Abstract
To help cells cope with protein misfolding and aggregation, Hsp70 molecular chaperones selectively bind a variety of sequences ("selective promiscuity"). Statistical analyses from substrate-derived peptide arrays reveal that DnaK, the E. coli Hsp70, binds to sequences containing three to five branched hydrophobic residues, although otherwise the specific amino acids can vary considerably. Several high-resolution structures of the substrate -binding domain (SBD) of DnaK bound to peptides reveal a highly conserved configuration of the bound substrate and further suggest that the substrate-binding cleft consists of five largely independent sites for interaction with five consecutive substrate residues. Importantly, both substrate backbone orientations (N- to C- and C- to N-) allow essentially the same backbone hydrogen-bonding and side-chain interactions with the chaperone. In order to rationalize these observations, we performed atomistic molecular dynamics simulations to sample the interactions of all 20 amino acid side chains in each of the five sites of the chaperone in the context of the conserved substrate backbone configurations. The resulting interaction energetics provide the basis set for deriving a predictive model that we call Paladin (Physics-based model of DnaK-Substrate Binding). Trained using available peptide array data, Paladin can distinguish binders and nonbinders of DnaK with accuracy comparable to existing predictors and further predicts the detailed configuration of the bound sequence. Tested using existing DnaK-peptide structures, Paladin correctly predicted the binding register in 10 out of 13 substrate sequences that bind in the N- to C- orientation, and the binding orientation in 16 out of 22 sequences. The physical basis of the Paladin model provides insight into the origins of how Hsp70s bind substrates with a balance of selectivity and promiscuity. The approach described here can be extended to other Hsp70s where extensive peptide array data is not available.
Highlights
To maintain a healthy proteome, the cell relies on an extensive network of molecular chaperones and degradation enzymes called the protein homeostasis network [1,2,3]
We developed a model to describe how client proteins bind to DnaK, the E. coli Hsp70, using physics-based molecular dynamics simulations to quantify the interactions between a variety of peptide substrates and key sites on DnaK
Substrates bind to βSBD in a highly conserved conformation
Summary
To maintain a healthy proteome, the cell relies on an extensive network of molecular chaperones and degradation enzymes called the protein homeostasis (or proteostasis) network [1,2,3]. Central to these quality control networks are the highly conserved 70-kDa heat shock chaperones (Hsp70s) [4,5,6,7]. Upon ATP hydrolysis, the ADP-bound NBD and the SBD undock, and the α-helical lid of the SBD associates with the βSBD, promoting the stable binding of the substrate (slow on/off rates) [9]. Hsp70s bind, hold, and release their client proteins by cycling between these two allosteric endpoints
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
