Pharmacological regulation of protein-polymer hydrogel stiffness

Kun-Lin Wu; Ross C Bretherton; Jennifer Davis; Cole A DeForest

doi:10.1039/d3ra04046a

Pharmacological regulation of protein-polymer hydrogel stiffness

RSC Adv. 2023 Aug 15;13(35):24487-24490. doi: 10.1039/d3ra04046a. eCollection 2023 Aug 11.

Authors

Kun-Lin Wu¹, Ross C Bretherton^{2

3}, Jennifer Davis^{2

3

4

5}, Cole A DeForest^{1

2

5

6

7

8}

Affiliations

¹ Department of Chemical Engineering, University of Washington (UW) Seattle WA 98105 USA profcole@uw.edu.
² Department of Bioengineering, UW Seattle WA 98105 USA.
³ Institute for Stem Cell & Regenerative Medicine, UW Seattle WA 98109 USA.
⁴ Center for Cardiovascular Biology, UW Seattle WA 98109 USA.
⁵ Department of Laboratory Medicine & Pathology, UW Seattle WA 98109 USA.
⁶ Department of Chemistry, UW Seattle WA 98105 USA.
⁷ Molecular Engineering & Sciences Institute, UW Seattle WA 98109 USA.
⁸ Institute for Protein Design, UW Seattle WA 98105 USA.

Abstract

The extracellular matrix (ECM) undergoes constant physiochemical change. User-programmable biomaterials afford exciting opportunities to study such dynamic processes in vitro. Herein, we introduce a protein-polymer hydrogel whose stiffness can be pharmacologically and reversibly regulated with conventional antibiotics. Specifically, a coumermycin-mediated homodimerization of gel-tethered DNA gyrase subunit B (GyrB) creates physical crosslinking and a rheological increase in hydrogel mechanics, while competitive displacement of coumermycin with novobiocin returns the material to its softened state. These unique platforms could potentially be modulated in vivo and are expected to prove useful in elucidating the effects of ECM-presented mechanical signals on cell function.