Stephen J. Korn

Contribution of the selectivity filter to inactivation in potassium channels.

Voltage-gated K+ channels exhibit a slow inactivation process, which becomes an important influence on the rate of action potential repolarization during prolonged or repetitive depolarization. During slow inactivation, the outer mouth of the permeation pathway undergoes a conformational change. We report here that during the slow inactivation process, the channel progresses through at least three permeation states; from the initial open state that is highly selective for K+, the channel enters a state that is less permeable to K+ and more permeable to Na+, and then proceeds to a state that is non-conducting. Similar results were obtained in three different voltage-gated K+ channels: Kv2.1, a channel derived from Shaker (Shaker Delta A463C), and a chimeric channel derived from Kv2.1 and Kv1.3 that displays classical C-type inactivation. The change in selectivity displayed both voltage- and time-dependent properties of slow inactivation and was observed with K+ on either side of the channel. Elevation of internal [K+] inhibited Na+ conduction through the inactivating channel in a concentration-dependent manner. These results indicate that the change in selectivity filter function is an integral part of the slow inactivation mechanism, and argue against the hypothesis that the inactivation gate is independent from the selectivity filter. Thus, these data suggest that the selectivity filter is itself the inactivation gate.

Modulation of C-Type Inactivation by K+ at the Potassium Channel Selectivity Filter

With prolonged or repetitive activation, voltage-gated K+ channels undergo a slow (C-type) inactivation mechanism, which decreases current flow through the channel. Previous observations suggest that C-type inactivation results from a localized constriction in the outer mouth of the channel pore and that the rate of inactivation is controlled by the-rate at which K+ leaves an unidentified binding site in the pore. We have functionally identified two K+ binding sites in the conduction pathway of a chimeric K+ channel that conducts Na+ in the absence of K+. One site has a high affinity for K+ and contributes to the selectivity filter mechanism for K+ over Na+. Another site, external to the high-affinity site, has a lower affinity for K+ and is not involved in channel selectivity. Binding of K+ to the high-affinity binding site slowed inactivation. Binding of cations to the external low-affinity site did not slow inactivation directly but could slow it indirectly, apparently by trapping K+ at the high-affinity site. These data support a model whereby C-type inactivation involves a constriction at the selectivity filter, and the constriction cannot proceed when the selectivity filter is occupied by K+.

[22] - Perforated Patch Recording

Publisher Summary This chapter presents an overview of the perforated patch recording technique. Perforated patch recording differs from standard whole-cell recording in the way electrical access to the cell interior is gained. Both methods begin with the formation of a gigaseal between the recording pipet and cell membrane. With standard whole-cell recording, the low-resistance pathway between pipet and cell interior is made by rupturing the membrane patch, usually by suction. With perforated patch recording, the low-resistance pathway is formed by the incorporation of pores into the membrane patch that are highly selective for small monovalent ions. These pores are established by including the polyene antibiotic, nystatin, in the pipet solution. As with the standard configuration, it is possible to excise a patch of membrane from the perforated patch configuration. This yields a perforated vesicle from which single-channel currents can be recorded. A major disadvantage of perforated patch technique is that the experiments are slower than comparable experiments with whole-cell recording. Moreover, the series resistance is approximately three times greater than that achieved in whole-cell recording under similar conditions.

Prevention of rundown in electrophysiological recording.

Publisher Summary This chapter discusses and evaluates several methods that reduce or avoid the problems presented by whole-cell recording, and are used to prevent rundown in electrophysiological experiments. Cell-attached patch recording usually implies that cytoplasm is maintained on the intracellular surface of the plasma membrane. With this configuration tingle-channel currents are usually observed. However, if channel density is very high or if very large pipettes are used, macroscopic currents may be observed in cell-attached patches. Such currents are modulable by second messengers and do not wash out. These techniques preserve—to varying extents—the integrity of the cytoplasm. Each has its own virtues and pitfalls, and it is unlikely that one method will suffice for all purposes. Usually, the choice of technique involves a compromise between the ability to determine the composition of the intracellular solution and the preservation of the cytoplasm.

Polyunsaturated fatty acids modulates stomatal aperture and two distinct K+ channel currents in guard cells

Regulation of stomatal aperture is critical for both CO2 uptake and water retention by plants. Stomatal opening is produced by osmotic water flow into guard cells, which follows K+ transport across the plasma membrane. We report here that linolenic acid and arachidonic acid, but not several other fatty acids, enhance stomatal opening and inhibit stomatal closing. In patch clamped guard cell protoplasts, linolenic and arachidonic acid rapidly potentiated inward K+ currents and inhibited outward K+ currents, which are carried via distinct K+ channels. These results suggest that certain fatty acids regulate stomatal aperture by modulation of two different K+ channels and may act as second messengers for stimuli that regulate CO2 uptake and water retention by plants.

