Download MendeleyA De Novo Designed Protein with Versatile Metal Binding and Tunable Hydrolytic Activity.
Hoffnagle, A.M., Srisantitham, S., Neeley, M., Tsai, C.Y., Tezcan, F.A.(2025) Biochemistry 64: 3261-3271
- PubMed: 40700614
- DOI: https://doi.org/10.1021/acs.biochem.5c00259
- Primary Citation of Related Structures:
9DB8, 9DB9, 9DBA, 9DBB, 9DBC, 9DBD, 9DBF - PubMed Abstract:
Metalloenzyme superfamilies achieve diverse functions within a shared structural framework, and similar functional variety may be achievable in designed proteins. We have previously reported a computational approach that enables the de novo design of symmetric protein assemblies around metal centers with predefined coordination geometries. Here, we demonstrate that an artificial protein trimer, termed Tet4, whose structure was designed around an idealized tetrahedral His 3 /H 2 O-Zn II coordination motif, enables the high-affinity binding of several other divalent first-row transition metal ions in the same geometry as for Zn II . We then follow the proposed evolutionary path of a natural metalloenzyme superfamily by engineering a pseudosymmetric, single-chain variant of Tet4, scTet4 25 . scTet4 25 allows us to introduce asymmetric point mutations that influence the catalytic properties of the metal center. We also demonstrate that we can further tune the enzymatic activity of Tet4 by designing a substrate pocket that improves Zn-Tet4's affinity for a hydrolysis substrate, 4-methylumbelliferyl acetate.
- Department of Chemistry and Biochemistry, University of California, San Diego, La Jolla, California 92093, United States.
Organizational Affiliation:
