Jerry P. Eu

The Skeletal Muscle Calcium Release Channel: Coupled O2 Sensor and NO Signaling Functions

Ion channels have been studied extensively in ambient O2 tension (pO2), whereas tissue PO2 is much lower. The skeletal muscle calcium release channel/ryanodine receptor (RyR1) is one prominent example. Here we report that PO2 dynamically controls the redox state of 6-8 out of 50 thiols in each RyR1 subunit and thereby tunes the response to NO. At physiological pO2, nanomolar NO activates the channel by S-nitrosylating a single cysteine residue. Among sarcoplasmic reticulum proteins, S-nitrosylation is specific to RyR1 and its effect on the channel is calmodulin dependent. Neither activation nor S-nitrosylation of the channel occurs at ambient PO2. The demonstration that channel cysteine residues subserve coupled O2 sensor and NO regulatory functions and that these operate through the prototypic allosteric effector calmodulin may have general implications for the regulation of redox-related systems.

Cysteine-3635 is responsible for skeletal muscle ryanodine receptor modulation by NO.

We have shown previously that at physiologically relevant oxygen tension (pO2 ≈ 10 mmHg), NO S-nitrosylates 1 of ≈50 free cysteines per ryanodine receptor 1 (RyR1) subunit and transduces a calcium-sensitizing effect on the channel by means of calmodulin (CaM). It has been suggested that cysteine-3635 is part of a CaM-binding domain, and its reactivity is attenuated by CaM [Porter Moore, C., Zhang, J. Z., Hamilton, S. L. (1999) J. Biol. Chem. 274, 36831–36834]. Therefore, we tested the hypothesis that the effect of NO was mediated by C3635. The full-length RyR1 single-site C3635A mutant was generated and expressed in HEK293 cells. The mutation resulted in the loss of CaM-dependent NO modulation of channel activity and reduced S-nitrosylation by NO to background levels but did not affect NO-independent channel modulation by CaM or the redox sensitivity of the channel to O2 and glutathione. Our results reveal that different cysteines within the channel have been adapted to serve in nitrosative and oxidative responses, and that S-nitrosylation of the cysteine-containing CaM-binding domain underlies the mechanism of CaM-dependent regulation of RyR1 by NO.

STIM1 signalling controls store-operated calcium entry required for development and contractile function in skeletal muscle

It is now well established that stromal interaction molecule 1 (STIM1) is the calcium sensor of endoplasmic reticulum stores required to activate store-operated calcium entry (SOC) channels at the surface of non-excitable cells. However, little is known about STIM1 in excitable cells, such as striated muscle, where the complement of calcium regulatory molecules is rather disparate from that of non-excitable cells. Here, we show that STIM1 is expressed in both myotubes and adult skeletal muscle. Myotubes lacking functional STIM1 fail to show SOC and fatigue rapidly. Moreover, mice lacking functional STIM1 die perinatally from a skeletal myopathy. In addition, STIM1 haploinsufficiency confers a contractile defect only under conditions where rapid refilling of stores would be needed. These findings provide insight into the role of STIM1 in skeletal muscle and suggest that STIM1 has a universal role as an ER/SR calcium sensor in both excitable and non-excitable cells.

Regulation of ryanodine receptors by reactive nitrogen species

The ryanodine receptors (RyRs) are large intracellular calcium release channels that play an important role in the control of the calcium levels in excitable and non-excitable cells. Many endogenous modulators such as Mg2+, ATP, or calmodulin can affect the channel activities of the three known mammalian RyR isoforms. RyRs also are known to be redox-responsive. However, the molecular basis and the physiological relevance of redox modulation of RyRs are unclear. Recent evidence suggests that nitric oxide (NO) and related molecules may be endogenous regulators of the skeletal and cardiac muscle RyRs. The two tissues express nitric oxide synthases (NOSs), and NO or NO-related species have been shown to affect Ca2+ release channel activities directly via covalent modifications of thiol groups. Both an oxidative and a nitrosative modification of RyRs have been described, leading to either a reversible or irreversible alteration of RyR ion channel activity. Additional mechanisms of regulation may include cyclic GMP-dependent signaling pathways and NO modification of RyR regulatory proteins such as the surface membrane L-type Ca2+ channel. Modification of RyRs by NO may influence a variety of physiological functions such as insulin release, vasomotor control, and muscle contraction.

