αB-crystallin is a sensor for assembly intermediates and for the subunit topology of desmin intermediate filaments

Desmin-related myopathies (DRM) are inherited neuromuscular disorders characterized by adult onset and delayed accumulation of aggregates of desmin, a protein belonging to the type III intermediate filament family, in the sarcoplasma of skeletal and cardiac muscles. In this paper, we have mapped the locus for DRM in a large French pedigree to a 26-cM interval in chromosome 11q21-23. This region contains the alphaB-crystallin gene (CRYAB), a candidate gene encoding a 20-kD protein that is abundant in lens and is also present in a number of non-ocular tissues, including cardiac and skeletal muscle. AlphaB-crystallin is a member of the small heat shock protein (shsp) family and possesses molecular chaperone activity. We identified an R120G missense mutation in CRYAB that co-segregates with the disease phenotype in this family. Muscle cell lines transfected with the mutant CRYAB cDNA showed intracellular aggregates that contain both desmin and alphaB-crystallin as observed in muscle fibers from DRM patients. These results are the first to identify a defect in a molecular chaperone as a cause for an inherited human muscle disorder.

Desmin, the muscle specific intermediate filament (IF) protein encoded by a single gene, is expressed in all muscle tissues. In mature striated muscle, desmin IFs surround the Z-discs, interlink them together and integrate the contractile apparatus with the sarcolemma and the nucleus. To investigate the function of desmin in all three muscle types in vivo, we generated desmin null mice through homologous recombination. Surprisingly, desmin null mice are viable and fertile. However, these mice demonstrated a multisystem disorder involving cardiac, skeletal, and smooth muscle. Histological and electron microscopic analysis in both heart and skeletal muscle tissues revealed severe disruption of muscle architecture and degeneration. Structural abnormalities included loss of lateral alignment of myofibrils and abnormal mitochondrial organization. The consequences of these abnormalities were most severe in the heart, which exhibited progressive degeneration and necrosis of the myocardium accompanied by extensive calcification. Abnormalities of smooth muscle included hypoplasia and degeneration. The present data demonstrate the essential role of desmin in the maintenance of myofibril, myofiber, and whole muscle tissue structural and functional integrity, and show that the absence of desmin leads to muscle degeneration.

We have investigated the functional role of the non-helical end domains of vimentin on its assembly properties using truncated Xenopus and human recombinant proteins. Removal of the amino-terminal "head" domain yielded a molecule that did not assemble into 10 nm filaments but remained in a soluble oligomeric particle form with a sedimentation coefficient considerably smaller than that of wild-type vimentin (Vim(wt)). In contrast, removal of the carboxy-terminal "tail" domain had no obvious effect on the sedimentation characteristics. In particular, sedimentation equilibrium analysis under low ionic strength conditions yielded oligomeric particle species of Mr 135,000 to 360,000, indistinguishable from those obtained with Vim(wt). When induced to form filaments from this state by rapid dilution into filament forming buffer, Vim(wt) and Vim(deltaT) protein generated similar viscosity profiles. However, as determined by scanning transmission electron microscopy, under these conditions Vim(deltaT) formed filaments of heterogeneous diameter, corresponding to various distinct mass-per-length (MPL) values: whereas Vim(wt) yielded MPL values peaking between 40 and 45 kDa/nm, Vim(deltaT) filaments produced histograms which could be fitted by three Gaussian curves peaking between 37 and 131 kDa/nm. In contrast, when dialyzed against, instead of being rapidly diluted into, filament forming buffer, Vim(deltaT) gave histograms with one major peak at about 54 kDa/nm. The MPL heterogeneity observed for Vim(deltaT) was already evident at the earliest stages of assembly. For example, ten seconds after initiation, "unit-length" filament segments (58 to 63 nm) were formed with both wt and deltaT proteins, but the diameters were considerably larger for Vim(deltaT) compared to Vim(wt) (20(+/- 3) nm versus 16(+/- 3)nm), indicating a distinct role of the carboxy-terminal tail domain in the width control during unit-length filament formation. Despite this difference both Vim(deltaT) and Vim(wt) filaments appeared to grow stepwise in a modular fashion from such unit-length filament segments. This suggests that assembly occurred by a principally similar mechanism involving the end-on-fusion or annealing of unit-length filaments.