Structural and functional gastrointestinal abnormalities in ACTA2 R179H mice modeling multisystemic smooth muscle dysfunction syndrome
Ahmed A. Rahman, Rhian Stavely, Leah C. Ott, Christopher Y. Han, Kensuke Ohishi, Ryo Hotta, Alan J. Burns, Sabyasachi Das, Emily Da Cruz, Diana Tambala, Mark E. Lindsay, Patricia L. Musolino, Allan M. Goldstein
Ahmed A. Rahman, Rhian Stavely, Leah C. Ott, Christopher Y. Han, Kensuke Ohishi, Ryo Hotta, Alan J. Burns, Sabyasachi Das, Emily Da Cruz, Diana Tambala, Mark E. Lindsay, Patricia L. Musolino, Allan M. Goldstein
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Research Article Gastroenterology Neuroscience

Structural and functional gastrointestinal abnormalities in ACTA2 R179H mice modeling multisystemic smooth muscle dysfunction syndrome

Abstract

Multisystemic smooth muscle dysfunction syndrome (MSMDS) is a rare disorder caused by ACTA2 mutations, including the R179H variant, which alters actin filament stability and dynamics and smooth muscle contractility. Cardiovascular complications dominate its clinical presentation, but gastrointestinal (GI) dysfunction significantly affects quality of life. To investigate the structural, functional, and cellular basis of gut dysmotility in MSMDS, we reviewed clinical data from 24 patients with MSMDS and studied the ACTA2 R179H mouse model. Patients exhibited severe gut dysmotility, with 75% requiring medication for chronic constipation. ACTA2 mutant mice displayed cecal and colonic dilatation, reduced intestinal length, and disrupted colonic migrating motor complexes. Delayed whole-gut transit and impaired contractile responses to electrical and pharmacological stimulation were observed. Transcriptomic analysis revealed significant actin cytoskeleton-related gene changes in smooth muscle cells, and immune profiling identified increased lymphocytic infiltration. Despite functional abnormalities, there were no obvious changes in the enteric nervous system. These findings establish ACTA2 mice as a robust model for studying GI pathology in MSMDS, elucidating the role of smooth muscle dysfunction in gut dysmotility. This model provides a foundation for developing targeted therapies aimed at restoring intestinal motility by directly addressing actin cytoskeletal disruptions in smooth muscle cells.

Authors

Ahmed A. Rahman, Rhian Stavely, Leah C. Ott, Christopher Y. Han, Kensuke Ohishi, Ryo Hotta, Alan J. Burns, Sabyasachi Das, Emily Da Cruz, Diana Tambala, Mark E. Lindsay, Patricia L. Musolino, Allan M. Goldstein

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Figure 5

Transcriptional changes in intestinal smooth muscle cells in ACTA2 mutant mice.

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Transcriptional changes in intestinal smooth muscle cells in ACTA2 mutan...
(A) Expression of gene markers for smooth muscle cells (Myh11 and Acta2), mesothelial cells (Upk3b), enteric glial cells (Cdh19), excitatory and inhibitory enteric neurons (Chat and Nos1), lymphatic endothelial cells (Prox1), fibroblasts (Pdgfra), immune cells (Ptprc), ICCs (Kit and Ano1), and vascular endothelial cells (Vwf) in nuclei isolated from the muscularis propria of the colon from control and ACTA2 mutant mice represented as UMAP plots. (B and C) Unsupervised clustering of cell populations annotated for cell type identity (B) and genotype (C) in UMAP space. (D) Total number of differentially expressed genes (DEGs) between ACTA2 mutant mice and controls for each cell population cluster. (E) Volcano plot showing DEGs in smooth muscle cells from ACTA2 mutants compared with controls. The x axis indicates log2 fold change (mutant vs. control), with positive values (right) representing genes upregulated in ACTA2 mutants and negative values (left) representing genes downregulated in mutants. The y axis indicates the –log10 adjusted P value. Red dots denote significantly differentially expressed genes (adjusted P < 0.05), and black dots represent nonsignificant genes. Selected genes of interest are labeled. (F) Overrepresentation analysis of DEGs between ACTA2 mutant mice and controls against the GO database. Heatmap shows the logFC changes in mutants compared with controls for each gene associated with the gene ontology.