Po-Tsang Huang

Functional and structural characterization of PKA-mediated pHi gating of ROMK1 channels

Hyperprostaglandin E syndrome/antenatal Bartter syndrome (HPS/aBS) is a severe salt-losing renal tubular disorder and results from the mutation of renal outer medullary K(+) (ROMK1) channels. The aberrant ROMK1 function induces alterations in intracellular pH (pH(i)) gating under physiological conditions. We investigate the role of protein kinase A (PKA) in the pH(i) gating of ROMK1 channels. Using giant patch clamp with Xenopus oocytes expressing wild-type and mutant ROMK1 channels, PKA-mediated phosphorylation decreased the sensitivity of ROMK1 channels to pH(i). A homology model of ROMK1 reveals that a PKA phosphorylation site (S219) is spatially juxtaposed to the phosphatidylinositol 4,5-bisphosphate (PIP(2)) binding residues (R188, R217, and K218). Molecular dynamics simulations suggest a stable transition state, in which the shortening of distance between S219 and R217 and the movement of K218 towards the membrane after the PKA-phosphorylation can be observed. Such conformational change may bring the PIP(2) binding residues (K218) more accessible to the membrane-bound PIP(2). In addition, PIP(2) dose-dependently reactivates the acidification-induced rundown channels only when ROMK1 channels have been phosphorylated by PKA. This implies a sequence regulatory episode reflecting the role of PIP(2) in the pH(i) gating of ROMK1 channels by PKA-mediated phosphorylation. Our results provide new insights into the molecular mechanisms underlying the ROMK1 channel regulation associated with HPS/aBS.

Protein kinase C mediated pH i -regulation of ROMK1 channels via a phosphatidylinositol-4,5-bisphosphate-dependent mechanism

The protein kinase C (PKC) pathway is important for the regulation of K+ transport. The renal outer medullar K+ (ROMK1) channels show an exquisite sensitivity to intracellular protons (pHi) (effective pKa approximately 6.8) and play a key role in K+ homeostasis during metabolic acidosis. Our molecular dynamic simulation results suggest that PKC-mediated phosphorylation on Thr-193 may disrupt the PIP2-channel interaction via a charge–charge interaction between Thr-193 and Arg-188. Therefore, we investigated the role of PKC and pHi in regulation of ROMK1 channel activity using a giant patch clamp with Xenopus oocytes expressing wild-type and mutant ROMK1 channels. ROMK1 channels pre-incubated with the PKC activator phorbol-12-myristate-13-acetate exhibited increased sensitivity to pHi (effective pKa shifted to pH approximately 7.0). In the presence of GF109203X—a PKC selective inhibitor—the effective pKa for inhibition of ROMK1 channels by pHi decreased (effective pKa shifted to pH approximately 6.5). The pHi sensitivity of ROMK1 channels mediated by PKC appeared to be dependent of PIP2 depletion. The giant patch clamp together with site direct mutagenesis revealed that Thr-193 is the phosphorylation site on PKC that regulates the pHi sensitivity of ROMK1 channels. Mutation of PKC-induced phosphorylation sites (T193A) decreases the pHi sensitivity and increases the interaction of channel-PIP2. Taken together, these results provide new insights into the molecular mechanisms underlying the pHi gating of ROMK1 channel regulation by PKC.

Structural Influence of Hanatoxin Binding on the Carboxyl Terminus of S3 Segment in Voltage-Gated K + -Channel Kv2.1

The voltage-sensing domains of voltage-gated potassium channels Kv2.1 (drk1) contain four transmembrane segments in each subunit, termed S1 to S4. While S4 is known as the voltage sensor, the carboxyl terminus of S3 (S3C) bears a gradually broader interest concerning the site for gating modifier toxins like hanatoxin and thus the secondary structure arrangement as well as its surrounding environment. To further examine the putative three-dimensional (3-D) structure of S3C and to illustrate the residues required for hanatoxin binding (which may, in turn, show the influence on the S4 in terms of changes in channel gating), molecular simulations and dockings were performed. These were based on the solution structure of hanatoxin and the structural information from lysine-scanning results for S3C fragment. Our data suggest that several basic and acidic residues of hanatoxin are electrostatically and stereochemically mapped onto their partner residues on S3C helix, whereas some aromatic or hydrophobic residues located on the same helical fragment interact with the hydrophobic patch of the toxin upon binding. Therefore, a slight distortion of the S3C helix, in a direction toward the N-terminus of S4, may exist. Such conformational change of S3C upon toxin binding is presented as a possible explanation for the observed shift in hanatoxin binding-induced gating.

Non-basic amino acids in the ROMK1 channels via an appropriate distance modulate PIP2 regulated pHi-gating

The ROMK1 (Kir1.1) channel activity is predominantly regulated by intracellular pH (pHi) and phosphatidylinositol 4,5-bisphosphate (PIP2). Although several residues were reported to be involved in the regulation of pHi associated with PIP2 interaction, the detailed molecular mechanism remains unclear. We perform experiments in ROMK1 pHi-gating with electrophysiology combined with mutational and structural analysis. In the present study, non basic residues of C-terminal region (S219, N215, I192, L216 and L220) in ROMK1 channels have been found to mediate channel-PIP2 interaction and pHi gating. Further, our structural results show these residues with an appropriate distance to interact with membrane PIP2. Meanwhile, a cluster of basic residues (R188, R217 and K218), which was previously discovered regarding the interaction with PIP2, exists in this appropriate distance to discriminate the regulation of channel-PIP2 interaction and pHi-gating. This appropriate distance can be observed with high conservation in the Kir channel family. Our results provide insight that an appropriate distance cooperates with the electrostatics interaction of channel-PIP2 to regulate pHi-gating.

The Penetration Depth for Hanatoxin Partitioning into the Membrane Hydrocarbon Core Measured with Neutron Reflectivity

Hanatoxin (HaTx) from spider venom works as an inhibitor of Kv2.1 channels, most likely by interacting with the voltage sensor (VS). However, the way in which this water-soluble peptide modifies the gating remains poorly understood as the VS is deeply embedded within the bilayer, although it would change its position depending on the membrane potential. To determine whether HaTx can indeed bind to the VS, the depth at which HaTx penetrates into the POPC membranes was measured with neutron reflectivity. Our results successfully demonstrate that HaTx penetrates into the membrane hydrocarbon core (∼9 Å from the membrane surface), not lying on the membrane-water interface as reported for another voltage sensor toxin (VSTx). This difference in penetration depth suggests that the two toxins fix the voltage sensors at different positions with respect to the membrane normal, thereby explaining their different inhibitory effects on the channels. In particular, results from MD simulations constrained by our penetration data clearly demonstrate an appropriate orientation for HaTx to interact with the membranes, which is in line with the biochemical information derived from stopped-flow analysis through delineation of the toxin-VS binding interface.