Dihydropyridine-sensitive skeletal muscle Ca channels in polarized planar bilayers. 1. Kinetics and voltage dependence of gating

Reciprocal dihydropyridine and ryanodine receptor interactions in skeletal muscle activation

Dihydropyridine (DHPR) and ryanodine receptors (RyRs) are central to transduction of transverse (T) tubular membrane depolarisation initiated by surface action potentials into release of sarcoplasmic reticular (SR) Ca2+ in skeletal muscle excitation-contraction coupling. Electronmicroscopic methods demonstrate an orderly positioning of such tubular DHPRs relative to RyRs in the SR at triad junctions where their membranes come into close proximity. Biochemical and genetic studies associated expression of specific, DHPR and RyR, isoforms with the particular excitation-contraction coupling processes and related elementary Ca2+ release events found respectively in skeletal and cardiac muscle. Physiological studies of intramembrane charge movements potentially related to voltage triggering of Ca2+ release demonstrated a particular qγ charging species identifiable with DHPRs through its T-tubular localization, pharmacological properties, and steep voltage-dependence paralleling Ca2+ release. Its nonlinear kinetics implicated highly co-operative conformational events in its transitions in response to voltage change. The effects of DHPR and RyR agonists and antagonists upon this intramembrane charge in turn implicated reciprocal rather than merely unidirectional DHPR-RyR interactions in these complex reactions. Thus, following membrane potential depolarization, an orthograde qγ-DHPR-RyR signaling likely initiates conformational alterations in the RyR with which it makes contact. The latter changes could then retrogradely promote further qγ-DHPR transitions through reciprocal co-operative allosteric interactions between receptors. These would relieve the resting constraints on both further, delayed, nonlinear qγ-DHPR charge transfers and on RyR-mediated Ca2+ release. They would also explain the more rapid charging and recovery qγ transients following larger depolarizations and membrane potential repolarization to the resting level.

COOH-terminal truncated alpha(1S) subunits conduct current better than full-length dihydropyridine receptors

Skeletal muscle dihydropyridine (DHP) receptors function both as voltage-activated Ca(2+) channels and as voltage sensors for coupling membrane depolarization to release of Ca(2+) from the sarcoplasmic reticulum. In skeletal muscle, the principal or alpha(1S) subunit occurs in full-length ( approximately 10% of total) and post-transcriptionally truncated ( approximately 90%) forms, which has raised the possibility that the two functional roles are subserved by DHP receptors comprised of different sized alpha(1S) subunits. We tested the functional properties of each form by injecting oocytes with cRNAs coding for full-length (alpha(1S)) or truncated (alpha(1SDeltaC)) alpha subunits. Both translation products were expressed in the membrane, as evidenced by increases in the gating charge (Q(max) 80-150 pC). Thus, oocytes provide a robust expression system for the study of gating charge movement in alpha(1S), unencumbered by contributions from other voltage-gated channels or the complexities of the transverse tubules. As in recordings from skeletal muscle, for heterologously expressed channels the peak inward Ba(2+) currents were small relative to Q(max). The truncated alpha(1SDeltaC) protein, however, supported much larger ionic currents than the full-length product. These data raise the possibility that DHP receptors containing the more abundant, truncated form of the alpha(1S) subunit conduct the majority of the L-type Ca(2+) current in skeletal muscle. Our data also suggest that the carboxyl terminus of the alpha(1S) subunit modulates the coupling between charge movement and channel opening.

Effects of mutations causing hypokalaemic periodic paralysis on the skeletal muscle L-type Ca2+ channel expressed in Xenopus laevis oocytes

1. A truncated form of the rabbit alpha1S Ca2+ channel subunit (alpha1SDeltaC) was expressed with the beta1b, alpha2delta and gamma auxiliary subunits in Xenopus laevis oocytes. After 5-7 days, skeletal muscle L-type currents were measured (469 +/- 48 nA in 10 mM Ba2+). All three of the auxiliary subunits were necessary to record significant L-type current. A rapidly inactivating, dihydropyridine-insensitive endogenous Ba2+ current was observed in oocytes expressing the auxiliary subunits without an exogenous alpha subunit. Expression of full-length alpha1S gave 10-fold smaller currents than the truncated form. 2. Three missense mutations causing hypokalaemic periodic paralysis (R528H in domain II S4 of the alpha1S subunit; R1239H and R1239G in domain IV S4) were introduced into alpha1SDeltaC and expressed in oocytes. L-type current was separated from the endogenous current by nimodipine subtraction. All three of the mutations reduced L-type current amplitude ( approximately 40 % for R528H, approximately 60-70 % for R1239H and R1239G). 3. The disease mutations altered the activation properties of L-type current. R528H shifted the G(V) curve approximately 5 mV to the left and modestly reduced the voltage dependence of the activation time constant, tauact. R1239H and R1239G shifted the G(V) curve approximately 5-10 mV to the right and dramatically slowed tauact at depolarized test potentials. 4. The voltage dependence of steady-state inactivation was not significantly altered by any of the disease mutations. 5. Wild-type and mutant L-type currents were also measured in the presence of (-)-Bay K8644, which boosted the amplitude approximately 5- to 7-fold. The effects of the mutations on the position of the G(V) curve and the voltage dependence of tauact were essentially the same as in the absence of agonist. Bay K-enhanced tail currents were slowed by R528H and accelerated by R1239H and R1239G. 6. We conclude that the domain IV mutations R1239H and R1239G have similar effects on the gating properties of the skeletal muscle L-type Ca2+ channel expressed in Xenopus oocytes, while the domain II mutation R528H has distinct effects. This result implies that the location of the substitutions is more important than their degree of conservation in determining their biophysical consequences.

Gating of the L-type Ca channel in human skeletal myotubes: an activation defect caused by the hypokalemic periodic paralysis mutation R528H

The skeletal muscle L-type Ca channel serves a dual role as a calcium-conducting pore and as the voltage sensor coupling t-tubule depolarization to calcium release from the sarcoplasmic reticulum. Mutations in this channel cause hypokalemic periodic paralysis (HypoPP), a human autosomal dominant disorder characterized by episodic failure of muscle excitability that occurs in association with a decrease in serum potassium. The voltage-dependent gating of L-type Ca channels was characterized by recording whole-cell Ca currents in myotubes cultured from three normal individuals and from a patient carrying the HypoPP mutation R528H. We found two effects of the R528H mutation on the L-type Ca current in HypoPP myotubes: (1) a mild reduction in current density and (2) a significant slowing of the rate of activation. We also measured the voltage dependence of steady-state L-type Ca current inactivation and characterized, for the first time in a mammalian preparation, the kinetics of both entry into and recovery from inactivation over a wide range of voltages. The R528H mutation had no effect on the kinetics or voltage dependence of inactivation.

Gating of the L-type Ca channel in human skeletal myotubes: an activation defect caused by the hypokalemic periodic paralysis mutation R528H

The skeletal muscle L-type Ca channel serves a dual role as a calcium-conducting pore and as the voltage sensor coupling t-tubule depolarization to calcium release from the sarcoplasmic reticulum. Mutations in this channel cause hypokalemic periodic paralysis (HypoPP), a human autosomal dominant disorder characterized by episodic failure of muscle excitability that occurs in association with a decrease in serum potassium. The voltage-dependent gating of L-type Ca channels was characterized by recording whole-cell Ca currents in myotubes cultured from three normal individuals and from a patient carrying the HypoPP mutation R528H. We found two effects of the R528H mutation on the L-type Ca current in HypoPP myotubes: (1) a mild reduction in current density and (2) a significant slowing of the rate of activation. We also measured the voltage dependence of steady-state L-type Ca current inactivation and characterized, for the first time in a mammalian preparation, the kinetics of both entry into and recovery from inactivation over a wide range of voltages. The R528H mutation had no effect on the kinetics or voltage dependence of inactivation.