Concerted regulation of skeletal muscle contractility by oxygen tension and endogenous nitric oxide

It is generally accepted that inhibition of nitric oxide synthase (NOS) facilitates, and thus nitric oxide (NO) inhibits, contractility of skeletal muscle. However, standard assessments of contractility are carried out at a nonphysiological oxygen tension [partial pressure of oxygen (pO2)] that can interfere with NO signaling (95% O2). We therefore examined, in normal and neuronal NOS (nNOS)-deficient mice, the influence of pO2 on whole-muscle contractility and on myocyte calcium flux and sarcomere shortening. Here, we demonstrate a significant enhancement of these measures of muscle performance at low physiological pO2 and an inhibitory influence at higher physiological pO2, which depend on endogenous nNOS. At 95% O2 (which produces oxidative stress; muscle core pO2 ≈400 mmHg), force production is enhanced but control of contractility by NO/nitrosylation is greatly attenuated. In addition, responsivity to pO2 is altered significantly in nNOS mutant muscle. These results reveal a fundamental role for the concerted action of NO and O2 in physiological regulation of skeletal muscle contractility, and suggest novel molecular aspects of myopathic disease. They suggest further that the role of NO in some cellular systems may require reexamination.

Mice Lacking Homer 1 Exhibit a Skeletal Myopathy Characterized by Abnormal Transient Receptor Potential Channel Activity

ABSTRACT Transient receptor potential (TRP) channels are nonselective cation channels, several of which are expressed in striated muscle. Because the scaffolding protein Homer 1 has been implicated in TRP channel regulation, we hypothesized that Homer proteins play a significant role in skeletal muscle function. Mice lacking Homer 1 exhibited a myopathy characterized by decreased muscle fiber cross-sectional area and decreased skeletal muscle force generation. Homer 1 knockout myotubes displayed increased basal current density and spontaneous cation influx. This spontaneous cation influx in Homer 1 knockout myotubes was blocked by reexpression of Homer 1b, but not Homer 1a, and by gene silencing of TRPC1. Moreover, diminished Homer 1 expression in mouse models of Duchennes muscular dystrophy suggests that loss of Homer 1 scaffolding of TRP channels may contribute to the increased stretch-activated channel activity observed in mdx myofibers. These findings provide direct evidence that Homer 1 functions as an important scaffold for TRP channels and regulates mechanotransduction in skeletal muscle.

Regulation of the Cardiac Muscle Ryanodine Receptor by O2 Tension and S-Nitrosoglutathione

The cardiac and skeletal muscle sarcoplasmic reticulum ryanodine receptor Ca(2+) release channels contain thiols that are potential targets of endogenously produced reactive oxygen and nitrogen intermediates. Previously, we showed that the skeletal muscle ryanodine receptor (RyR1) has O(2)-sensitive thiols; only when these thiols are in the reduced state (pO(2) approximately 10 mmHg) can physiological concentrations of NO (nanomolar) activate RyR1. Here, we report that cardiac muscle ryanodine receptor (RyR2) activity also depends on pO(2), but unlike RyR1, RyR2 was not activated or S-nitrosylated directly by NO. Rather, activation and S-nitrosylation of RyR2 required S-nitrosoglutathione. The effects of peroxynitrite were indiscriminate on RyR1 and RyR2. Our results indicate that both RyR1 and RyR2 are pO(2)-responsive yet point to different mechanisms by which NO and S-nitrosoglutathione influence cardiac and skeletal muscle sarcoplasmic reticulum Ca(2+) release.

Impaired adenosine-5'-triphosphate release from red blood cells promotes their adhesion to endothelial cells: a mechanism of hypoxemia after transfusion.

