Tissue confinement regulates cell growth and size in epithelia

Abstract

SummaryCell proliferation is a central process in tissue development, homeostasis and disease. Yet how proliferation is regulated in the tissue context remains poorly understood. Here, we introduce a quantitative framework to elucidate how tissue growth dynamics regulate cell proliferation. We show that tissue growth causes confinement that suppresses cell growth; however, this confinement does not directly affect the cell cycle. This leads to uncoupling between rates of cell growth and division in epithelia and, thereby, reduces cell size. Division becomes arrested at a minimal cell size, which is consistent across diverse epithelia in vivo. Here, the nucleus approaches a volume limit set by the compacted genome. The loss of Cyclin D1-dependent cell size regulation results in an abnormally high nuclear-to-cytoplasmic volume ratio and DNA damage. Overall, we demonstrate how epithelial proliferation is regulated by the interplay between tissue confinement and cell size regulation.Highlights-In epithelia, regulation of cell growth and cycle are uncoupled-Cell growth is regulated by tissue-scale dynamics, which determine confinement-Cell volume in epithelial tissue is described by G1 sizer model with a tunable growth rate-Volume of cells in epithelial tissues is near a minimum set by genome size