Conducting and voltage-dependent behaviors of potassium ion channels reconstituted from diaphragm sarcoplasmic reticulum: comparison with the cardiac isoform.

Sarcoplasmic reticulum (SR) K+ channels from canine diaphragm were studied upon fusion of longitudinal and junctional membrane vesicles into planar lipid bilayers (PLB). The large-conductance cation selective channel (gamma(max) = 250 pS; Km = 33 mM) displays long-lasting open events which are much more frequent at positive than at negative voltages. A major subconducting state about 45% of the fully-open state current amplitude was occasionally observed at all voltages. The voltage-dependence of the open probability displays a sigmoid relationship that was fitted by the Boltzmann equation and expressed in terms of thermodynamic parameters, namely the free energy (delta Gi) and the effective gating charge (Zs): delta Gi = 0.27 kcal/mol and Zs = -1.19 in 250 mM potassium gluconate (K-gluconate). Kinetic analyses also confirmed the voltage-dependent gating behavior of this channel, and indicate the implication of at least two open and three closed states. The diaphragm SR K+ channel shares several biophysical properties with the cardiac isoform: g = 180 pS, delta Gi = 0.75 kcal/mol, Zs = -1.45 in 150 mM K-gluconate, and a similar sigmoid P(o)/voltage relationship. Little is known about the regulation of the diaphragm and cardiac SR K+ channels. The conductance and gating of these channels were not influenced by physiological concentrations of Ca2+ (0.1 microM-1 mM) or Mg2+ (0.25-1 mM), as well as by cGMP (25-100 microM), lemakalim (1-100 microM), glyburide (up to 10 microM) or charybdotoxin (45-200 nM), added either to the cis or to the trans chamber. The apparent lack of biochemical or pharmacological modulation of these channels implies that they are not related to any of the well characterized surface membrane K+ channels. On the other hand, their voltage sensitivity strongly suggests that their activity could be modulated by putative changes in SR membrane potential that might occur during calcium fluxes.

Conducting and voltage-dependent behaviors of the native and purified SR Ca2+-release channels from the canine diaphragm.

The ryanodine-sensitive Ca2+-release channel of the canine diaphragm sarcoplasmic reticulum (SR) was characterized using biochemical assays and the planar lipid bilayer technique. Diaphragm SR membranes have a [3H]ryanodine-binding capacity (Bmax) of 1.2 pmol/mg protein and a binding affinity (K(D)) of 6.3 nM. The conductance of the native channel was 330 pS in 50 mM/250 mM trans/cis CsCH3SO3 and was reduced to 71 pS by 10 mM Ca2+ trans. The Ca2+-release channel was purified as a 400 kDa protein on SDS-PAGE and displayed a conductance of 715 pS in 200 mM KCl. The native and purified Ca2+ channels were activated by micromolar Ca2+ and ATP and inhibited by Mg2+, ryanodine and ruthenium red. Although diaphragm muscle contraction was shown to depend on extracellular Ca2+ like cardiac muscles, we provide evidence that the diaphragm SR Ca2+-release channel may be classified as a skeletal ryanodine receptor isoform. First, the IC50 for [3H]ryanodine binding was in the same range as estimated for skeletal SR, with 20 nM. Second, the channel was maximally activated by 10-30 microM cytoplasmic Ca2+ and inhibited at higher concentrations. Third, ryanodine binding to the diaphragm SR was less sensitive to Ca2+ than cardiac SR, with EC50, values of 50 and 1 microM, respectively. Finally, Ca2+-release activity and [3H]ryanodine binding capacity of the diaphragm and skeletal SR were similarly more sensitive to Mg2+ than cardiac SR. Together, these results suggest a predominantly skeletal-type of excitation-contraction coupling in the diaphragm.

Suppression of Ca(2+)-dependent heat production in mouse skeletal muscle by high fish oil consumption.

