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Strain-dependent glutathionylation of fibronectin fibers impacts mechano-chemical behavior and primes an integrin switch

Wei Li, Leandro Moretti, Xinya Su, Chiuan‐Ren Yeh, Matthew P. Torres, Thomas H. Barker

2024Nature Communications13 citationsDOIOpen Access PDF

Abstract

The extracellular matrix (ECM) is a protein polymer network that physically supports cells within a tissue. It acts as an important physical and biochemical stimulus directing cell behaviors. For fibronectin (Fn), a predominant component of the ECM, these physical and biochemical activities are inextricably linked as physical forces trigger conformational changes that impact its biochemical activity. Here, we analyze whether oxidative post-translational modifications, specifically glutathionylation, alter Fn’s mechano-chemical characteristics through stretch-dependent protein modification. ECM post-translational modifications represent a potential for time- or stimulus-dependent changes in ECM structure-function relationships that could persist over time with potentially significant impacts on cell and tissue behaviors. In this study, we show evidence that glutathionylation of Fn ECM fibers is stretch-dependent and alters Fn fiber mechanical properties with implications on the selectivity of engaging integrin receptors. These data demonstrate the existence of multimodal post-translational modification mechanisms within the ECM with high relevance to the microenvironmental regulation of downstream cell behaviors. Post-translational modifications potentially alter the biochemical and biophysical properties of the extracellular matrix in significant ways. Here, the authors discover that glutathionylation alters the properties of the matrix protein fibronectin.

Topics & Concepts

FibronectinIntegrinStrain (injury)Cell biologyChemistryBiophysicsBiologyBiochemistryExtracellular matrixReceptorAnatomyCell Adhesion Molecules ResearchCellular Mechanics and InteractionsRedox biology and oxidative stress