Jiying Zhao

Functional calcium release channel formed by the carboxyl-terminal portion of ryanodine receptor

The ryanodine receptor (RyR) is one of the key proteins involved in excitation-contraction (E-C) coupling in skeletal muscle, where it functions as a Ca2+ release channel in the sarcoplasmic reticulum (SR) membrane. RyR consists of a single polypeptide of approximately 560 kDa normally arranged in a homotetrameric structure, which contains a carboxyl (C)-terminal transmembrane domain and a large amino (N)-terminal cytoplasmic domain. To test whether the carboxyl-terminal portion of RyR is sufficient to form a Ca2+ release channel, we expressed the full-length (RyR-wt) and C-terminal (RyR-C, approximately 130 kDa) RyR proteins in a Chinese hamster ovary (CHO) cell line, and measured their Ca2+ release channel functions in planar lipid bilayer membranes. The single-channel properties of RyR-wt were found to be similar to those of RyR from skeletal muscle SR. The RyR-C protein forms a cation-selective channel that shares some of the channel properties with RyR-wt, including activation by cytoplasmic Ca2+ and regulation by ryanodine. Unlike RyR-wt, which exhibits a linear current-voltage relationship and inactivates at millimolar Ca2+, the channels formed by RyR-C display significant inward rectification and fail to close at high cytoplasmic Ca2+. Our results show that the C-terminal portion of RyR contains structures sufficient to form a functional Ca2+ release channel, but the N-terminal portion of RyR also affects the ion-conduction and calcium-dependent regulation of the Ca2+ release channel.

Function of the R domain in the cystic fibrosis transmembrane conductance regulator chloride channel.

For a cystic fibrosis transmembrane conductance regulator (CFTR) channel to enter its open state, serine residues in the R domain must be phosphorylated by cAMP-dependent protein kinase, and intracellular ATP must bind to the nucleotide-binding folds and subsequently be hydrolyzed. CFTR with its R domain partially removed, ΔR(708–835)-CFTR, forms a chloride channel that opens independently of protein kinase A phosphorylation, with open probability approximately one-third that of the wild type CFTR channel. Deletion of this portion of the R domain from CFTR alters the response of the channel to 5′-adenylylimidodiphosphate, pyrophosphate, and vanadate, compounds that prolong burst duration of the wild type CFTR channel but fail to do so in the ΔR-CFTR. In addition, the addition of exogenous unphosphorylated R domain protein, which blocks the wild type CFTR channel, has no effect on the ΔR-CFTR channel. However, when the exogenous R domain is phosphorylated, significant stimulation of the ΔR-CFTR channel results;P o increases from 0.10 to 0.22. These data are consistent with a model for CFTR function in which the R domain in the unphosphorylated state interacts with the first nucleotide binding fold to inhibit either binding or hydrolysis of ATP or transduction of the effect to open the pore, but when the R domain is phosphorylated, it undergoes conformational change and interacts at a separate site in the first nucleotide binding fold to stimulate either binding or hydrolysis of ATP or transduction of the effect to open the pore.

A Single Conductance Pore for Chloride Ions Formed by Two Cystic Fibrosis Transmembrane Conductance Regulator Molecules

The cystic fibrosis transmembrane conductance regulator (CFTR) is a cAMP-dependent protein kinase (PKA)- and ATP-regulated chloride channel, whose gating process involves intra- or intermolecular interactions among the cytosolic domains of the CFTR protein. Tandem linkage of two CFTR molecules produces a functional chloride channel with properties that are similar to those of the native CFTR channel, including trafficking to the plasma membrane, ATP- and PKA-dependent gating, and a unitary conductance of 8 picosiemens (pS). A heterodimer, consisting of a wild type and a mutant CFTR, also forms an 8-pS chloride channel with mixed gating properties of the wild type and mutant CFTR channels. The data suggest that two CFTR molecules interact together to form a single conductance pore for chloride ions.

Rectification of skeletal muscle ryanodine receptor mediated by FK506 binding protein.