Control of ion channel expression for patch clamp recordings using an inducible expression system in mammalian cell lines

BackgroundMany molecular studies of ion channel function rely on the ability to obtain high quality voltage clamp recordings using the patch clamp technique. For a variety of channel types studied in mammalian cell heterologous expression systems, the lack of experimenter control over expression levels severely hinders the ability to obtain a high percentage of cells with an expression level suitable for high quality recordings. Moreover, it has been nearly impossible to obtain expression levels in mammalian cells well suited for single channel recordings. We describe here the use of an inducible promoter system in a stably transfected mammalian cell line that produces nearly 100% success in obtaining ion channel expression levels suitable for either whole cell or single ion channel studies.ResultsWe used a tetracycline-regulated expression system to control K+ channel expression in a CHO (Chinese hamster ovary) cell line. Current magnitudes within a reasonably narrow range could be easily and reliably obtained for either macroscopic or single channel recordings. Macroscopic currents of 1 – 2 nA could be obtained in nearly 100% of cells tested. The desired expression level could be obtained within just 2 to 3 hours, and remained stable at room temperature. Very low expression levels of transfected channels could also be obtained, which resulted in a >70% success rate in the ability to record single channel currents from a patch. Moreover, at these low expression levels, it appeared that endogenous channels produced little or no contamination.ConclusionThis approach to controlling ion channel expression is relatively simple, greatly enhances the speed and efficiency with which high quality macroscopic current data can be collected, and makes it possible to easily and reliably record single channel currents in a mammalian cell heterologous expression system. Whereas we demonstrate the ability of this system to control expression levels of voltage-gated K+ channels, it should be applicable to all other channel types that express well in mammalian expression systems.

Influence of pore residues on permeation properties in the Kv2.1 potassium channel. Evidence for a selective functional interaction of K+ with the outer vestibule

The Kv2.1 potassium channel contains a lysine in the outer vestibule (position 356) that markedly reduces open channel sensitivity to changes in external [K+]. To investigate the mechanism underlying this effect, we examined the influence of this outer vestibule lysine on three measures of K+ and Na+ permeation. Permeability ratio measurements, measurements of the lowest [K+] required for interaction with the selectivity filter, and measurements of macroscopic K+ and Na+ conductance, were all consistent with the same conclusion: that the outer vestibule lysine in Kv2.1 interferes with the ability of K+ to enter or exit the extracellular side of the selectivity filter. In contrast to its influence on K+ permeation properties, Lys 356 appeared to be without effect on Na+ permeation. This suggests that Lys 356 limited K+ flux by interfering with a selective K+ binding site. Combined with permeation studies, results from additional mutagenesis near the external entrance to the selectivity filter indicated that this site was located external to, and independent from, the selectivity filter. Protonation of a naturally occurring histidine in the same outer vestibule location in the Kv1.5 potassium channel produced similar effects on K+ permeation properties. Together, these results indicate that a selective, functional K+ binding site (e.g., local energy minimum) exists in the outer vestibule of voltage-gated K+ channels. We suggest that this site is the location of K+ hydration/dehydration postulated to exist based on the structural studies of KcsA. Finally, neutralization of position 356 enhanced outward K+ current magnitude, but did not influence the ability of internal K+ to enter the pore. These data indicate that in Kv2.1, exit of K+ from the selectivity filter, rather than entry of internal K+ into the channel, limits outward current magnitude. We discuss the implications of these findings in relation to the structural basis of channel conductance in different K+ channels.

Effect of external pH on activation of the Kv1.5 potassium channel.

We studied the mechanism by which external acidification from pH 7.3 to 6.8 reduced current magnitude in the Kv1.5 potassium channel. At physiological external [K(+)], a shift in the voltage-dependence of activation was entirely responsible for the acidification-induced decrease in Kv1.5 current magnitude (pK = 7.15). Elevation of external [Ca(2+)] or [Mg(2+)] identically shifted activation curves to the right and identically shifted the pH-sensitivity of the activation curves to more acidic values. Similar observations were made with the Kv2.1 K(+) channel, except that the pK for the activation shift was out of the physiological range. These data are consistent with a mechanism by which acidification shifted activation via modification of a local surface potential. Elimination of eight positive charges within the outer vestibule of the conduction pathway had no effect on the voltage-dependence of activation at pH 7.3 or higher, which suggested that sites exposed to the conduction pathway within the outer vestibule did not directly contribute to the relevant local surface potential. However, mutations at position 487 (within the conduction pathway) displaced the pK of the pH-sensitive shift in activation, such that the sensitivity of Kv1.5 current to physiologically relevant changes in pH was reduced or eliminated. These results suggest that, among voltage-gated K(+) channels, activation in Kv1.5 is uniquely sensitive to physiologically relevant changes in pH because the pK for the sites that contribute to the local surface potential effect is near pH 7. Moreover, the pK for the activation shift depends not only on the nature of the sites involved but also on structural orientation conferred, in part, by at least one residue within the conduction pathway.

