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Conformational changes induced in ubiquitin by circular protein-DNA chimeras

Created on 07 Jul 2026

Authors

Boral, S., Schnebly, M. D., Gamada, D. M., Gardner, K. H., Hekstra, D. R.

Abstract

Proteins are dynamic molecular machines that change shape in response to physical and chemical perturbations. Although single-molecule force spectroscopy provides precise information about the stretching of proteins in response to tunable forces, it does so without structural detail. Circular protein-DNA chimeras, with DNA attached to pairs of surface sites, have been introduced as an alternative way to tunably apply forces to proteins. Intriguingly, these chimeras should be tractable for atomic-level study by nuclear magnetic resonance (NMR) spectroscopy and other structural methods. Here, we describe the NMR-scale synthesis of circular chimeras of single- and double-stranded DNA with ubiquitin, an essential component of many cellular pathways. We designed these chimeras to probe a two-residue retraction of ubiquitin's C-terminal {beta}5 strand, normally triggered by phosphorylation of serine 65 during initiation of mitophagy. We probed the resulting conformational changes by NMR and found that the attachment of a single strand of DNA suffices to alter this conformational equilibrium. A control bearing two separate short single DNA strands recapitulated much of the circular chimera's NMR properties, supporting a dominant role for local protein-DNA interactions rather than spring-like action by single- or double-stranded DNA. These results provide a necessary benchmark for future studies using DNA springs to probe the functional dynamics of proteins.

Preprint server: bioRxiv
The authors list and abstract were imported from bioRxiv on 07 Jul 2026.

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