A dihydropyridine-sensitive voltage-dependent calcium channel in the sarcolemmal membrane of crustacean muscle

Single-channel currents through calcium channels in muscle of a marine crustacean, the isopod Idotea baltica, were investigated in cell-attached patches. Inward barium currents were strongly voltage-dependent, and the channels were closed at the cell's resting membrane potential. The open probability (Po) increased e-fold for an 8.2 mV (+/- 2.4, n = 13) depolarization. Channel opening were mainly brief (< 0.3 ms) and evenly distributed throughout 100-ms pulses. Averaged, quasimacroscopic currents showed fast activation and deactivation and did not inactivate during 100-ms test pulses. Similarly, channel activity persisted at steadily depolarized holding potentials. With 200 mM Ba2+ as charge carrier, the average slope conductance from the unitary currents between +30 and +80 mV, was 20 pS (+/- 2.6, n = 12). The proportion of long openings, which were very infrequent under control conditions, was greatly increased by preincubation of the muscle fibers with the calcium channel agonist, the dihydropyridine Bay K8644 (10-100 microM). Properties of these currents resemble those through the L-type calcium channels of mammalian nerve, smooth muscle, and cardiac muscle cells.

Rectification of cystic fibrosis transmembrane conductance regulator chloride channel mediated by extracellular divalent cations

We report here distinct rectification of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel reconstituted in lipid bilayer membranes. Under the symmetrical ionic condition of 200 mM KCl (with 1 mM MgCl2 in cis intracellular and 0 MgCl2 in trans extracellular solutions, pH in both solutions buffered at 7.4 with 10 mM HEPES), the inward currents (intracellular-->extracellular chloride movement) through a single CFTR channel were approximately 20% larger than the outward currents. This inward rectification of the CFTR channel was mediated by extracellular divalent cations, as the linear current-voltage relationship of the channel could be restored through the addition of millimolar concentrations of MgCl2 or CaCl2 to the trans solution. The dose responses for [Mg]zero and [Ca]zero had half-dissociation constants of 152 +/- 72 microM and 172 +/- 40 microM, respectively. Changing the pH buffer from HEPES to N-tris-(hydroxymethyl)methyl-2-aminoethanesulfonic acid did not alter rectification of the CFTR channel. The nonlinear conductance property of the CFTR channel seemed to be due to negative surface charges on the CFTR protein, because in pure neutral phospholipid bilayers, clear rectification of the channel was also observed when the extracellular solution did not contain divalent cations. The CFTR protein contains clusters of negatively charged amino acids on several extracellular loops joining the transmembrane segments, which could constitute the putative binding sites for Ca and Mg.

Unitary behavior of skeletal, cardiac, and chimeric L-type Ca2+ channels expressed in dysgenic myotubes

Skeletal and cardiac dihydropyridine receptors function both as voltage-dependent L-type calcium channels (L-channels) and as critical proteins that trigger calcium release from the sarcoplasmic reticulum in muscle. In spite of these similarities, skeletal L-channels exhibit a markedly slower activation rate than cardiac L-channels. We investigated the mechanisms underlying this difference by comparing the unitary behavior of L-channels in cell-attached patches of dysgenic myotubes expressing skeletal, cardiac, or chimeric dihydropyridine receptors. Our results demonstrate that ensemble averages activate rapidly for the purely cardiac dihydropyridine receptor and approximately five times more slowly for L-channels attributable to the purely skeletal dihydropyridine receptor or a chimeric dihydropyridine receptor in which only the first internal repeat and all of the putative intracellular loops are of skeletal origin. All of the constructs studied similarly exhibit a brief (2-ms) and a long (> or = 15-ms) open time in the presence of Bay K 8644, neither of which depend significantly on voltage. In the absence of Bay K 8644, the fraction of total open events is markedly shifted to the briefer open time without altering the rate of ensemble activation. Closed time analysis of L-channels with cardiac-like, rapid activation (recorded in the presence of dihydropyridine agonist) reveals both a brief (approximately 1-ms) closed time and a second, voltage-dependent, long-lasting closed time. The time until first opening after depolarization is three to six times faster for rapidly activating L-channels than for slowly activating L-channels and depends strongly on voltage for both types of channels. The results suggest that a voltage-dependent, closed-closed transition that is fast in cardiac L-channels and slow in skeletal L-channels can account for the difference in activation rate between these two channels.

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.

