Mechanical shear stress influences endothelial RNA methylation in atherosclerosis and pulmonary arterial hypertension

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Frontiers in Medicine Published June 5, 2026 Medically reviewed June 5, 2026 DOI ↗ By Dr. Julia Lee, PhD · Oncology, Genomics & Drug Development

Key Takeaway

Note that mechanistic links between shear stress and RNA methylation remain incompletely understood.

This narrative review synthesizes current evidence regarding the interplay between hemodynamic shear stress and epitranscriptomic mechanisms in endothelial cells. The scope covers conditions such as atherosclerosis, pulmonary arterial hypertension, and diabetic microangiopathy. The authors explore secondary outcomes including endothelial-to-mesenchymal transition, barrier integrity, and angiogenesis within this mechanistic context.

The review highlights that the specific mechanisms by which mechanical forces converge on epitranscriptomic pathways to regulate RNA fate remain incompletely understood. Furthermore, the integration of m6A modification into shear-dependent remodeling has not been systematically explored in the existing literature.

The authors caution that the distinction between association and causation is not distinguished in the current evidence base. This emerging evidence suggests that mechanistic modules illustrating how flow-responsive transcriptional programs may intersect with RNA methylation processes require further systematic investigation.

practice_relevance was not reported. The review serves to outline gaps in understanding the intersection of mechanical forces and RNA methylation processes.

Study Details

Study typeSystematic review

EvidenceLevel 1

PublishedMay 2026

View Original Abstract ↓

Hemodynamic shear stress is a fundamental biomechanical cue that shapes endothelial phenotypes and contributes to vascular diseases. Although flow-responsive transcription factors such as KLF2 and KLF4 are well recognized, how mechanical forces converge on epitranscriptomic mechanisms to regulate RNA fate remains incompletely understood. Emerging evidence identifies N6-methyladenosine (m6A) modification as a dynamic regulator of non-coding RNA stability and endothelial function, yet its integration into shear-dependent remodeling has not been systematically explored. This review synthesizes current evidence on the interplay between shear stress and the m6A regulatory machinery and discusses how epitranscriptomic modulation of coding and non-coding RNAs may contribute to endothelial plasticity. Within this broader framework, the KLF2/4–METTL3–H19 pathway is presented as a representative mechanistic module illustrating how flow-responsive transcriptional programs may intersect with RNA methylation processes and reader-mediated transcript regulation. The potential implications of such interactions for endothelial-to-mesenchymal transition, barrier integrity, angiogenesis, and vascular diseases—including atherosclerosis, pulmonary arterial hypertension, and diabetic microangiopathy—are discussed. This integrated perspective highlights the emerging role of mechano-epitranscriptomic crosstalk in vascular biology and identifies directions for future investigation.