posted on 2024-08-02, 07:13authored bySilvia Rinaldi, Giorgio Colombo, Giulia Morra
Hsp70 belongs to a family of molecular chaperones ubiquitous
through
organisms that assist client protein folding and prevent aggregation.
It works through a tightly ATP-regulated allosteric cycle mechanism,
which organizes its two NBD and SBD into alternate open and closed
arrangements that facilitate loading and unloading of client proteins.
The two cytosolic human isoforms Hsc70 and HspA1 are relevant targets
for neurodegenerative diseases and cancer. Illuminating the molecular
details of Hsp70 functional dynamics is essential to rationalize differences
among the well-characterized bacterial homologue DnaK and the less
explored human forms and develop subtype- or species-selective allosteric
drugs. We present here a molecular dynamics-based analysis of the
conformational dynamics of HspA1. By using an “allosterically
impaired” mutant for comparison, we can reconstruct the impact
of the ADP–ATP swap on interdomain contacts and dynamic coordination
in full-length HspA1, supporting previous predictions that were, however,
limited to the NBD. We model the initial onset of the conformational
cycle by proposing a sequence of structural steps, which reveal the
role of a specific human sequence insertion at the linker, and a modulation
of the angle formed by the two NBD lobes during the progression of
docking. Our findings pinpoint functionally relevant conformations
and set the basis for a selective structure-based drug discovery approach
targeting allosteric sites in human Hsp70.