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- Title
Atomic resolution protein allostery from the multi-state structure of a PDZ domain.
- Authors
Ashkinadze, Dzmitry; Kadavath, Harindranath; Pokharna, Aditya; Chi, Celestine N.; Friedmann, Michael; Strotz, Dean; Kumari, Pratibha; Minges, Martina; Cadalbert, Riccardo; Königl, Stefan; Güntert, Peter; Vögeli, Beat; Riek, Roland
- Abstract
Recent methodological advances in solution NMR allow the determination of multi-state protein structures and provide insights into structurally and dynamically correlated protein sites at atomic resolution. This is demonstrated in the present work for the well-studied PDZ2 domain of protein human tyrosine phosphatase 1E for which protein allostery had been predicted. Two-state protein structures were calculated for both the free form and in complex with the RA-GEF2 peptide using the exact nuclear Overhauser effect (eNOE) method. In the apo protein, an allosteric conformational selection step comprising almost 60% of the domain was detected with an "open" ligand welcoming state and a "closed" state that obstructs the binding site by changing the distance between the β-sheet 2, α-helix 2, and sidechains of residues Lys38 and Lys72. The observed induced fit-type apo-holo structural rearrangements are in line with the previously published evolution-based analysis covering ~25% of the domain with only a partial overlap with the protein allostery of the open form. These presented structural studies highlight the presence of a dedicated highly optimized and complex dynamic interplay of the PDZ2 domain owed by the structure-dynamics landscape. In this manuscript the authors report accurate multi-state protein structures of the PDZ domain using biological NMR. By looking into protein structural states, the authors report an allosteric pathway at atomic resolution that validates previously reported low resolution findings and uncovered a structural hallmark of the allosteric ligand binding to the PDZ domain.
- Subjects
PROTEIN fractionation; OVERHAUSER effect (Nuclear physics); PROTEIN-tyrosine phosphatase; PROTEIN structure; PEPTIDES; PROTEIN domains
- Publication
Nature Communications, 2022, Vol 13, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-022-33687-x