Abstract
The bacterial chaperonin GroEL/ES promotes protein folding post-translation by transiently encapsulating substrate proteins within a central chamber. GroEL also binds translating ribosomes in vivo, suggesting an additional role in cotranslational folding. Here, we used biochemical reconstitution, structural proteomics and electron microscopy to study the mechanism by which GroEL/ES engages nascent polypeptides. We show that GroEL binds nascent chains on the inside of its cavity via the apical domains and disordered C-terminal tails, resulting in local structural destabilization of the substrate. Ribosome-tethered nascent proteins are partially encapsulated upon GroES binding to GroEL, and refold in the chaperonin cavity. Reconstitution of chaperone competition at the ribosome shows that both Trigger factor and GroEL can be accommodated on long nascent chains, but GroEL and DnaK are mutually antagonistic. Our findings extend the role of GroEL/ES in de novo protein folding, and reveal an unexpected plasticity of the chaperonin mechanism that allows cotranslational substrate encapsulation.
Competing Interest Statement
The authors have declared no competing interest.