Compartment specific responses to contractility in the small intestinal epithelium

• Published in: PLoS genetics Vol. 20; no. 3; p. e1010899
• Main Authors: Hinnant, Taylor, Ning, Wenxiu, Lechler, Terry
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 22.03.2024
• Subjects: Actomyosin; Analysis; Animal models; Apoptosis; Biology and Life Sciences; Cells; Contractility; Cytoskeleton; DNA damage; Epithelial cells; Epithelium; Extracellular matrix; Genetic aspects; Homeostasis; Intestine, Small; Medicine and Health Sciences; Muscle proteins; Myosin; Physiological aspects; Research and Analysis Methods; Small intestine; Transgenes; China
• ISSN: 1553-7404; 1553-7390; 1553-7404
• DOI: 10.1371/journal.pgen.1010899

Tissues are subject to multiple mechanical inputs at the cellular level that influence their overall shape and function. In the small intestine, actomyosin contractility can be induced by many physiological and pathological inputs. However, we have little understanding of how contractility impacts the intestinal epithelium on a cellular and tissue level. In this study, we probed the cell and tissue-level effects of contractility by using mouse models to genetically increase the level of myosin activity in the two distinct morphologic compartments of the intestinal epithelium, the crypts and villi. We found that increased contractility in the villar compartment caused shape changes in the cells that expressed the transgene and their immediate neighbors. While there were no discernable effects on villar architecture or cell polarity, even low levels of transgene induction in the villi caused non-cell autonomous hyperproliferation of the transit amplifying cells in the crypt, driving increased cell flux through the crypt-villar axis. In contrast, induction of increased contractility in the proliferating cells of the crypts resulted in nuclear deformations, DNA damage, and apoptosis. This study reveals the complex and diverse responses of different intestinal epithelial cells to contractility and provides important insight into mechanical regulation of intestinal physiology.