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Rapid cyclic stretching of cultured human visceral smooth muscle cells promotes a synthetic, proinflammatory phenotype
Sharon M. Wolfson, Katherine Beigel, Sierra E. Anderson, Brooke Deal, Molly Weiner, Se-Hwan Lee, Deanne M. Taylor, Su Chin Heo, Robert O. Heuckeroth, Sohaib K. Hashmi
Sharon M. Wolfson, Katherine Beigel, Sierra E. Anderson, Brooke Deal, Molly Weiner, Se-Hwan Lee, Deanne M. Taylor, Su Chin Heo, Robert O. Heuckeroth, Sohaib K. Hashmi
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Research Article Cell biology Gastroenterology Muscle biology

Rapid cyclic stretching of cultured human visceral smooth muscle cells promotes a synthetic, proinflammatory phenotype

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Abstract

Bowel smooth muscle experiences mechanical stress constantly during normal function and pathologic mechanical stressors in disease states. We tested the hypothesis that pathologic mechanical stress could alter transcription to induce smooth muscle phenotypic class switching. To test this hypothesis, primary human intestinal smooth muscle cells (HISMCs), seeded on electrospun aligned poly-ε-caprolactone nano-fibrous scaffolds, were subjected to pathologic, high-frequency (1 Hz) uniaxial 3% cyclic stretch (loaded) or kept unloaded in culture for 6 hours. RNA-Seq, quantitative PCR (qPCR), and quantitative IHC defined loading-induced changes in gene expression. NicheNet predicted how differentially expressed genes might affect HISMCs and other bowel cells. These studies show loading induced differential expression of 4,537 HISMC genes. Loaded HISMCs had a less contractile phenotype, with increased expression of synthetic SMC genes, proinflammatory cytokines, and altered expression of axon guidance molecules, growth factors, and morphogens. Many differentially expressed genes encode secreted ligands that could act cell autonomously on smooth muscle and on other cells in the bowel wall. These data show that HISMCs undergo remarkably rapid phenotypic plasticity in response to mechanical stress that may convert contractile HISMCs into proliferative fibroblast-like cells or proinflammatory cells. These mechanical stress–induced changes in HISMC gene expression may be relevant for human bowel disease.

Authors

Sharon M. Wolfson, Katherine Beigel, Sierra E. Anderson, Brooke Deal, Molly Weiner, Se-Hwan Lee, Deanne M. Taylor, Su Chin Heo, Robert O. Heuckeroth, Sohaib K. Hashmi

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Figure 1

HISMC cultured on aligned nanofibrous spun scaffolds had more MYH11 protein and less VIM mRNA compared with HISMC cultured on nonaligned scaffolds.

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HISMC cultured on aligned nanofibrous spun scaffolds had more MYH11 prot...
(A) Schematic of nonaligned (top) and aligned (bottom) PCL scaffolds. (B) Confocal Z-stack maximum intensity projections of HISMCs stained with antibodies to smooth muscle myosin (MYH11, magenta) and F-actin (Phalloidin-Alexa Fluor 488, green) after culture on nonaligned (top) or aligned (bottom) scaffolds for 72 hours. Scale bar: 100 μm. (C) MYH11 antibody staining was brighter in HISMCs cultured 72 hours on aligned scaffolds compared with HISMC cultured on nonaligned scaffolds (median [interquartile range] aligned: 54.33 AU [32.6 AU], nonaligned: 47.6 AU [28.28 AU], Mann-Whitney test, P < 0.0001, n = 3). (D–J) qPCR analyses for mRNA levels of smooth muscle synthetic genes (VIM, COL1A1, MMP14, FN1) showed increased VIM expression in HISMCs grown on nonaligned scaffolds (D), with similar expression of other synthetic genes. qPCR analyses demonstrated mRNA levels of smooth muscle contractile genes (MYH11, ACTG2, ACTA2) were similar for HISMCs grown on nonaligned and aligned scaffolds. VIM (mean ± SEM aligned: 0.01462 ± 0.002633, mean nonaligned: 0.025 ± 0.0002020, P = 0.0052, n = 5). ACTA2 (mean ± SEM aligned: 0.3656 ± 0.07053, mean nonaligned: 0.4986 ± 0.04450, P = 0.1494, n = 5). MYH11 (mean ± SEM aligned: 0.002982 ± 0.0006099, mean nonaligned: 0.003978 ± 0.0004698, P = 0.2322, n = 5). COL1A1 (median [interquartile range], aligned: 10.38 [12.679], nonaligned: 18.95 [4.61], P = 0.0952, n = 5). FN1 (median [interquartile range], aligned: 6.985 [6.93], nonaligned: 10.21 [8.483], P = 0.4206, n = 5). ACTG2 (mean ± SEM aligned: 0.7499 ± 0.06910, mean nonaligned: 1.009 ± 0.1477, P = 0.1249, n = 5). MMP14 (median [interquartile range], aligned: 1.16 [1.624], nonaligned: 2.319 [2.898], P = 0.2222, n = 5). **P < 0.01, ***P < 0.001.

Copyright © 2026 American Society for Clinical Investigation
ISSN 2379-3708

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