Signalling in sarcomeres in development and disease

Sarcomeres are the smallest contractile units of heart and skeletal muscles and are essential for generation and propagation of mechanical force in these striated muscles. During the last decades it has become increasingly clear that components of sarcomeres also play a fundamental role in signal transduction in physiological and pathophysiological conditions. Mutations or misexpression of both sarcomeric contractile and non-contractile proteins have been associated with a variety of cardiac diseases. Moreover, re-expression of foetal sarcomeric proteins or isoforms during cardiac disease can be observed, emphasising the importance of understanding signalling in sarcomeres in both development and disease. The prospective of pharmacological intervention at the level of the sarcomere is now emerging and may lead to novel therapeutic strategies for the treatment of cardiac and skeletal muscle diseases. These aspects will be discussed in this brief review and recent findings, which led to novel insights into the role of the sarcomeric cytoskeleton in muscle development and disease, will be highlighted.     

Differential response of stress fibers and myofibrils to gelsolin

The actin-severing activity of human platelet gelsolin was analyzed on embryonic skeletal and cardiac myofibrils, and on stress fibers in non-muscle cells. These subcellular structures, although in all three cell types composed of contractile proteins arranged in sarcomeric units, were found to respond differently to gelsolin. The myofibrils in permeabilized myotubes or cardiac cells, as well as in living, microinjected muscle cells proved resistant to a wide concentration range of gelsolin. The same was found for the "mini-sarcomeres" which are seen in developing muscle cells. In contrast, stress fibers in microinjected fibroblasts or epithelial cells, as well as in permeabilized cells, were broken down rapidly by the platelet gelsolin. We conclude from these results that the mini-sarcomeres in embryonic myotubes and cardiac myocytes are not identical with stress fibers.     

Ryanodine receptor channelopathies

Ryanodine receptors (RyR) are the Ca2+ release channels of sarcoplasmic reticulum that provide the majority of the [Ca2+] necessary to induce contraction of cardiac and skeletal muscle cells. In their cellular environment, RyRs are exquisitely regulated by a variety of cytosolic factors and accessory proteins so that their output signal (Ca2+) induces cell contraction without igniting signaling pathways that eventually lead to contractile dysfunction or pathological cellular remodeling. Here we review how dysfunction of RyRs, most commonly expressed as enhanced Ca2+ release at rest (skeletal muscle) or during diastole (cardiac muscle), appears to be the fundamental mechanism underlying several genetic or acquired syndromes. In skeletal muscle, malignant hyperthermia and central core disease result from point mutations in RYR1, the skeletal isoform of RyRs. In cardiac muscle, RYR2 mutations lead to catecholaminergic polymorphic ventricular tachycardia and other cardiac arrhythmias. Lastly, an altered phosphorylation of the RyR2 protein may be involved in some forms of congestive heart failure.     

Co-expression of skeletal and cardiac troponin T decreases mouse cardiac function

In contrast to skeletal muscles that simultaneously express multiple troponin T (TnT) isoforms, normal adult human cardiac muscle contains a single isoform of cardiac TnT. To understand the significance of myocardial TnT homogeneity, we examined the effect of TnT heterogeneity on heart function. Transgenic mouse hearts overexpressing a fast skeletal muscle TnT together with the endogenous cardiac TnT was investigated in vivo and ex vivo as an experimental system of concurrent presence of two classes of TnT in the adult cardiac muscle. This model of myocardial TnT heterogeneity produced pathogenic phenotypes: echocardiograph imaging detected age-progressive reductions of cardiac function; in vivo left ventricular pressure analysis showed decreased myocardial contractility; ex vivo analysis of isolated working heart preparations confirmed an intrinsic decrease of cardiac function in the absence of neurohumoral influence. The transgenic mice also showed chronic myocardial hypertrophy and degeneration. The dominantly negative effects of introducing a fast TnT into the cardiac thin filaments to produce two classes of Ca(2+) regulatory units in the adult myocardium suggest that TnT heterogeneity decreases contractile function by disrupting the synchronized action during ventricular contraction that is normally activated as an electrophysiological syncytium.     