Boar sperm plasma membrane Ca(2+)-selective channels in planar lipid bilayers

Entry of Ca2+ through Ca2+ channels is thought to trigger the acrosome reaction of spermatozoa during fertilization. Antagonists of the L-type Ca2+ channel are known to prevent the intracellular Ca2+ (Ca2+) increase and inhibit acrosomal exocytosis in mammalian sperm. Planar bilayer recordings were used to study Ca2- channels incorporated from partially purified boar sperm plasma membranes. With symmetrical 50 mM NaCl and 100 mM BaCl2 on the cis side, single-channel events consistent with Ba2+ flux from cis to trans were observed. These channels were activated by the dihydropyridine agonist (+/-)BAY K 8644 and blocked by the antagonist nitrendipine. Sperm Ca2- channels did not require depolarization for activation and did not inactivate. The (+/-)BAY K 8644 and (S-)BAY K 8644 enantiomers increased apparent open time in a dose-dependent [half-maximal activity constant (K0.5) = 0.9 and 0.3 microM, respectively] manner. Dihydropyridine antagonists nitrendipine (K0.5 = 0.5 microM) and (R+)BAY K 8644 (K0.5 = 2.8 microM) decreased apparent open times. The channels described in this report share some properties with brain, cardiac, and skeletal muscle t tubule Ca2+ channels and may be involved in increasing Cai2+ before the acrosome reaction.

Desensitization of the skeletal muscle ryanodine receptor: evidence for heterogeneity of calcium release channels

Ca release channels from the junctional sarcoplasmic reticulum (SR) membranes of rabbit skeletal muscle were incorporated into the lipid bilayer membrane, and the inactivation kinetics of the channel were studied at large membrane potentials. The channels conducting Cs currents exhibited a characteristic desensitization that is both ligand and voltage dependent: 1) with a test pulse to -100 mV (myoplasmic minus luminal SR), the channel inactivated with a time constant of 3.9 s; 2) the inactivation had an asymmetric voltage dependence; it was only observed at voltages more negative than -80 mV; and 3) repetitive tests to -100 mV usually led to immobilization of the channel, which could be recovered by a conditioning pulse to positive voltages. The apparent desensitization was seen in approximately 50% of the experiments, with both the native Ca release channel (in the absence of ryanodine) and the ryanodine-activated channel (1 microM ryanodine). The native Ca release channels revealed heterogeneous gating with regard to activation by ATP and binding to ryanodine. Most channels had high affinity to ATP activation (average open probability (po) = 0.55, 2 mM ATP, 100 microM Ca), whereas a small portion of channels had low affinity to ATP activation (po = 0.11, 2 mM ATP, 100 microM Ca), and some channels bound ryanodine faster (< 2 min), whereas others bound much slower (> 20 min). The faster ryanodine-binding channels always desensitized at large negative voltages, whereas those that bound slowly did not show apparent desensitization. The heterogeneity of the reconstituted Ca release channels is likely due to the regulatory roles of other junctional SR membrane proteins on the Ca release channel.

Single calcium channel behavior in native skeletal muscle

The purpose of this study was to use whole-cell and cell-attached patches of cultured skeletal muscle myotubes to study the macroscopic and unitary behavior of voltage-dependent calcium channels under similar conditions. With 110 mM BaCl2 as the charge carrier, two types of calcium channels with markedly different single-channel and macroscopic properties were found. One class was DHP-insensitive, had a single-channel conductance of approximately 9 pS, yielded ensembles that displayed an activation threshold near -40 mV, and activated and inactivated rapidly in a voltage-dependent manner (T current). The second class could only be well resolved in the presence of the DHP agonist Bay K 8644 (5 microM) and had a single-channel conductance of approximately 14 pS (L current). The 14-pS channel produced ensembles exhibiting a threshold of approximately -10 mV that activated slowly (tau act approximately 20 ms) and displayed little inactivation. Moreover, the DHP antagonist, (+)-PN 200-110 (10 microM), greatly increased the percentage of null sweeps seen with the 14-pS channel. The open probability versus voltage relationship of the 14-pS channel was fitted by a Boltzmann distribution with a VP0.5 = 6.2 mV and kp = 5.3 mV. L current recorded from whole-cell experiments in the presence of 110 mM BaCl2 + 5 microM Bay K 8644 displayed similar time- and voltage-dependent properties as ensembles of the 14-pS channel. Thus, these data are the first comparison under similar conditions of the single-channel and macroscopic properties of T current and L current in native skeletal muscle, and identify the 9- and 14-pS channels as the single-channel correlates of T current and L current, respectively.