The cytosolic receptor for immunosuppressant drugs, FK506 binding protein (FKBP12), maintains a tight association with ryanodine receptors of sarcoplasmic reticulum (SR) membrane in skeletal muscle. The interaction between FKBP12 and ryanodine receptors resulted in distinct rectification of the Ca release channel. The endogenous FKBP-bound Ca release channel conducted current unidirectionally from SR lumen to myoplasm; in the opposite direction, the channel deactivated with fast kinetics. The binding of FKBP12 is likely to alter subunit interactions within the ryanodine receptor complex, as revealed by changes in conductance states of the channel. Both on- and off-rates of FKBP12 binding to the ryanodine receptor showed clear dependence on the membrane potential, suggesting that the binding sites of FKBP12 reside in or near the conduction pore of the Ca release channel. Rectification of the Ca release channel would prevent counter-current flow during the rapid release of Ca from SR membrane, and thus may serve as a negative feedback mechanism that participates in the process of muscle excitation-contraction coupling.

Slow conversions among subconductance states of cystic fibrosis transmembrane conductance regulator chloride channel

The cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel exhibits multiple subconductance states. To study the regulation of conductance states of the CFTR channel, we expressed the wild-type CFTR protein in HEK 293 cells, and isolated microsomal membrane vesicles for reconstitution studies in lipid bilayer membranes. A single CFTR channel had a dominant conductance of 7.8 pS (H), plus two sub-open states with conductances of approximately 6 pS (M) and 2.7 pS (L) in 200 mM KCl with 1 mM MgCl2 (intracellular) and 50 mM KCl with no MgCl2 (extracellular), with pH maintained at 7.4 by 10 mM HEPES-Tris on both sides of the channel. In 200 mM KCl, both H and L states could be measured in stable single-channel recordings, whereas M could not. Spontaneous transitions between H and L were slow; it took 4.5 min for L-->H, and 3.2 min for H-->L. These slow conversions among subconductance states of the CFTR channel were affected by extracellular Mg; in the presence of millimolar Mg, the channel remained stable in the H state. Similar phenomena were also observed with endogenous CFTR channels in T84 cells. In high-salt conditions (1.5 M KCl), all three conductance states of the expressed CFTR channel, 12.1 pS, 8.2 pS, and 3.6 pS, became stable and seemed to gate independently from each other. The existence of multiple stable conductance states associated with the CFTR channel suggests two possibilities: either a single CFTR molecule can exist in multiple configurations with different conductance values, or the CFTR channel may contain multimers of the 170-kDa CFTR protein, and different conductance states are due to different aggregation states of the CFTR protein.

Highly cooperative and hysteretic response of the skeletal muscle ryanodine receptor to changes in proton concentrations

Ryanodine receptors are key molecules in excitation-contraction coupling of skeletal muscle. They form the pore of the calcium release channel, which is regulated by Ca and ATP. Multiple proton titration sites are involved in controlling the different open states of the channel, as indicated by the following: i) the channel had a biphasic response to changes in proton concentrations around neutral pH; ii) the activities of the channel were inhibited by acidic pHs in a highly cooperative manner; and iii) the channel exhibited pronounced hysteresis to changes in pH. Four distinct conductance states can be identified in the single ryanodine-activated calcium release channel. The distribution of the multiple conductance states depends on the level of [Ca], ATP, and pH in the recording solution. The data are consistent with the multimeric structure of the skeletal muscle ryanodine receptor.

Human epithelial cystic fibrosis transmembrane conductance regulator without exon 5 maintains partial chloride channel function in intracellular membranes.

The cardiac isoform of the cystic fibrosis transmembrane conductance regulator (CFTR) is a splice variant of the epithelial CFTR, with lacks 30 amino acids encoded by exon 5 in the first intracellular loop. For examination of the role of exon 5 in CFTR channel function, a CFTR deletion mutant, in which exon 5 was removed from the human epithelial CFTR, was constructed. The wild type and delta exon5 CFTR were expressed in a human embryonic kidney cell line (293 HEK). Fully mature glycosylated CFTR (approximately 170 kDa) was immunoprecipitated from cells transfected with wild type CFTR cDNA, whereas cells transfected with delta exon5 CFTR express only a core-glycosylated from (approximately 140 kDa). The Western blot test performed on subcellular membrane fractions showed that delta exon5 CFTR was located in the intracellular membranes. Neither incubation at lower temperature (26 degrees C) nor stimulation of 293 HEK cells with forskolin or CPT-cAMP caused improvement in glycosylation and processing of delta exon5 CFTR proteins, indicating that the human epithelial CFTR lacking exon5 did not process properly in 293 HEK cells. On incorporation of intracellular membrane vesicles containing the delta exon5 CFTR proteins into the lipid bilayer membrane, functional phosphorylation- and ATP-dependent chloride channels were identified. CFTR channels with an 8-pS full-conductance state were observed in 14% of the experiments. The channel had an average open probability (Po) of 0.098 +/- 0.022, significantly less than that of the wild type CFTR (Po = 0.318 +/- 0.028). More frequently, the delta exon5 CFTR formed chloride channels with lower conductance states of approximately 2-3 and approximately 4-6 pS. These subconductance states were also observed with wild type CFTR but to a much lesser extent. Average Po for the 2-3-pS subconductance state, estimated from the area under the curve on an amplitude histogram, was 0.461 +/- 0.194 for delta exon5 CFTR and 0.332 +/- 0.142 for wild type (p = 0.073). The data obtained indicate that deleting 30 amino acids from the first intracellular loop of CFTR affects both processing and function of the CFTR chloride channel.

