[HTML][HTML] Insulin demand regulates β cell number via the unfolded protein response

RB Sharma, AC O'Donnell… - The Journal of …, 2015 - Am Soc Clin Investig
RB Sharma, AC O'Donnell, RE Stamateris, B Ha, KM McCloskey, PR Reynolds, P Arvan
The Journal of clinical investigation, 2015Am Soc Clin Investig
Although stem cell populations mediate regeneration of rapid turnover tissues, such as skin,
blood, and gut, a stem cell reservoir has not been identified for some slower turnover
tissues, such as the pancreatic islet. Despite lacking identifiable stem cells, murine
pancreatic β cell number expands in response to an increase in insulin demand. Lineage
tracing shows that new β cells are generated from proliferation of mature, differentiated β
cells; however, the mechanism by which these mature cells sense systemic insulin demand …
Although stem cell populations mediate regeneration of rapid turnover tissues, such as skin, blood, and gut, a stem cell reservoir has not been identified for some slower turnover tissues, such as the pancreatic islet. Despite lacking identifiable stem cells, murine pancreatic β cell number expands in response to an increase in insulin demand. Lineage tracing shows that new β cells are generated from proliferation of mature, differentiated β cells; however, the mechanism by which these mature cells sense systemic insulin demand and initiate a proliferative response remains unknown. Here, we identified the β cell unfolded protein response (UPR), which senses insulin production, as a regulator of β cell proliferation. Using genetic and physiologic models, we determined that among the population of β cells, those with an active UPR are more likely to proliferate. Moreover, subthreshold endoplasmic reticulum stress (ER stress) drove insulin demand–induced β cell proliferation, through activation of ATF6. We also confirmed that the UPR regulates proliferation of human β cells, suggesting that therapeutic UPR modulation has potential to expand β cell mass in people at risk for diabetes. Together, this work defines a stem cell–independent model of tissue homeostasis, in which differentiated secretory cells use the UPR sensor to adapt organ size to meet demand.
The Journal of Clinical Investigation