Simultaneous expression of cardiac and skeletal muscle isoforms of the L-type Ca2+ channel in a rat heart muscle cell line

1. We have investigated the identity of the L-type Ca2+ channels present in the H9c2 myoblast line derived from embryonic rat ventricle. To this end, we characterized macroscopic and unitary Ba2+ currents through Ca2+ channels, and looked for specific genetic messages encoding different L-type Ca2+ channel isoforms. 2. The macroscopic Ba2+ current (recorded in 10 mM BaCl2) revealed two components with different time courses of activation. The fast component (IBa,fast) activates with a time constant of 23 +/- 12 ms (at +10 mV), while the slow component activates with a time constant of 125 +/- 12 ms (at +10 mV). 3. Single-channel recordings revealed the presence of two independent channels with conductance values of 11 and 25 pS (in 70 mM Ba2+). These values are identical to those reported previously for skeletal muscle and cardiac Ca2+ channels, respectively. 4. The mean ensemble current from the 11 pS channel reproduced the time course of the slow component observed at the macroscopic level, while the 25 pS ensemble time course paralleled that of the fast component. 5. Reverse transcriptase polymerase chain reaction (PCR) with alpha 1-isoform-specific primers revealed the presence of two distinct transcripts in H9c2 cells. The sequences of the PCR products showed a high degree of homology with the corresponding segments of the rabbit cardiac and skeletal muscle L-type Ca2+ channel isoforms. Adult rat skeletal and cardiac muscle expressed only one type of transcript. 6. H9c2 cells appear to be unique in that they simultaneously express both skeletal muscle and cardiac isoforms of the L-type Ca2+ channel alpha 1-subunit. Thus, the H9c2 cell line may prove to be useful when studying the regulation of subtype-specific Ca2+ channel gene expression.

Kinetic properties of skeletal-muscle-like high-threshold calcium currents in a non-fusing muscle cell line

Macroscopic kinetics and single-channel properties of skeletal-muscle-type calcium currents were studied in the non-fusing, clonal muscle cell line, BC3H1. Slowly activating, dihydropyridine(DHP)-sensitive currents, associated with T-tubular DHP receptors and ion channels, could be isolated from rapidly activating, DHP-resistant currents. Description of macroscopic current activation kinetics required only a brief delay term (tau o <1 ms), two ascending exponential terms with voltage-dependent time constants (2 < tau 1 > 20 ms and 10 < tau 2 < 200 ms), and a single exponential decay term (0.5 < tau 3 < or = 5 s). Steady-state activation voltage dependence required description by two Boltzmann distribution terms with V 1/2 and slope factors differing by 20 mV and 3.5- to 4-fold respectively. These two distributions were correlated with the steady-state voltage dependence of the two ascending kinetic terms described by tau 1 and tau 2 respectively. Rundown of the DHP-sensitive slow current was correlated with a negative shift in the voltage dependence of current decay (tau 3). Three conductance levels (4.5 pS, 8 pS and 12 pS) were detected in single-channel records, two of which (the 8-pS and 12-pS events) were prolonged by BayK8644 and thus associated with DHP-sensitive single-channel events. Description of single-channel open time distributions required a minimum of two exponential terms (2.5 +/- 0.9 ms and 10.3 +/- 5.4 ms at -10 mV). Slow transitions among closed states results in biexponential latency-to-first-event distributions (47 +/- 12 ms and 470 +/- 123 ms at -10 mV).

