The in vivo aggregation of proteins into amyloid fibrils suggests that cellular mechanisms that normally prevent or reverse this aggregation have failed. The small heat-shock molecular chaperone protein αB-crystallin (αB-c) inhibits amyloid formation and colocalizes with amyloid plaques; however, the physiological reason for this localization remains unexplored. Here, using apolipoprotein C-II (apoC-II) as a model fibril-forming system, we show that αB-c binds directly to mature amyloid fibrils (K 5.4 ± 0.5 μM). In doing so, αB-c stabilized the fibrils from dilution-induced fragmentation, halted elongation of partially formed fibrils, and promoted the dissociation of mature fibrils into soluble monomers. Moreover, in the absence of dilution, the association of αB-c with apoC-II fibrils induced a 14-fold increase in average aggregate size, resulting in large fibrillar tangles reminiscent of protein inclusions. We propose that the binding of αB-c to fibrils prevents fragmentation and mediates the lateral association of fibrils into large inclusions. We further postulate that transient interactions of apoC-II with αB-c induce a fibril-incompetent monomeric apoC-II form, preventing oligomerization and promoting fibril dissociation. This work reveals previously unrecognized mechanisms of αB-c chaperone action in amyloid assembly and fibril dynamics, and provides a rationale for the in vivo colocalization of small heat-shock proteins with amyloid deposits.
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