AI Article Synopsis
- The research focuses on how proteins adapt to their substrates, a central question in molecular physics and physical chemistry.
- By using a new method that combines structure and mechanics, the study connects molecular dynamics simulations to the elastic properties of proteins, creating a rigidity graph that shows how residues affect each other's mechanical strength.
- Examples with S1A protease and PDZ3 domain show that when substrates bind or dissociate, groups of connected residues change in mechanical rigidity, shedding light on conformational changes and long-range communication within proteins, especially in critical areas for biological functions and mutation sensitivity.
Article Abstract
A protein's adaptive response to its substrates is one of the key questions driving molecular physics and physical chemistry. This work employs the recently developed structure-mechanics statistical learning method to establish a mechanical perspective. Specifically, by mapping all-atom molecular dynamics simulations onto the spring parameters of a backbone-side-chain elastic network model, the chemical moiety specific force constants (or mechanical rigidity) are used to assemble the rigidity graph, which is the matrix of inter-residue coupling strength. Using the S1A protease and the PDZ3 signaling domain as examples, chains of spatially contiguous residues are found to exhibit prominent changes in their mechanical rigidity upon substrate binding or dissociation. Such a mechanical-relay picture thus provides a mechanistic underpinning for conformational changes, long-range communication, and inter-domain allostery in both proteins, where the responsive mechanical hotspots are mostly residues having important biological functions or significant mutation sensitivity.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8966636 | PMC |
| http://dx.doi.org/10.1039/d1sc06184d | DOI Listing |
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