Accessibility of Myofilament Cysteines and Effects on ATPase Depend on the Activation State during Exposure to Oxidants

Signaling by reactive oxygen species has emerged as a major physiological process. Due to its high metabolic rate, striated muscle is especially subject to oxidative stress, and there are multiple examples in cardiac and skeletal muscle where oxidative stress modulates contractile function. Here we assessed the potential of cysteine oxidation as a mechanism for modulating contractile function in skeletal and cardiac muscle. Analyzing the cysteine content of the myofilament proteins in striated muscle, we found that cysteine residues are relatively rare, but are very similar between different muscle types and different vertebrate species. To refine this list of cysteines to those that may modulate function, we estimated the accessibility of oxidants to cysteine residues using protein crystal structures, and then sharpened these estimates using fluorescent labeling of cysteines in cardiac and skeletal myofibrils. We demonstrate that cysteine accessibility to oxidants and ATPase rates depend on the contractile state in which preparations are exposed. Oxidant exposure of skeletal and cardiac myofibrils in relaxing solution exposes myosin cysteines not accessible in rigor solution, and these modifications correspond to a decrease in maximum ATPase. Oxidant exposure under rigor conditions produces modifications that increase basal ATPase and calcium sensitivity in ventricular myofibrils, but these effects were muted in fast twitch muscle. These experiments reveal how structural and sequence variations can lead to divergent effects from oxidants in different muscle types.     

Spatial Ca(2+) distribution in contracting skeletal and cardiac muscle cells

The spatiotemporal distribution of intracellular Ca(2+) release in contracting skeletal and cardiac muscle cells was defined using a snapshot imaging technique. Calcium imaging was performed on intact skeletal and cardiac muscle cells during contractions induced by an action potential (AP). The sarcomere length of the skeletal and cardiac cells was approximately 2 micrometer. Imaging Rhod-2 fluorescence only during a very brief (7 ns) snapshot of excitation light minimized potential image-blurring artifacts due to movement and/or diffusion. In skeletal muscle cells, the AP triggered a large fast Ca(2+) transient that peaked in less than 3 ms. Distinct subsarcomeric Ca(2+) gradients were evident during the first 4 ms of the skeletal Ca(2+) transient. In cardiac muscle, the AP-triggered Ca(2+) transient was much slower and peaked in approximately 100 ms. In contrast to the skeletal case, there were no detectable subsarcomeric Ca(2+) gradients during the cardiac Ca(2+) transient. Theoretical simulations suggest that the subsarcomeric Ca(2+) gradients seen in skeletal muscle were detectable because of the high speed and synchrony of local Ca(2+) release. Slower asynchronous recruitment of local Ca(2+) release units may account for the absence of detectable subsarcomeric Ca(2+) gradients in cardiac muscle. The speed and synchrony of local Ca(2+) gradients are quite different in AP-activated contracting cardiac and skeletal muscle cells at normal resting sarcomere lengths.     

Phalloidin suppresses the force in nebulin-rich lamprey cardiac muscle

The effect of phalloidin, an agent detaching nebulin from actin in skeletal muscle, on the isometric force in lamprey skinned cardiac muscle, which has nebulin in amounts comparable to that in skeletal muscle, has been studied. We found that, unlike mammalian cardiac muscle expressing nebulin less abundantly and responding to phalloidin by a force increase, lamprey cardiac muscle responds to phalloidin by a force decrease (approximately 50% decrease), thereby resembling the response of skeletal muscle. These results support our hypothesis that nebulin detachment from actin underlies phalloidin-induced force loss and suggest a role of actin-nebulin interaction in contractile function.     

Stimulation of slow skeletal muscle fiber gene expression by calcineurin in vivo

Adult skeletal muscle fibers can be categorized into fast and slow twitch subtypes based on specialized contractile and metabolic properties and on distinctive patterns of muscle gene expression. Muscle fiber-type characteristics are dependent on the frequency of motor nerve stimulation and are thought to be controlled by calcium-dependent signaling. The calcium, calmodulin-dependent protein phosphatase, calcineurin, stimulates slow fiber-specific gene promoters in cultured skeletal muscle cells, and the calcineurin inhibitor, cyclosporin A, inhibits slow fiber gene expression in vivo, suggesting a key role of calcineurin in activation of the slow muscle fiber phenotype. Calcineurin has also been shown to induce hypertrophy of cardiac muscle and to mediate the hypertrophic effects of insulin-like growth factor-1 on skeletal myocytes in vitro. To determine whether activated calcineurin was sufficient to induce slow fiber gene expression and hypertrophy in adult skeletal muscle in vivo, we created transgenic mice that expressed activated calcineurin under control of the muscle creatine kinase enhancer. These mice exhibited an increase in slow muscle fibers, but no evidence for skeletal muscle hypertrophy. These results demonstrate that calcineurin activation is sufficient to induce the slow fiber gene regulatory program in vivo and suggest that additional signals are required for skeletal muscle hypertrophy.     

