Abstract
pRb, p107, and p130 are related proteins that play a central role in the regulation of cell cycle progression and terminal differentiation in mammalian cells. Nevertheless, it is still largely unclear how these proteins achieve this regulation in vivo. The intestinal epithelium is an ideal in vivo system in which to study the molecular pathways that regulate proliferation and differentiation because it exists in a constant state of development throughout an animal's lifetime. We studied the phenotypic effects on the intestinal epithelium of mutating Rb and p107 or p130. Although mutating these genes singly had little or no effect, loss of pRb and p107 or p130 together produced chronic hyperplasia and dysplasia of the small intestinal and colonic epithelium. In Rb/p130 double mutants this hyperplasia was associated with defects in terminal differentiation of specific cell types and was dependent on the increased proliferation seen in the epithelium of mutant animals. At the molecular level, dysregulation of the Rb pathway led to an increase in the expression of Math1, Cdx1, Cdx2, transcription factors that regulate proliferation and differentiation in the intestinal epithelium. The absence of Cdx1 function in Rb/p130 double mutant mice partially reverted the histologic phenotype by suppressing ectopic mitosis in the epithelium. These studies implicate the Rb pathway as a regulator of epithelial homeostasis in the intestine.
Highlights
Normal adult tissues maintain a constant cell number by regulating the relative amounts of proliferation and apoptosis
Little is known about the role of the pocket proteins in regulating homeostasis in the intestinal epithelium
To determine whether the pocket proteins regulate intestinal epithelial homeostasis through specific transcription factors, we examined the relationship between pRb and p130 and several transcription factors thought to regulate differentiation in the intestinal epithelium, namely Math1, Elf3, Cdx1, and Cdx2
Summary
Normal adult tissues maintain a constant cell number by regulating the relative amounts of proliferation and apoptosis. The predominant function of the pocket proteins is to control the G1/S transition through negative regulation of the E2F family of transcription factors [3]. This protein family plays an important role in regulating other cellular processes, such as terminal differentiation and senescence [4]. Given the importance of the pocket proteins in regulating cell cycle progression and differentiation, it is not surprising that mutations in the RB gene are frequent in many human tumor types [3].
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