Two mechanisms of K(+)-dependent potentiation in Kv2.1 potassium channels.

Elevation of external [K(+)] potentiates outward K(+) current through several voltage-gated K(+) channels. This increase in current magnitude is paradoxical in that it occurs despite a significant decrease in driving force. We have investigated the mechanisms involved in K(+)-dependent current potentiation in the Kv2.1 K(+) channel. With holding potentials of -120 to -150 mV, which completely removed channels from the voltage-sensitive inactivated state, elevation of external [K(+)] up to 10 mM produced a concentration-dependent increase in outward current magnitude. In the absence of inactivation, currents were maximally potentiated by 38%. At more positive holding potentials, which produced steady-state inactivation, K(+)-dependent potentiation was enhanced. The additional K(+)-dependent potentiation (above 38%) at more positive holding potentials was precisely equal to a K(+)-dependent reduction in steady-state inactivation. Mutation of two lysine residues in the outer vestibule of Kv2.1 (K356 and K382), to smaller, uncharged residues (glycine and valine, respectively), completely abolished K(+)-dependent potentiation that was not associated with inactivation. These mutations did not influence steady-state inactivation or the K(+)-dependent potentiation due to reduction in steady-state inactivation. These results demonstrate that K(+)-dependent potentiation can be completely accounted for by two independent mechanisms: one that involved the outer vestibule lysines and one that involved K(+)-dependent removal of channels from the inactivated state. Previous studies demonstrated that the outer vestibule of Kv2.1 can be in at least two conformations, depending on the occupancy of the selectivity filter by K(+) (Immke, D., M. Wood, L. Kiss, and S. J. Korn. 1999. J. Gen. Physiol. 113:819-836; Immke, D., and S. J. Korn. 2000. J. Gen. Physiol. 115:509-518). This change in conformation was functionally defined by a change in TEA sensitivity. Similar to the K(+)-dependent change in TEA sensitivity, the lysine-dependent potentiation depended primarily (>90%) on Lys-356 and was enhanced by lowering initial K(+) occupancy of the pore. Furthermore, the K(+)-dependent changes in current magnitude and TEA sensitivity were highly correlated. These results suggest that the previously described K(+)-dependent change in outer vestibule conformation underlies the lysine-sensitive, K(+)-dependent potentiation mechanism.

Control of outer vestibule dynamics and current magnitude in the Kv2.1 potassium channel.

In Kv2.1 potassium channels, changes in external [K+] modulate current magnitude as a result of a K+-dependent interconversion between two outer vestibule conformations. Previous evidence indicated that outer vestibule conformation (and thus current magnitude) is regulated by the occupancy of a selectivity filter binding site by K+. In this paper, we used the change in current magnitude as an assay to study how the interconversion between outer vestibule conformations is controlled. With 100 mM internal K+, rapid elevation of external [K+] from 0 to 10 mM while channels were activated produced no change in current magnitude (outer vestibule conformation did not change). When channels were subsequently closed and reopened in the presence of elevated [K+], current magnitude was increased (outer vestibule conformation had changed). When channels were activated in the presence of low internal [K+], or when K+ flow into conducting channels was transiently interrupted by an internal channel blocker, increasing external [K+] during activation did increase current magnitude (channel conformation did change). These data indicate that, when channels are in the activated state under physiological conditions, the outer vestibule conformation remains fixed despite changes in external [K+]. In contrast, when channel occupancy is lowered, (by channel closing, an internal blocker or low internal [K+]), the outer vestibule can interconvert between the two conformations. We discuss evidence that the ability of the outer vestibule conformation to change is regulated by the occupancy of a nonselectivity filter site by K+. Independent of the outer vestibule-based potentiation mechanism, Kv2.1 was remarkably insensitive to K+-dependent processes that influence current magnitude (current magnitude changed by <7% at membrane potentials between −20 and 30 mV). Replacement of two outer vestibule lysines in Kv2.1 by smaller neutral amino acids made current magnitude dramatically more sensitive to the reduction in K+ driving force (current magnitude changed by as much as 40%). When combined, these outer vestibule properties (fixed conformation during activation and the presence of lysines) all but prevent variation in Kv2.1 current magnitude when [K+] changes during activation. Moreover, the insensitivity of Kv2.1 current magnitude to changes in K+ driving force promotes a more uniform modulation of current over a wide range of membrane potentials by the K+-dependent regulation of outer vestibule conformation.