PEER-REVIEWED PUBLICATION

2022

Pressure and stiffness sensing together regulate vascular smooth muscle cell phenotype switching

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Swiatlowska P, Sit B, et al.

Science Advances

Queen Mary University of London, King’s College London, Hong Kong University

RESEARCH SUMMARY
This study investigated how two pathological mechanical cues implicated in atherosclerosis—hypertensive pulsatile pressure and a compliant extracellular matrix—combine to drive vascular smooth muscle cell (VSMC) phenotypic switching. VSMCs cultured on defined-stiffness substrates (spanning very soft, intima-like compliance to stiff, calcified-like conditions) showed measurable cytoskeletal and morphometric changes in response to either substrate compliance or pressure alone, but a full switch was only observed when hypertensive pressure was applied on compliant substrates. Under these combined conditions, VSMCs robustly formed matrix-degrading podosomes (confirmed by cortactin core with zyxin/vinculin ring organization and gelatin degradation), exhibited reduced actin alignment and altered cell shape distributions, and displayed broad proteomic remodeling (TMT-based quantitative proteomics) that was most pronounced specifically in the compliant-plus-hypertensive condition. Mechanistically, the work identified convergent regulation of actin dynamics through cofilin: stiffness sensing modulated cofilin activity via a RhoA–ROCK2–LIMK2 axis, while pressure (and PKC activation) promoted Ca2+- and slingshot-dependent cofilin dephosphorylation, together maximizing podosome formation and ECM remodeling—linking distinct mechanosensing pathways to early atherosclerotic progression.
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CELLSCALE INSTRUMENT USED

MechanoCulture TR

VSMCs plated on PDMS substrates with controlled stiffness (e.g., 1–130 kPa range) were exposed to cyclic hydrodynamic pressure using a CellScale MechanoCulture TR pressure stimulator (modified for a low-pressure range) housed inside a 37°C incubator. The system was used to reproduce physiological normal blood pressure (measured 120/60 mmHg) and stage II hypertensive pressure (measured 180/120 mmHg) via cyclic pressurization for 12 hours, with media perfusion ports supplying presaturated culture medium. This CellScale-driven pressure stimulation was the central experimental input enabling systematic comparison of pressure-only, stiffness-only, and combined pressure-plus-compliance conditions, and it was the key condition that induced maximal VSMC phenotypic switching marked by podosome formation and matrix degradation on compliant substrates.
AUTHORS

Pamela Swiatlowska, Brian Sit, Zhen Feng, Emilie Marhuenda, Ioannis Xanthis, Simona Zingaro, Matthew Ward, Xinmiao Zhou, Qingzhong Xiao, Cathy Shanahan, Gareth E. Jones, Cheng-han Yu, Thomas Iskratsch.

PUBLICATION DETAILS
JOURNAL

Science Advances

YEAR

2022

INSTITUTIONS

Queen Mary University of London, King’s College London, Hong Kong University

COUNTRIES

Hong Kong, United Kingdom

INSTRUMENT USED

MechanoCulture TR

TESTING METHODS

Hydrated and Temperature Controlled TestingHydrostatic Pressure Testing

RESEARCH APPLICATIONS

Fibrosis & Tissue RemodelingMechanotransductionVascular Tissue Engineering & Mechanics

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