voltage-gated ion channels.
Assuntos
Ativação do Canal Iônico , Canais de Potássio/química , Conformação Proteica , Sequência de Aminoácidos , Animais , Corantes , Fluorescência , Corantes Fluorescentes , Potenciais da Membrana , Microscopia Confocal , Dados de Sequência Molecular , Oócitos , Técnicas de Patch-Clamp , Fragmentos de Peptídeos , Canais de Potássio/metabolismo , Rodaminas , XenopusRESUMO
In this paper a variety of mercurials, including a pCMB-nitroxide analogue, were used to study urea transport in human red cell ghosts. It was determined that the rate of inhibition for pCMBS, pCMB, pCMB-nitroxide, and chlormerodrin extended over four orders of magnitude consistent with their measured oil/water partition coefficients. From these results, we concluded that a significant hydrophobic barrier limits access to the urea inhibition site, suggesting that the urea site is buried in the bilayer or in a hydrophobic region of the transporter. In contrast, the rate of water inhibition by the mercurials ranged by only a factor of four and did not correlate with their hydrophobicities. Thus, the water inhibition site may be more directly accessible via the aqueous phase. Under conditions that leave water transport unaffected, we determined that < or = 32,000 labeled sites per cell corresponded to complete inhibition of urea transport. This rules out major transmembrane proteins such as band 3, the glucose carrier, and CHIP28 as candidates for the urea transporter. In contrast, this result is consistent with the Kidd (Jk) antigen being the urea transporter with an estimated 14,000 copies per cell. From the experimental number of urea sites, a turnover number between 2-6 x 10(6) sec-1 at 22 degrees C is calculated suggesting a channel mechanism.