The energy dissipation associated with calcium homeostasis amounts to more than 20% of muscle energy expenditure (EE) at rest and can be quantified from microcalorimetric measurements of heat production in response to chemical modulators of sarcoplasmic reticulum (SR) Ca2+ release. Using this approach, Ca(2+)-dependent heat production in both red- and white-fiber muscles from mice fed a high-fat (HF) diet rich in fish oil was found to be significantly lower than in other groups fed HF diets rich in saturated fat (hydrogenated coconut oil) or n-6 polyunsaturated fats corn oil) and in a group fed a low-fat diet. These findings reveal a potentially specific effect of fish oil on muscle-cell energy metabolism via interference with sarcoplasmic calcium homeostasis, and raise the possibility that modification of the energy cost for intracellular calcium homoeostasis may be a cellular mechanism by which diet could modulate skeletal muscle thermogenesis and whole-body EE.

Smooth muscle energetic in the pig coronary artery during a calcium-dependent and a calcium-independent isometric contraction.

Heat production by resting smooth muscle, was measured with a heat-flux micro calorimeter on cut-open segments of pig coronary artery superfused at 30 degrees C, was 0.93+/-0.06 (n=16) mW/g wet weight. Time courses of the increases in isometric tension and heat production with respect to basal during sustained supra maximal acetylcholine stimulation were qualitatively similar: initial peak tapering down to a supra basal plateau. Mean tension-associated heat production over 1 h was 0.16 J/g. During sustained exposure to phorbol 12,13-dibutyrate, supra basal tension and--with a 5-10 min initial delay--supra basal heat progressively increased to a plateau in about 40 min. Mean tension-associated heat production over 1 h was only 0.02 J/g with normal extracellular and intracellular mobilizable Ca2+ pools, and it was further reduced to 0.01 J/g with depleted Ca2+ pools. These results show that the maintenance--if not necessarily the building up--of tension under phorbol 12,13-dibutyrate does not entail any large dissipation of energy and is not dependent on the presence of normal Ca2+ pools.

Examination of the role of phosphorylation and phospholamban in the regulation of the cardiac sarcoplasmic reticulum Cl- channel.

Sarcoplasmic reticulum (SR) vesicles were prepared from either canine or sheep heart and fused into lipid bilayers to study their ionic channels. A 92 +/- 5 pS anion-selective channel was recorded in asymmetric 50 mM trans/250 mM cis CsCl buffer system. Reversal potentials and theoretical equilibrium potentials for Cl-ions obtained under various experimental conditions allowed us to confirm the Cl- selectivity of this SR channel. The majority (69%) of channel recordings (n = 45) displayed steady-state kinetics and a slight voltage dependency of the open probability. However, 31% of the channels inactivated after their incorporation. We now report that the channel might be reactivated by depolarizing voltage steps. Furthermore, the use of either PKA or PKG in association with adequate phosphorylating buffers lengthens the deactivation process at the end of the voltage pulses, but does not prevent the inactivation. It was assumed that the change in gating mode was due to a voltage-sensitive association/dissociation mechanism with a phosphorylated protein of the SR membrane such as phospholamban (PL). We demonstrated that a specific monoclonal antibody raised against canine PL inhibited the activity of the channel and prevented its reactivation by depolarizing steps. 400 to 800 ng/ml of Anti-PL Ab consistently and sequentially turned off the channel activities. In contrast, heat inactivated Anti-PL Ab had no effect. We propose that phospholamban may be a primer of the SR Cl- channel whereby Cl- anions would play the role of counter-charge carrier during rapid Ca2+ release and Ca2+ uptake by the SR.

Decreased rates of Ca(2+)-dependent heat production in slow- and fast-twitch muscles from the dystrophic (mdx) mouse.

Using a newly developed microcalorimetric approach to assess the rate of energy expenditure for intracellular [Ca2+] homeostasis in isolated muscles at rest, we found this was lower in mdx than in control mouse muscles, by 62% and 29% in soleus and extensor digitorum longus, respectively. Differences in total and Ca(2+)-dependent rates of specific heat production between mdx and control were enhanced during sustained, KCl-induced stimulation of energy dissipation. These results suggest that the low sarcoplasmic energy status of dystrophic muscles is not due to any excessive energy expenditure for intracellular [Ca2+] homeostasis.

Defective regulation of energy metabolism in mdx-mouse skeletal muscles.

Our previous finding of a reduced energy metabolism in slow- and fast-twitch skeletal muscle fibres from the murine model of Duchenne muscular dystrophy (the mdx mouse) led us to examine the importance of intracellular glucose availability for a normal energy turnover. To this end, basal and KCl-stimulated (20.9 mM total extracellular K+) rates of glucose uptake (GUP) and heat production were measured in isolated, glucose-incubated (5 mM) soleus and extensor digitorum longus muscles from mdx and control C57B1/10 mice, in the presence and in the absence of insulin (1.7 nM). Under all conditions and for both muscle types, glucose uptake values for mdx and control muscles were similar although heat production was lower in mdx muscles. The marked stimulation of GUP by insulin in both mdx and control muscles had only minor effects on heat production. In contrast, glucose deprivation or inhibition of glycolysis with 2-deoxy-D-glucose (5 mM) significantly decreased heat production in control muscles only, which attenuated, although did not suppress, the difference in basal heat production between mdx and control muscles. Stimulation of heat production by a short-chain fatty acid salt (octanoate, 2 mM) was significantly less marked in mdx than in control muscles. Increased cytoplasmic synthesis of CoA by addition of 5 mM pantothenate (vitamin B5) increased the thermogenic response to glucose more in mdx than in control muscles. We conclude that the low energy turnover in mdx-mouse muscle fibres is not due to a decrease of intracellular glucose availability, but rather to a decreased oxidative utilization of glucose and free fatty acids. We suggest that some enzyme complex of the tricarboxylic acid cycle or inefficiency of CoA transport in the mitochondria could be involved.

Dystrophin-dependent efficiency of metabolic pathways in mouse skeletal muscles.

Muscles from the mdx mouse (X-linked genetic disorder similar to Duchenne muscular dystrophy) lack dystrophin-associated transsarcolemmal proteins and show reduced maintenance metabolic rates. Here, microcalorimetric comparisons of metabolic stimulation by exogenous substrates in isolated muscles revealed substrate-selective limitation of chemical reaction rates through both glycolytic and TCA-cycle pathways, identical in slow- and fast-twitch mdx muscles. This systemic approach, as opposed to comparisons of single-enzyme activities, sheds new light on the function of dystrophin and associated proteins. The in vivo efficiency of metabolic pathways may depend on stabilization of enzyme complexes by dystrophin-associated elements of the cytoskeleton.

Components of energy expenditure in the mdx mouse model of Duchenne muscular dystrophy.

Previous observations showing that basal heat production rates and glucose metabolism were reduced in mdx mouse skeletal muscles incubated in vitro led us to study the components of total energy expenditure by open-circuit indirect calorimetry in the intact, free-moving mdx mouse. Our purpose was to verify if the mdx mouse exhibited whole-body alterations in energy metabolism. The results revealed that total and basal energy expenditure, as well as spontaneous activity, energetic cost of activity, and, therefore, energy expended in relation to activity were not significantly different in C57B1/10 (control) and in dystrophic (mdx) mice. In contrast, the thermic effect of food was 32% larger in mdx than in control mice and was accompanied by significant differences in post-prandial glucose and lipid oxidation. The present in vivo study could not show a direct demonstration that impaired glucose metabolism by skeletal muscles participated in this phenomenon. However, since post-prandial glucose metabolism by skeletal muscles contributes a significant part of the thermic effect of food, the present data are in line with previous studies in vitro that show that mdx mouse skeletal muscles probably suffer an impaired control of their energy metabolism.

Ca(2+)-dependent heat production under basal and near-basal conditions in the mouse soleus muscle.

