Yassemi Capetanaki

Desmin Cytoskeleton ☆: A Potential Regulator of Muscle Mitochondrial Behavior and Function

Alterations in mitochondrial distribution and morphology are associated with normal cellular processes such as cell division and differentiation, as well as a variety of pathological conditions, including muscular dystrophy and cardiomyopathy. These observations have illuminated the necessity for a cellular machinery that mediates mitochondrial behavior and function. One important candidate member of this machinery is the cytoskeleton, all three members of which seem to associate with mitochondria. The role and significance of such association with the intermediate filament (IF) cytoskeleton in muscle was until recently completely unknown. Recent studies with desmin-deficient mice revealed the importance of desmin IFs in mitochondrial behavior and function. This review summarizes recent findings that link desmin cytoskeleton to muscle mitochondrial distribution and function. In particular, hypotheses are presented on the potential mechanism by which desmins absence from cardiac muscle leads to abnormal mitochondrial behavior and compromised function, potentially responsible for the development of dilated cardiomyopathy and heart failure in desmin-null mice.

Structural and Functional Roles of Desmin in Mouse Skeletal Muscle during Passive Deformation

Mechanical interactions between desmin and Z-disks, costameres, and nuclei were measured during passive deformation of single muscle cells. Image processing and continuum kinematics were used to quantify the structural connectivity among these structures. Analysis of both wild-type and desmin-null fibers revealed that the costamere protein talin colocalized with the Z-disk protein alpha-actinin, even at very high strains and stresses. These data indicate that desmin is not essential for mechanical coupling of the costamere complex and the sarcomere lattice. Within the sarcomere lattice, significant differences in myofibrillar connectivity were revealed between passively deformed wild-type and desmin-null fibers. Connectivity in wild-type fibers was significantly greater compared to desmin-null fibers, demonstrating a significant functional connection between myofibrils that requires desmin. Passive mechanical analysis revealed that desmin may be partially responsible for regulating fiber volume, and consequently, fiber mechanical properties. Kinematic analysis of alpha-actinin strain fields revealed that knockout fibers transmitted less shear strain compared to wild-type fibers and experienced a slight increase in fiber volume. Finally, linkage of desmin intermediate filaments to muscle nuclei was strongly suggested based on extensive loss of nuclei positioning in the absence of desmin during passive fiber loading.

Caspase Proteolysis of Desmin Produces a Dominant-negative Inhibitor of Intermediate Filaments and Promotes Apoptosis

Caspase cleavage of key cytoskeletal proteins, including several intermediate filament proteins, triggers the dramatic disassembly of the cytoskeleton that characterizes apoptosis. Here we describe the muscle-specific intermediate filament protein desmin as a novel caspase substrate. Desmin is cleaved selectively at a conserved Asp residue in its L1-L2 linker domain (VEMD↓M264) by caspase-6 in vitro and in myogenic cells undergoing apoptosis. We demonstrate that caspase cleavage of desmin at Asp263 has important functional consequences, including the production of an amino-terminal cleavage product, N-desmin, which is unable to assemble into intermediate filaments, instead forming large intracellular aggregates. Moreover, N-desmin functions as a dominant-negative inhibitor of filament assembly, both for desmin and the structurally related intermediate filament protein vimentin. We also show that stable expression of a caspase cleavage-resistant desmin D263E mutant partially protects cells from tumor necrosis factor-α-induced apoptosis. Taken together, these results indicate that caspase proteolysis of desmin at Asp263produces a dominant-negative inhibitor of intermediate filaments and actively participates in the execution of apoptosis. In addition, these findings provide further evidence that the intermediate filament cytoskeleton has been targeted systematically for degradation during apoptosis.

Desmin-related myopathy

van Spaendonck‐Zwarts KY, van Hessem L, Jongbloed JDH, de Walle HEK, Capetanaki Y, van der Kooi AJ, van Langen IM, van den Berg MP, van Tintelen JP. Desmin‐related myopathy.

