Maintaining and escaping feedback control in hierarchically organised tissue: a case study of the intestinal epithelium

Abstract: The intestinal epithelium is one of the fastest renewing tissues in mammals with an average turnover time of only a few days. It shows a remarkable degree of stability towards external perturbations such as physical injuries or radiation damage. Tissue renewal is driven by intestinal stem cells, and differentiated cells can de-differentiate if the stem cell niche is lost after tissue damage. However, self-renewal and regeneration require a tightly regulated balance to uphold tissue homoeostasis, and failure ca… Show more

“…Both healthy and cancer cell populations show a reversal of their developmental trajectories in which differentiated cells regain stem cell characteristics [18][19][20][21][22][23][24][25]. The effects of such a dedifferentiation on the homoeostasis of healthy tissue [26,27], on the speed of mutation acquisition during carcinogenesis [28], on the phenotypic equilibrium [29,30], on transient overshoots [31,32], on the invasion of differentiated malignant cells into cellular hierarchies [33] and on tumour survival in the limit of a small number of cells [34] have already been studied mathematically. While [35] have added a uniform cellular dedifferentiation rate for all non-stem compartments to the model by [16], they specifically fitted the model to a set of in vitro measurements on a colon carcinoma cell line and used the model to study the population dynamics after radiation treatment.…”

On tumoural growth and treatment under cellular dedifferentiation

“…Both healthy and cancer cell populations show a reversal of their developmental trajectories in which differentiated cells regain stem cell characteristics [18][19][20][21][22][23][24][25]. The effects of such a dedifferentiation on the homoeostasis of healthy tissue [26,27], on the speed of mutation acquisition during carcinogenesis [28], on the phenotypic equilibrium [29,30], on transient overshoots [31,32], on the invasion of differentiated malignant cells into cellular hierarchies [33] and on tumour survival in the limit of a small number of cells [34] have already been studied mathematically. While [35] have added a uniform cellular dedifferentiation rate for all non-stem compartments to the model by [16], they specifically fitted the model to a set of in vitro measurements on a colon carcinoma cell line and used the model to study the population dynamics after radiation treatment.…”

On tumoural growth and treatment under cellular dedifferentiation