PEER-REVIEWED PUBLICATION

2025

Targeted silencing of Engrailed-1 reprograms profibrotic fibroblast lineage for scarless wound healing

A tensile test divider icon

Xu X, Wang L, et al.

Molecular Therapy

Zhejiang University, Westlake University, Westlake Institute for Advanced Study, Tianjin University

RESEARCH SUMMARY
This study develops FibroMC, a nanoscale fibroblast-mimicking siRNA carrier designed to selectively silence Engrailed-1 (En1), a transcription factor that drives profibrotic fibroblast lineage commitment in adult skin. FibroMC is constructed by coating ionizable lipid nanoparticles with fibroblast cell membranes containing integrin β1 and N-cadherin, enabling preferential uptake by Engrailed-1 lineage-positive fibroblasts (EPFs) in vitro and in vivo. Delivery of siEn1 via FibroMC effectively suppresses En1 expression, reduces collagen I deposition, inhibits myofibroblast differentiation, and reverses the profibrotic phenotype of EPFs. In murine wound models, a single topical dose of FibroMC restores epidermal and dermal architecture, regenerates hair follicles and skin appendages, normalizes collagen fiber orientation, and significantly reduces scarring. Mechanical assessments confirm that treated wounds recover near-native skin compliance and elasticity. This work introduces a lineage-targeted RNAi strategy capable of reprogramming pathological fibroblasts to achieve scarless skin regeneration.
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CELLSCALE INSTRUMENT USED

UniVert

Mechanical properties of regenerated skin were evaluated using a CellScale UniVert mechanical testing system. Excised wound-site tissues were mounted in uniaxial tension fixtures and extended at controlled strain rates while the UniVert recorded force–displacement curves. Tensile modulus, maximum load, and strain-to-failure were quantified to assess functional recovery of biomechanical strength following FibroMC treatment. UniVert measurements demonstrated that siEn1-mediated reprogramming restored skin mechanical properties toward those of unwounded tissue, supporting the therapeutic potential of FibroMC for scarless wound repair.
AUTHORS

Xuehan Xu, Luyi Wang, Xinyue Bi, Tingting Cao, Menghua Gao, Buwei Hu, Jiafeng Zhong, Chenlin Ji, Rui Sun, Chengjie Sun, Yanjun Zhao, Qin Zhou, Jianjun Cheng.

PUBLICATION DETAILS
JOURNAL

Molecular Therapy

YEAR

2025

INSTITUTIONS

Zhejiang University, Westlake University, Westlake Institute for Advanced Study, Tianjin University

COUNTRIES

China

INSTRUMENT USED

UniVert

TESTING METHODS

Micro-Mechanical TestingTensile Testing

RESEARCH APPLICATIONS

Drug Screening & Drug Delivery MechanicsFibrosis & Tissue RemodelingSkin and Wound Healing Biomechanics

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