Costameres: repeating structures at the sarcolemma of skeletal muscle.

Costameres, structures at the plasma membrane of skeletal muscle, are present in a rectilinear array that parallels the organization of the underlying contractile apparatus. Costameres have three major functions: to keep the plasma membrane, or sarcolemma, aligned and in register with nearby contractile structures; to protect the sarcolemma against contraction-induced damage; and to transmit some of the forces of contraction laterally, to the extracellular matrix. These functions require that costameres link the contractile apparatus through the membrane to the extracellular matrix. Mutations to key components of costameres cause these structures to lose their rectilinear organization and can result in muscle weakness or death. This article summarizes the evidence that costameres are composed of large complexes of integral and peripheral membrane proteins that are linked to the contractile apparatus by intermediate filaments and to the extracellular matrix by laminin. They also present evidence that costameres are altered when key costameric components are missing, as in a murine form of muscular dystrophy.

Regulation of adverse remodelling by osteopontin in a genetic heart failure model

AIMS Desmin, the muscle-specific intermediate filament protein, is a major target in dilated cardiomyopathy and heart failure in humans and mice. The hallmarks of desmin-deficient (des(-/-)) mice pathology include pronounced myocardial degeneration, extended fibrosis, and osteopontin (OPN) overexpression. We sought to identify the molecular and cellular events regulating adverse cardiac remodelling in des(-/-) mice and their potential link to OPN. METHODS AND RESULTS In situ hybridization, histology, and immunostaining demonstrated that inflammatory cells and not cardiomyocytes were the source of OPN. RNA profile comparison revealed that activation of inflammatory pathways, sustained by innate immunity mechanisms, predominated among all changes occurring in degenerating des(-/-) myocardium. The expression of the most highly up-regulated genes (OPN: 226×, galectin-3: 26×, osteoactivin/Gpnmb/DC-HIL: 160× and metalloprotease-12: 98×) was associated with heart infiltrating macrophages. To evaluate the role of OPN, we generated des(-/-)OPN(-/-) mice and compared their cardiac function and remodelling indices with those of des(-/-). Osteopontin promoted cardiac dysfunction in this model since des(-/-)OPN(-/-) mice showed 53% improvement of left ventricular function, paralleled to an up to 44% reduction in fibrosis. The diminished fibrotic response in the absence of OPN could be partly mediated by a dramatic reduction in myocardial galectin-3 levels, associated with an impaired galectin-3 secretion by OPN-deficient infiltrating macrophages. CONCLUSION Cardiomyocyte death due to desmin deficiency leads to inflammation and subsequent overexpression of a series of remodelling modulators. Among them, OPN seems to be a major regulator of des(-/-) adverse myocardial remodelling and it functions at least by potentiating galectin-3 up-regulation and secretion.

Desmin mediates TNF-α–induced aggregate formation and intercalated disk reorganization in heart failure

We explored the involvement of the muscle-specific intermediate filament protein desmin in the model of tumor necrosis factor α (TNF-α)–induced cardiomyopathy. We demonstrate that in mice overexpressing TNF-α in the heart (α–myosin heavy chain promoter-driven secretable TNF-α [MHCsTNF]), desmin is modified, loses its intercalated disk (ID) localization, and forms aggregates that colocalize with heat shock protein 25 and ubiquitin. Additionally, other ID proteins such as desmoplakin and β-catenin show similar localization changes in a desmin-dependent fashion. To address underlying mechanisms, we examined whether desmin is a substrate for caspase-6 in vivo as well as the implications of desmin cleavage in MHCsTNF mice. We generated transgenic mice with cardiac-restricted expression of a desmin mutant (D263E) and proved that it is resistant to caspase cleavage in the MHCsTNF myocardium. The aggregates are diminished in these mice, and D263E desmin, desmoplakin, and β-catenin largely retain their proper ID localization. Importantly, D263E desmin expression attenuated cardiomyocyte apoptosis, prevented left ventricular wall thinning, and improved the function of MHCsTNF hearts.