Objective:Transfusion of red blood cells has been linked to disappointing clinical outcomes in the critically ill, but specific mechanisms of organ dysfunction after transfusion remain poorly understood. We tested the hypothesis that red blood cell storage impairs the ability of red blood cells to release adenosine-5′-triphosphate and that impaired adenosine-5′-triphosphate release was injurious in vivo, in part through increased red blood cell adhesion. Design:Prospective, controlled, mechanistic study. Setting:University research laboratory. Subjects:Human and mouse blood donors; nude mouse transfusion recipients. Interventions:Manipulation of adenosine-5′-triphosphate release, supplemental adenosine-5′-triphosphate, and antibodies to red blood cell and endothelial adhesion receptors were used in vitro and in vivo to probe the roles of released adenosine-5′-triphosphate and adhesion in responses to (transfused) red blood cells. Measurements and Main Results:The ability of stored red blood cells to release adenosine-5′-triphosphate declined markedly within 14 days after collection despite relatively stable levels of adenosine-5′-triphosphate within the red blood cells. Inhibiting adenosine-5′-triphosphate release promoted the adhesion of stored red blood cells to endothelial cells in vitro and red blood cell sequestration in the lungs of transfused mice in vivo. Unlike transfusion of fresh human red blood cells, stored red blood cell transfusion in mice decreased blood oxygenation and increased extravasation of red blood cells into the lungs alveolar air spaces. Similar findings were seen with transfusion of fresh red blood cells treated with the adenosine-5′-triphosphate release inhibitors glibenclamide and carbenoxolone. These findings were prevented by either coinfusion of an adenosine-5′-triphosphate analog or pretransfusion incubation of the red blood cells with an antibody against the erythrocyte adhesion receptor Landsteiner-Wiener (intercellular adhesion molecule-4). Conclusions:The normal flow of red blood cells in pulmonary microvessels depends in part on the release of antiadhesive adenosine-5′-triphosphate from red blood cells, and storage-induced deficiency in adenosine-5′-triphosphate release from transfused red blood cells may promote or exacerbate microvascular pathophysiology in the lung, in part through increased red blood cell adhesion.

Knocking Down Type 2 but Not Type 1 Calsequestrin Reduces Calcium Sequestration and Release in C2C12 Skeletal Muscle Myotubes

We examined the roles of type 1 and type 2 calsequestrins (CSQ1 and CSQ2) in stored Ca2+ release of C2C12 skeletal muscle myotubes. Transduction of C2C12 myoblasts with CSQ1 or CSQ2 small interfering RNAs effectively reduced the expression of targeted CSQ protein to near undetectable levels. As compared with control infected or CSQ1 knockdown myotubes, CSQ2 and CSQ1/CSQ2 knockdown myotubes had significantly reduced stored Ca2+ release evoked by activators of intracellular Ca2+ release channel/ryanodine receptor (10 mm caffeine, 200 μm 4-chloro-m-cresol, or 10 mm KCl). Thus, CSQ1 is not essential for effective stored Ca2+ release in C2C12 myotubes despite our in vitro studies suggesting that CSQ1 may enhance ryanodine receptor channel activity. To determine the basis of the reduced stored Ca2+ release in CSQ2 knockdown myotubes, we performed immunoblot analyses and found a significant reduction in both sarco/endoplasmic reticulum Ca2+-ATPase and skeletal muscle ryanodine receptor proteins in CSQ2 and CSQ1/CSQ2 knockdown myotubes. Moreover, these knockdown myotubes exhibited reduced Ca2+ uptake and reduced stored Ca2+ release by UTP (400 μm) that activates a different family of intracellular Ca2+ release channels (inositol 1,4,5-trisphosphate receptors). Taken together, our data suggest that knocking down CSQ2, but not CSQ1, leads to reduced Ca2+ storage and release in C2C12 myotubes.

Excitation-Contraction Coupling in Airway Smooth Muscle

Excitation-contraction (EC) coupling in striated muscles is mediated by the cardiac or skeletal muscle isoform of voltage-dependent L-type Ca2+ channel (Cav1.2 and Cav1.1, respectively) that senses a depolarization of the cell membrane, and in response, activates its corresponding isoform of intracellular Ca2+ release channel/ryanodine receptor (RyR) to release stored Ca2+, thereby initiating muscle contraction. Specifically, in cardiac muscle following cell membrane depolarization, Cav1.2 activates cardiac RyR (RyR2) through an influx of extracellular Ca2+. In contrast, in skeletal muscle, Cav1.1 activates skeletal muscle RyR (RyR1) through a direct physical coupling that negates the need for extracellular Ca2+. Since airway smooth muscle (ASM) expresses Cav1.2 and all three RyR isoforms, we examined whether a cardiac muscle type of EC coupling also mediates contraction in this tissue. We found that the sustained contractions of rat ASM preparations induced by depolarization with KCl were indeed partially reversed (∼40%) by 200 μm ryanodine, thus indicating a functional coupling of L-type channels and RyRs in ASM. However, KCl still caused transient ASM contractions and stored Ca2+ release in cultured ASM cells without extracellular Ca2+. Further analyses of rat ASM indicated that this tissue expresses as many as four L-type channel isoforms, including Cav1.1. Moreover, Cav1.1 and RyR1 in rat ASM cells have a similar distribution near the cell membrane in rat ASM cells and thus may be directly coupled as in skeletal muscle. Collectively, our data implicate that EC-coupling mechanisms in striated muscles may also broadly transduce diverse smooth muscle functions.