1. The rate of energy expended for the clearance of sarcoplasmic Ca2+ by sarcoreticular Ca2+ uptake process(es), plus the concomitant metabolic reactions, was evaluated from measurements of resting heat production by mouse soleus muscle before and after indirect inhibition of Ca2+ uptake by sarcoplasmic reticulum (SR). 2. Direct inhibition of the Ca2+, Mg(2+)-ATPase of SR membrane in intact muscle preparations exposed to the specific inhibitor 2,5-di(tert-butyl-1,4-benzohydroquinone (tBuBHQ) slowly increased the rate of heat production (E). Indirect inhibition of SR Ca2+ uptake was obtained by reducing sarcoplasmic Ca2+ concentration (Ca2+i) as a consequence of reducing Ca2+ release from the SR using dantrolene sodium. This promptly decreased E by 12%. Exposure of the preparations to an Mg(2+)-enriched environment (high Mg2+) or to the chemical phosphatase 2,3-butanedione monoxime (BDM), two other procedures aimed at decreasing SR Ca2+ release, also acutely decreased E, by 20 and 24%, respectively. 3. Subthreshold-for-contracture depolarization of the sarcolemma achieved by increasing extracellular K+ concentration to 11.8 mM induced a biphasic increase of E: an initial peak to 290% of basal E, followed by a plateau phase at 140% of basal E during which resting muscle tension was increased by less than 3%. Most, if not all, of the plateau-phase metabolic response was quickly suppressed by dantrolene or high Mg2+ or BDM. Another means of increasing SR Ca2+ cycling was to partially remove the calmodulin-dependent control of SR Ca2+ release using the calmodulin inhibitor W-7. The progressive increase in E with 30 microM-W-7 was largely reduced by dantrolene or high Mg2+ or BDM. 4. In the presence of either dantrolene or BDM to prevent the effect of W-7 on SR Ca2+ release, exposure of the muscle to W-7 acutely suppressed about 3% of E. This and the above results confirm that the plasmalemmal, calmodulin-dependent Ca(2+)-ATPase, although a qualitatively essential part of the Ca2+i homeostatic system of the cell, can only be responsible for a very minor part of the energy expenditure devoted to the homeostasis of Ca2+i. Active Ca2+ uptake by SR which, at least in the submicromolar range of Ca2+i, is expected to be responsible for most of this Ca(2+)-dependent energy expenditure, might dissipate up to 25-40% of total metabolic energy in the intact mouse soleus under basal and near-basal conditions.

Reconstitution of ionic channels from inner and outer membranes of mammalian cardiac nuclei.

Recent reports suggest that the nuclear envelope possesses specific ion transport mechanisms that regulate the electrolyte concentrations within the nucleoplasm and perinuclear space. In this work, intact nuclei were isolated from sheep cardiac cells. After chromatin digestion, the nuclear envelopes were sonicated and four nuclear vesicle populations were separated by sucrose step gradients (SF1-SF4). These fractions were compared by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their protein content was analyzed by Western blot, using lamin and SEC 61 antibodies. The lamins, which are associated with the inner nuclear membrane, were present in three fractions, SF2, SF3, and SF4, with a lower amount in SF2. The SEC 61 protein, a marker of the rough endoplasmic reticulum, was detected in small amounts in SF1 and SF2. Upon fusion of vesicles into bilayers, the activities of nuclear ionic channels were recorded in 50 mM trans/250 mM cis KCl or CsCl, pH 7.2. Two types of Cl- selective channels were recorded: a large conducting 150-180-pS channel displaying substates, and a low conducting channel of 30 pS. They were both spontaneously active into bilayers, and their open probability was poorly voltage dependent at negative voltages. Retinoic acid (10(-8) M) increases the po of the large Cl- conducting channel, whereas ATP modifies the kinetics of the low conductance anion selective channel. Our data also suggest that this anionic channel is mainly present in the SF3 and SF4 population. The presence of a 181 +/- 10 pS cation-selective channel was consistently observed in the SF2 population. The behavior of this channel was voltage dependent in the voltage range -80 to +60 mV. Furthermore, we report for the first time the activity of a channel exclusively present in the SF3 and SF4 fractions, shown to contain mainly inner membrane vesicles. This cation selective channel displays a 75-pS conductance in 50 mM trans/250 mM cis K-gluconate. It is concluded that the bilayer reconstitution technique is an attractive approach to studying the electrophysiological properties of the inner and outer membranes of the nuclear envelope.

Biochemical regulation of sarcoplasmic reticulum Cl- channel from human atrial myocytes: involvement of phospholamban.