Calcicludine, a venom peptide of the Kunitz-type protease inhibitor family, is a potent blocker of high-threshold Ca2+ channels with a high affinity for L-type channels in cerebellar granule neurons

Calcicludine (CaC) is a 60-amino acid polypeptide from the venom of Dendroaspis angusticeps. It is structurally homologous to the Kunitz-type protease inhibitor, to dendrotoxins, which block K+ channels, and to the protease inhibitor domain of the amyloid beta protein that accumulates in Alzheimer disease. Voltage-clamp experiments on a variety of excitable cells have shown that CaC specifically blocks most of the high-threshold Ca2+ channels (L-, N-, or P-type) in the 10-100 nM range. Particularly high densities of specific 125I-labeled CaC binding sites were found in the olfactory bulb, in the molecular layer of the dentate gyrus and the stratum oriens of CA3 field in the hippocampal formation, and in the granular layer of the cerebellum. 125I-labeled CaC binds with a high affinity (Kd = 15 pM) to a single class of noninteracting sites in rat olfactory bulb microsomes. The distribution of CaC binding sites in cerebella of three mutant mice (Weaver, Reeler, and Purkinje cell degeneration) clearly shows that the specific high-affinity labeling is associated with granule cells. Electrophysiological experiments on rat cerebellar granule neurons in primary culture have shown that CaC potently blocks the L-type component of the Ca2+ current (K0.5 = 0.2 nM). Then CaC, in the nanomolar range, appears to be a highly potent blocker of an L-subtype of neuronal Ca2+ channels.

Measurement of calcium transients and slow calcium current in myotubes

The purpose of this study was to characterize excitation-contraction (e-c) coupling in myotubes for comparison with e-c coupling of adult skeletal muscle. The whole cell configuration of the patch clamp technique was used in conjunction with the calcium indicator dye Fluo-3 to study the calcium transients and slow calcium currents elicited by voltage clamp pulses in cultured myotubes obtained from neonatal mice. Cells were held at -80 mV and stimulated with 15-20 ms test depolarizations preceded and followed by voltage steps designed to isolate the slow calcium current. The slow calcium current had a threshold for activation of about 0 mV; the peak amplitude of the current reached a maximum at 30 to 40 mV a and then declined for still stronger depolarizations. The calcium transient had a threshold of about -10 mV, and its amplitude increased as a sigmoidal function of test potential and did not decrease again even for test depolarizations sufficiently strong (> or = 50 mV) that the amplitude of the slow calcium current became very small. Thus, the slow calcium current in myotubes appears to have a negligible role in the process of depolarization-induced release of intracellular calcium and this process in myotubes is essentially like that in adult skeletal muscle. After repolarization, however, the decay of the calcium transient in myotubes was very slow (hundreds of ms) compared to adult muscle, particularly after strong depolarizations that triggered larger calcium transients. Moreover, when cells were repolarized after strong depolarizations, the transient typically continued to increase slowly for up to several tens of ms before the onset of decay. This continued increase after repolarization was abolished by the addition of 5 mM BAPTA to the patch pipette although the rapid depolarization-induced release was not, suggesting that the slow increase might be a regenerative response triggered by the depolarization-induced release of calcium. The addition of either 0.5 mM Cd2+ + 0.1 mM La3+ or the dihydropyridine (+)-PN 200-110 (1 microM) reduced the amplitude of the calcium transient by mechanisms that appeared to be unrelated to the block of current that these agents produce. In the majority of cells, the decay of the transient was accelerated by the addition of the heavy metals or the dihydropyridine, consistent with the idea that the removal system becomes saturated for large calcium releases and becomes more efficient when the size of the release is reduced.

Sarcoplasmic reticulum release channels from frog skeletal muscle display two types of calcium dependence

Calcium channels derived from sarcoplasmic reticulum of frog skeletal muscle were fused with planar lipid bilayers. Fractional open times displayed two types of calcium dependence: (i) blockable channels showed a bell-shaped calcium dependence with an activation constant of 4.5 microM, a Hill coefficient for activation of 1.46 and a blocking constant of 226 microM, and (ii) non-blockable channels displayed a sigmoidal calcium dependence with an activation constant of 1.1 microM and a Hill coefficient of 1.42; no blocking effect was seen with calcium up to 0.5 mM. These two types of calcium dependence may underlie the coexistence of two different pathways for calcium release in frog skeletal muscle.

