Distinct chaperone mechanisms can delay the formation of aggresomes by the myopathy-causing R120G alphaB-crystallin mutant.

A familial form of desmin-related myopathy (DRM) is associated with a missense mutation (R120G) in alphaB-crystallin (alphaB) and is characterized by intracellular desmin aggregation. Because alphaB is a molecular chaperone that participates in the assembly of desmin filaments, it has been suggested that the desmin aggregation might be due to the loss of alphaB function. We report here that alphaBR120G has indeed impaired in vivo function and structure as reflected by a highly reduced capacity to protect cells against heat shock and by an abnormal supramolecular organization even in cells not expressing desmin. In many cells, alphaBR120G accumulated in inclusion bodies that had characteristics of aggresomes concentrating around the centrosome following a microtubule-facilitated process. Three distinct chaperone mechanisms could reduce or even prevent the formation of the alphaBR120G aggresomes. Wild-type alphaB and Hsp27 prevented aggresome formation by co-oligomerizing with alphaBR120G. Hsp70 with its co-chaperone Hdj-1 or Chip-1 but not a mutant of Chip-1 lacking ubiquitin ligase activity, reduced the frequency of aggresome formation likely by targeting alphaBR120G for degradation. Finally, HspB8 interacted only transiently with alphaB but nonetheless rescued the alphaBR120G oligomeric organization, suggesting that it acted as a true chaperone assisting in the folding of the mutant protein. Hence, the formation of inclusion bodies in alphaBR120G-mediated DRM is probably due to the misfolding of alphaBR120G per se and can be delayed or prevented by expression of the wild type alphaB allele or other molecular chaperones, thereby explaining the adult onset of the disease.