Compromised genomic integrity impedes muscle growth after Atrx inactivation
Michael S. Huh, Tina Price O’Dea, Dahmane Ouazia, Bruce C. McKay, Gianni Parise, Robin J. Parks, Michael A. Rudnicki, David J. Picketts
Michael S. Huh, Tina Price O’Dea, Dahmane Ouazia, Bruce C. McKay, Gianni Parise, Robin J. Parks, Michael A. Rudnicki, David J. Picketts
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Research Article Muscle biology

Compromised genomic integrity impedes muscle growth after Atrx inactivation

Abstract

ATR-X syndrome is a severe intellectual disability disorder caused by mutations in the ATRX gene. Many ancillary clinical features are attributed to CNS deficiencies, yet most patients have muscle hypotonia, delayed ambulation, or kyphosis, pointing to an underlying skeletal muscle defect. Here, we identified a cell-intrinsic requirement for Atrx in postnatal muscle growth and regeneration in mice. Mice with skeletal muscle–specific Atrx conditional knockout (Atrx cKO mice) were viable, but by 3 weeks of age presented hallmarks of underdeveloped musculature, including kyphosis, 20% reduction in body mass, and 34% reduction in muscle fiber caliber. Atrx cKO mice also demonstrated a marked regeneration deficit that was not due to fewer resident satellite cells or their inability to terminally differentiate. However, activation of Atrx-null satellite cells from isolated muscle fibers resulted in a 9-fold reduction in myoblast expansion, caused by delayed progression through mid to late S phase. While in S phase, Atrx colocalized specifically to late-replicating chromatin, and its loss resulted in rampant signs of genomic instability. These observations support a model in which Atrx maintains chromatin integrity during the rapid developmental growth of a tissue.

Authors

Michael S. Huh, Tina Price O’Dea, Dahmane Ouazia, Bruce C. McKay, Gianni Parise, Robin J. Parks, Michael A. Rudnicki, David J. Picketts

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Figure 5

Loss of Atrx results in genomic instability and aberrant mitotic events.

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Loss of Atrx results in genomic instability and aberrant mitotic events....
(A) Double-immunofluorescent α-tubulin and γ-tubulin labeling of the mitotic spindle apparatus. Control Atrxf/y:Ad-LacZ myoblasts formed well-organized bipolar mitotic spindle assemblies Atrxf/y:Ad-Cre myoblasts displayed an unusual cellular phenotype, characterized by a higher frequency of cells with aberrant nuclear morphology and poorly formed mitotic spindles with supernumerary mitotic organizing centers. Also shown is percent cells with aberrant nuclei (binucleated, fragmented micronuclei, or polynuclei) in Atrxf/y:Ad-LacZ and Atrxf/y:Ad-Cre myoblasts. Values represent percent total ± 95% confidence interval. Atrxf/y:Ad-LacZ, 5,116 total cells (n = 3); Atrxf/y:Ad-Cre, 4,491 total cells (n = 3). *P < 0.05, t test. (B) Double-immunofluorescent α-tubulin and phospho–histone H3 labeling of the mitotic spindle apparatus and metaphase chromosomes of Atrxf/y:Ad-LacZ and Atrxf/y:Ad-Cre myoblasts. Original magnification, ×630 (A and B). Boxed regions in A are enlarged ×7 (yellow) and ×4 (orange) below.