A possible role of sarcoplasmic Ca2+ release in modulating the slow Ca2+ current of skeletal muscle

Ca2+ channels are regulated in a variety of different ways, one of which is modulation by the Ca2+ ion itself. In skeletal muscle, Ca2+ release sites are presumably located in the vicinity of the dihydropyridine-sensitive Ca2+ channel. In this study, we have tried to investigate the effects of Ca2+ release from the sarcoplasmic reticulum on the L-type Ca2+ channel in frog skeletal muscle, using the double Vaseline gap technique. We found an increase in Ca2+ current amplitude on application of caffeine, a well-known potentiator of Ca2+ release. Addition of the fast Ca2+ buffer BAPTA to the intracellular solution led to a gradual decline in Ca2+ current amplitude and eventually caused complete inhibition. Similar observations were made when the muscle fibre was perfused internally with the Ca2+ release channel blocker ruthenium red. The time course of Ca2+ current decline followed closely the increase in ruthenium red concentration. This suggests that Ca2+ release from the sarcoplasmic reticulum is involved in the regulation of L-type Ca2+ channels in frog skeletal muscle.

Interaction of phospholipids with proteins and peptides. New advances III

1. The review deals with the recent achievements in the study of the various interactions of phospholipids with proteins and peptides. 2. The interactions are classified according to the hydrophobic, hydrophilic or mixed character of the interactive forces. 3. The effect of the interaction on the structure and biological activity of the interacting molecules is also discussed.

Dihydropyridine-sensitive skeletal muscle Ca channels in polarized planar bilayers. 3. Effects of phosphorylation by protein kinase C

The effects of protein kinase C (PKC) were studied on dihydropyridine (DHP)-sensitive Ca channels from rabbit skeletal muscle T tubule membranes. To determine which channel subunits become phosphorylated under the conditions used for electrophysiological studies, we first performed biochemical studies of phosphorylation. T tubular membranes were fused with vesicles of the lipid mixture used in the planar bilayers, and phosphorylation was assessed using the same concentrations of PKC, adenosine 5'-triphosphate, and buffers as were used in the electrophysiological experiments. The alpha 1 subunit of the DHP receptors was phosphorylated by PKC to an extent of 1 mol phosphate/mol protein. The beta subunit was also phosphorylated but to a significantly lesser extent. The DHP-sensitive Ca channel activity was studied after fusing T tubule membranes with planar bilayers (Ma, J., C. Mundiña-Weilenmann, M. M. Hosey, and E. Ríos. 1991. Biophys. J. 60:890-901). The bilayers were held at -80 mV and activated by depolarizing voltage clamp pulses. The observed Ca channels exhibited two open states (tau o1 = 5 ms and tau o2 = 25 ms). On addition of purified PKC to the intracellular side, the proportion of the longer open state increased threefold. The average open probability during a 2-s, maximally activating pulse (Pmax) increased from 10 to 15%. The voltage dependence of activation was not changed by PKC; the Boltzmann parameters were V1 = -20.5 mV and K = 10.5 mV, which were not significantly different from the reference channels. The deactivation (closing) time constant was increased from 7 to 12 ms after PKC. The inactivation time constant during the pulse was slightly increased(from 1.2 to 1.6 s), and the channel availability at the holding potential was decreased from 76 to 71%. Taken together, the results revealed that PKC increased Pmax largely through a shift in the voltage independent open-close equilibrium of the fully activated channels.This is in contrast with the effect of phosphorylation by PKA (Mundir'a-Weilenmann, C., J. Ma, E. Rios, and M. M. Hosey. 1991. Biophys.J. 60:902-909), which also increases Pmax but mostly by increasing the availability of channels and slowing inactivation during the pulse.

The mechanical hypothesis of excitation-contraction (EC) coupling in skeletal muscle

The mechanism of transmission in skeletal muscle EC coupling is still an open question. There is some indirect evidence in favour of the mechanical coupling hypothesis, deriving mostly from consideration of the structure of the Ca2+ release channel protein. A new functional approach is proposed, that consists in comparing the properties of the complete system--EC coupling in a skeletal muscle fibre--with those of the EC coupling molecules in bilayers. In this approach, those properties of the whole system that are not traceable to its constitutive molecules, are ascribed to the physiological interaction, and are expected to yield new information on the nature of this interaction.