Phalloidin suppresses force in nebulin-rich lamprey cardiac muscle

We assessed the effect of phalloidin, known to detach nebulin from actin in skeletal myofibrils, on the isometric force of skinned lamprey cardiac muscle, which has nebulin in amounts comparable to that in skeletal muscle. In contrast to mammalian cardiac muscle, which contains much less nebulin and reacts to phalloidin only by an increase in force, the lamprey cardiac muscle responds to phalloidin by a pronounced (～ 50%) reduction in isometric force, thereby resembling the behavior of skeletal muscle. These results support our hypothesis that nebulin detachment from actin underlies phalloidin-induced force loss and suggest a role of actin-nebulin interaction in contractile function.     

The role of glycine (residue 89) in the central helix of EF-hand protein troponin-C exposed following amino-terminal alpha-helix deletion.

Because an N-terminal alpha-helical (N-helix) arm and a KGK-triplet (residues 88KGK90) in the central helix of troponin-C (TnC) are missing in calmodulin, several recent studies have attempted to elucidate the structure-function correlations of these units. Presently, with a family of genetically manipulated derivatives especially developed for this study and tested on permeabilized isolated single skeletal muscle fiber segments, we explored the specificities of the amino acid residues within the N-helix and the KGK-triplet in TnC. Noticeably, the amino acid compositions vary between the N-helices of the cardiac and skeletal TnC isoforms. On the other hand, the KGK-triplet is located similarly in both TnC isoforms. We previously indicated that deletion of the N-helix (mutant delta Nt) diminishes the tension obtained on activation with maximal calcium, but the contractile function is revived by the superimposed deletion of the 88KGK90-triplet (mutant delta Nt delta KGK; see Gulati J, Babu A, Su H, Zhang YF, 1993, J Biol Chem 268:11685-11690). Using this functional test, we find that replacement of Gly-89 with a Leu or an Ala could also overcome the contractile defect associated with N-helix deletion. On the other hand, replacement of the skeletal TnC N-helix with cardiac type N-helix was unable to restore contractile function. The findings indicate a destabilizing influence of Gly-89 residue in skeletal TnC and suggest that the N-terminal arm in normal TnC serves to moderate this effect. Moreover, specificity of the N-helix between cardiac and skeletal TnCs raises the possibility that resultant structural disparities are also important for the functional distinctions of the TnC isoforms.     

Smitin, a novel smooth muscle titin-like protein, interacts with myosin filaments in vivo and in vitro.

Smooth muscle cells use an actin-myosin II-based contractile apparatus to produce force for a variety of physiological functions, including blood pressure regulation and gut peristalsis. The organization of the smooth muscle contractile apparatus resembles that of striated skeletal and cardiac muscle, but remains much more poorly understood. We have found that avian vascular and visceral smooth muscles contain a novel, megadalton protein, smitin, that is similar to striated muscle titin in molecular morphology, localization in a contractile apparatus, and ability to interact with myosin filaments. Smitin, like titin, is a long fibrous molecule with a globular domain on one end. Specific reactivities of an anti-smitin polyclonal antibody and an anti-titin monoclonal antibody suggest that smitin and titin are distinct proteins rather than differentially spliced isoforms encoded by the same gene. Smitin immunofluorescently colocalizes with myosin in chicken gizzard smooth muscle, and interacts with two configurations of smooth muscle myosin filaments in vitro. In physiological ionic strength conditions, smitin and smooth muscle myosin coassemble into irregular aggregates containing large sidepolar myosin filaments. In low ionic strength conditions, smitin and smooth muscle myosin form highly ordered structures containing linear and polygonal end-to-end and side-by-side arrays of small bipolar myosin filaments. We have used immunogold localization and sucrose density gradient cosedimentation analyses to confirm association of smitin with both the sidepolar and bipolar smooth muscle myosin filaments. These findings suggest that the titin-like protein smitin may play a central role in organizing myosin filaments in the contractile apparatus and perhaps in other structures in smooth muscle cells.