Proper Perinuclear Localization of the TRIM-like Protein Myospryn Requires Its Binding Partner Desmin

Desmin, the muscle-specific intermediate filament protein, surrounds the Z disks and links the entire contractile apparatus to the sarcolemmal cytoskeleton, cytoplasmic organelles, and the nucleus. In an attempt to explore the molecular mechanisms of these associations, we performed a yeast two-hybrid screening of a cardiac cDNA library. We showed that the desmin amino-terminal domain (N-(1-103)) binds to a 413-kDa TRIM-like protein, myospryn, originally identified as the muscle-specific partner of dysbindin, a component of the biogenesis of lysosome-related organelles complex 1 (BLOC-1). Binding of desmin with myospryn was confirmed with glutathione S-transferase pulldown assays and coimmunoprecipitation experiments. Western blot analysis revealed that the complex immunoprecipitated by desmin antibodies, in addition to myospryn, contained the BLOC-1 components dysbindin and pallidin. Deletion analysis revealed that only the (N-(1-103)) fragment of desmin binds to myospryn carboxyl terminus and that this association takes place through the 24-amino acid-long carboxyl-terminal end of the SPRY domain of myospryn. Using an antibody against the COOH terminus of myospryn, we demonstrated that myospryn colocalizes with desmin at the periphery of the nucleus, in close proximity to the endoplasmic reticulum, of mouse neonatal cardiomyocytes. In adult heart muscle, the two proteins colocalize, predominantly at intercalated disks and costameres. We also showed that myospryn colocalizes with lysosomes. Using desmin null hearts, we determined that desmin is required for both the proper perinuclear localization of myospryn, as well as the proper positioning of lysosomes, thus suggesting a potential role of desmin intermediate filaments in lysosomes and lysosome-related organelle biogenesis and/or positioning.

Extensive Induction of Important Mediators of Fibrosis and Dystrophic Calcification in Desmin-Deficient Cardiomyopathy

Mice lacking the intermediate filament protein desmin demonstrate abnormal mitochondria behavior, disruption of muscle architecture, and myocardial degeneration with extensive calcium deposits and fibrosis. These abnormalities are associated with cardiomyocyte hypertrophy, cardiac chamber dilation and eventually with heart failure. In an effort to elucidate the molecular mechanisms leading to the observed pathogenesis, we have analyzed gene expression changes in cardiac tissue using differential display polymerase chain reaction and cDNA atlas array methods. The most substantial changes were found in genes coding the small extracellular matrix proteins osteopontin and decorin that are dramatically induced in the desmin-null myocardium. We further analyzed their expression pattern both at the RNA and protein levels and we compared their spatial expression with the onset of calcification. Extensive osteopontin localization is observed by immunohistochemistry in the desmin-null myocardium in areas with massive myocyte death, as well as in hypercellular regions with variable degrees of calcification and fibrosis. Osteopontin is consistently co-localized with calcified deposits, which progressively are transformed to psammoma bodies surrounded by decorin, especially in the right ventricle. These data together with the observed up-regulation of transforming growth factor-beta1 and angiotensin-converting enzyme, could explain the extensive fibrosis and dystrophic calcification observed in the heart of desmin-null mice, potentially crucial events leading to heart failure.

Desmin Related Disease: A Matter of Cell Survival Failure

Maintenance of the highly organized striated muscle tissue requires a cell-wide dynamic network that through interactions with all vital cell structures, provides an effective mechanochemical integrator of morphology and function, absolutely necessary for intra-cellular and intercellular coordination of all muscle functions. A good candidate for such a system is the desmin intermediate filament cytoskeletal network. Human desmin mutations and post-translational modifications cause disturbance of this network, thus leading to loss of function of both desmin and its binding partners, as well as potential toxic effects of the formed aggregates. Both loss of normal function and gain of toxic function are linked to mitochondrial defects, cardiomyocyte death, muscle degeneration and development of skeletal myopathy and cardiomyopathy.