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Myonuclear content regulates cell size with similar scaling properties in mice and humans

Kenth‐Arne Hansson, Einar Eftestøl, Jo C. Bruusgaard, Inga Solgård Juvkam, A. Cramer, Anders Malthe‐Sørenssen, Douglas P. Millay, Kristian Gundersen

2020Nature Communications80 citationsDOIOpen Access PDF

Abstract

Abstract Muscle fibers are the largest cells in the body, and one of its few syncytia. Individual cell sizes are variable and adaptable, but what governs cell size has been unclear. We find that muscle fibers are DNA scarce compared to other cells, and that the nuclear number ( N ) adheres to the relationship N = aV b where V is the cytoplasmic volume. N invariably scales sublinearly to V ( b < 1), making larger cells even more DNA scarce. N scales linearly to cell surface in adult humans, in adult and developing mice, and in mice with genetically reduced N , but in the latter the relationship eventually fails when they reach adulthood with extremely large myonuclear domains. Another exception is denervation-atrophy where nuclei are not eliminated. In conclusion, scaling exponents are remarkably similar across species, developmental stages and experimental conditions, suggesting an underlying scaling law where DNA-content functions as a limiter of muscle cell size.

Topics & Concepts

CytoplasmCell sizeCellScalingCell biologyBiologyAtrophyDNABiophysicsChemistryGeneticsMathematicsGeometryMuscle Physiology and DisordersAdipose Tissue and MetabolismGenetics and Physical Performance