Sarcoplasmic reticulum (SR) membrane vesicles derived from human atrium were characterized by specific ryanodine binding assay and fused into planar lipid bilayers. The tritiated form of the alkaloid bound to its receptor with a K(D) of 2.2 nM and a Bmax of 268 fmol/mg protein respectively. Special emphasis was placed on an anion-selective channel present in the SR membrane, which exhibited a mean conductance value of 67 pS when recorded in asymmetrical 50 mM trans/250 mM cis CsCl buffer system and a sensitivity to SITS (1 to 100 microM). Single and multiple channel activities displayed low voltage sensitivity and variability in its gating behavior which might result in spontaneous channel inactivation. However, the majority of the recordings (60%) resulted in a steady-state high open probability. The inactivated channel could be transiently reactivated with depolarizing voltage steps. This behavior is very similar, if not identical, to that observed for the SR Cl- channel in ventricular cells. The inactivation process is probably not directly related to a phosphorylation/dephosphorylation mechanism since PKA and PKG in presence of an adequate phosphorylation cocktail failed to reactivate the SR Cl- channel. In contrast, the use of a monoclonal anti-phospholamban antibody allowed the inhibition of the activity of the anionic channels. These results suggest that the regulation of the human atrial SR Cl- channel is dependent upon an interaction with phospholamban, which was clearly identified in our atrial preparations by Western blot analysis using monoclonal antibody.

Mini- and full-length dystrophin gene transfer induces the recovery of nitric oxide synthase at the sarcolemma of mdx4cv skeletal muscle fibers.

In normal skeletal muscle fibers, dystrophin accumulates at the cytoplasmic face of the sarcolemma where it associates with dystrophin-associated proteins (DAPs). Several studies have recently shown that the neuronal isoform of nitric oxide synthase (nNOS) is also located at the sarcolemma, and that this membrane localization is mediated through interactions of nNOS with one of the DAPs, namely alpha 1-syntrophin. Since the lack of dystrophin in muscle fibers from Duchenne muscular dystrophy patients and mdx mice is accompanied by an absence of sarcolemmal nNOS, we examined in the present study, whether dystrophin gene replacement would lead to the restoration of nNOS at its appropriate subcellular location. To this end, tibialis anterior muscles from mdx4cv mice were directly injected with plasmid DNA encoding either full-length (pRSV-dys) or mini-(pRSV-dyB; lacking exons 17-48) dystrophin. For these experiments, we chose to study 10-week-old mdx4cv mice since at this developmental stage, muscles from these mice have already undergone several cycles of degeneration-regeneration. Immunofluorescence experiments performed on serial cross-sections revealed that approximately 50% of the dystrophin-positive fibers also exhibited significant levels of nNOS at their sarcolemma 2 weeks following gene transfer with pRSV-dys. Similar results were obtained with pRSV-dyB indicating that exons 17-48 of the dystrophin gene are not essential for the correct localization of nNOS in skeletal muscle fibers. Taken together with the recent demonstration that dystrophin gene transfer leads to significant physiological benefits our results suggest that dystrophin gene therapy using full-length or truncated dystrophin, also induces a rapid recovery of biochemical functions.

Mini-dystrophin gene transfer in mdx4cv diaphragm muscle fibers increases sarcolemmal stability.

To date, all dystrophin gene transfer studies have been performed on mdx hindlimb skeletal muscles which in comparison to the severe deficits seen in muscles from patients afflicted with Duchenne muscular dystrophy (DMD), exhibit only modest morphological and functional changes. Since the mdx diaphragm muscle presents the same pathophysiological alterations characteristic of DMD muscles, we therefore injected recombinant plasmid DNA encoding the dystrophin mini-gene (pRSVdy-B) into diaphragm muscles of 10-week-old mdx4cv mice and examined the physiological consequences of dystrophin expression in a muscle that has undergone a phase of massive degeneration and regeneration. Immunoperoxidase and immunofluorescence experiments revealed that 1 and 3 weeks following gene transfer, approximately 17% of the fibers in a bundle of diaphragm muscle expressed dystrophin at the sarcolemma. Most importantly, this level of dystrophin expression was sufficient to protect all fibers present within these diaphragm muscle bundles from the damaging effects of repetitive lengthening contractions. In addition, dystrophin expression partially restored the ability of transduced mdx4cv muscle bundles to generate isometric tetanic tension following lengthening contractions. These results show that mini-dystrophin expression leads to rapid and significant functional improvements in diaphragm muscles of mdx4cv mice. Although these data provide encouraging results for future therapeutic strategies aimed at curing DMD, additional work will none the less be necessary to determine the full impact of dystrophin gene replacement. In this context, it is clear from the data presented here that the diaphragm muscle of the mdx mouse is an invaluable model system to address this critical issue.