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 4

Enteric nervous system in ACTA2 mutant mice.

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Enteric nervous system in ACTA2 mutant mice. (A and B) Morphometric anal...
(A and B) Morphometric analysis of the colonic myenteric plexus stained with neuronal markers Hu (total neurons), nNOS (inhibitory motor neurons), and calretinin (commonly associated with sensory neurons, interneurons, and some excitatory motor neurons). (C) Quantification of Hu+, nNOS+, and calretinin+ neurons per 2 mm2 area in whole-mount myenteric plexus preparations. Bar graphs on the right show the percentage of Hu+ neurons that were also positive for nNOS or calretinin. (D) Confocal images of ICC in the distal colon labeled with C-Kit. ICCs located at the myenteric plexus (ICC-MY) are indicated with arrows, and those near the submucosa (ICC-SM) with arrowheads. (E) Quantification of total C-Kit+ ICC immunoreactivity in control and ACTA2 mice. Scale bars: 50 μm. Data are presented as mean ± SEM. Statistical comparisons were made using unpaired 2-tailed t tests, as detailed in Methods.