Conformation, independent of charge, in the R domain affects cystic fibrosis transmembrane conductance regulator channel openings

The R domain of cystic fibrosis transmembrane conductance regulator (CFTR), when phosphorylated, undergoes conformational change, and the chloride channel opens. We investigated the contribution of R domain conformation, apart from the changes induced by phosphorylation, to channel opening, by testing the effect of the peptidyl-prolyl isomerase, cyclophilin A, on the CFTR channel. When it was applied after the channel had been opened by PKA phosphorylation, cyclophilin A increased the open probability of wild-type CFTR (from P(o) = 0.197 +/- 0.010 to P(o) = 0.436 +/- 0. 029) by increasing the number of channel openings, not open time. Three highly conserved proline residues in the R domain, at positions 740, 750, and 759, were considered as candidate targets for cyclophilin A. Mutations of these prolines to alanines (P3A mutant) resulted in a channel unresponsive to cyclophilin A but with pore properties similar to the wild type, under strict control of PKA and ATP, but with significantly increased open probability (P(o) = 0.577 +/- 0.090) compared to wild-type CFTR, again due to an increase in the number of channel openings and not open time. Mutation of each of the proline residues separately and in pairs demonstrated that all three proline mutations are required for maximal P(o). When P3A was expressed in 293 HEK cells and tested by SPQ assay, chloride efflux was significantly increased compared to cells transfected with wild-type CFTR. Thus, treatments favoring the trans-peptidyl conformation about conserved proline residues in the R domain of CFTR affect openings of CFTR, above and beyond the effect of PKA phosphorylation.

A negatively charged region of the skeletal muscle ryanodine receptor is involved in Ca2+-dependent regulation of the Ca2+ release channel

The ryanodine receptor/Ca2+ release channels from skeletal (RyR1) and cardiac (RyR2) muscle cells exhibit different inactivation profiles by cytosolic Ca2+. D3 is one of the divergent regions between RyR1 (amino acids (aa) 1872–1923) and RyR2 (aa 1852–1890) and may contain putative binding site(s) for Ca2+‐dependent inactivation of RyR. To test this possibility, we have deleted the D3 region from RyR1 (ΔD3‐RyR1), residues 1038–3355 from RyR2 (Δ(1038–3355)‐RyR2) and inserted the skeletal D3 into Δ(1038–3355)‐RyR2 to generate sD3‐RyR2. The channels formed by ΔD3‐RyR1 and Δ(1038–3355)‐RyR2 are resistant to inactivation by mM [Ca2+], whereas the chimeric sD3‐RyR2 channel exhibits significant inactivation at mM [Ca2+]. The ΔD3‐RyR1 channel retains its sensitivity to activation by caffeine, but is resistant to inactivation by Mg2+. The data suggest that the skeletal D3 region is involved in the Ca2+‐dependent regulation of the RyR1 channel.

Functional dissection of the R domain of cystic fibrosis transmembrane conductance regulator1

Exogenously expressed unphosphorylated sub‐domains of the R domain block CFTR Cl− channels in the planar lipid bilayer, though the block differs from block with full length R domain. Full length R domain peptide (aa 588–855) blocks CFTR Cl− channels quickly, completely and permanently [1]. Two sub‐domains, RD1RD2 (aa 588–805) and RD2TM (aa 672–855), also inhibit CFTR Cl− channels, but the block takes longer to effect and is not complete. Shorter sequences, RD1 (aa 588–746) and RD2 (aa 672–805), fail to effect any block. These data suggest that either the amino‐terminal or carboxy‐terminal portions of the R domain protein or its stabilized secondary structure are critical to functional regulation.