Activation mechanism of small heat shock protein HSPB5 revealed by disease-associated mutants

Article

Woods, Christopher N.; Janowska, Maria K.; Ulmer, Lindsey D.; Sidhu, Jasleen Kaur; Stone, Natalie L.; James, Ellie I.; Guttman, Miklos; Bush, Matthew F.; Klevit, Rachel E.

University of Washington; University of Washington Seattle; University of Washington; University of Washington Seattle; University of Washington; University of Washington Seattle; University of Washington; University of Washington Seattle

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA

0027-12915

10.1073/pnas.2425061122

2025-05-20

Found from bacteria to humans, small heat shock proteins (sHSPs) are the least understood protein chaperones. HSPB5 (or alpha B-crystallin) is among the most widely expressed of the 10 human sHSPs, including in muscle, brain, and eye lens where it is constitutively present at high levels. A high content of disorder in HSPB5 has stymied efforts to uncover how its structure gives rise to function. To uncover its mechanisms of action, we compared human HSPB5 and two disease-associated mutants, R120G and D109H. Expecting to learn how the mutations lead to loss of function, we found instead that the mutants are constitutively activated chaperones while wild-type HSPB5 can transition reversibly between nonactivated (low activity) and activated (high activity) states in response to changing conditions. Techniques that provide information regarding interactions and accessibility of disordered regions revealed that the disordered N-terminal regions (NTR) that are required for chaperone activity exist in a complicated interaction network within HSPB5 oligomers and are sequestered from solvent in nonactivated states. Either mutation or an activating pH change causes rearrangements in the network that expose parts of the NTR, making them more available to bind an aggregating client. Although beneficial in the short-term, failure of the mutants to adopt a state with lower activity and lower NTR accessibility leads to increased coaggregation propensity and, presumably, early cataract. The results support a model where chaperone activity and solubility are modulated through the quasi-ordered NTR and its multiple competing interactions.