TY - JOUR
T1 - Glucose metabolism
T2 - Key endogenous regulator of β-cell replication and survival
AU - Dadon, D.
AU - Tornovsky-Babaey, S.
AU - Furth-Lavi, J.
AU - Ben-Zvi, D.
AU - Ziv, O.
AU - Schyr-Ben-Haroush, R.
AU - Stolovich-Rain, M.
AU - Hija, A.
AU - Porat, S.
AU - Granot, Z.
AU - Weinberg-Corem, N.
AU - Dor, Y.
AU - Glaser, B.
N1 - JDRF; NIH; EU [241883]; Leona M. and Harry B. Helmsley Charitable Trust; Dutch Friends of Hebrew University; Novo NordiskResearch in our laboratories is generously funded by JDRF, NIH (beta-cell Biology Consortium), EU (ERC starting grant and the Seventh Framework Programme under grant agreement no241883), the Leona M. and Harry B. Helmsley Charitable Trust, and the Dutch Friends of Hebrew University. O.Z. is a NYSCF Druckenmiller fellow. M.S.R was funded by a generous post-doctoral fellowship from Novo Nordisk.
PY - 2012/10
Y1 - 2012/10
N2 - Recent studies in mice have shown that pancreatic β-cells have a significant potential for regeneration, suggesting that regenerative therapy for diabetes is feasible. Genetic lineage tracing studies indicate that β-cell regeneration is based on the replication of fully differentiated, insulin-positive β-cells. Thus, a major challenge for this field is to identify and enhance the molecular pathways that control β-cell replication and mass. We review evidence, from human genetics and mouse models, that glucose is a major signal for β-cell replication. The mitogenic effect of blood glucose is transmitted via glucose metabolism within β-cells, and through a signalling cascade that resembles the pathway for glucose-stimulated insulin secretion. We introduce the concept that the individual β-cell workload, defined as the amount of insulin that an individual β-cell must secrete to maintain euglycaemia, is the primary determinant of replication, survival and mass. We also propose that a cell-autonomous pathway, similar to that regulating replication, appears to be responsible for at least some of the toxic effects of glucose on β-cells. Understanding and uncoupling the mitogenic and toxic effects of glucose metabolism on β-cells may allow for the development of effective regenerative therapies for diabetes.
AB - Recent studies in mice have shown that pancreatic β-cells have a significant potential for regeneration, suggesting that regenerative therapy for diabetes is feasible. Genetic lineage tracing studies indicate that β-cell regeneration is based on the replication of fully differentiated, insulin-positive β-cells. Thus, a major challenge for this field is to identify and enhance the molecular pathways that control β-cell replication and mass. We review evidence, from human genetics and mouse models, that glucose is a major signal for β-cell replication. The mitogenic effect of blood glucose is transmitted via glucose metabolism within β-cells, and through a signalling cascade that resembles the pathway for glucose-stimulated insulin secretion. We introduce the concept that the individual β-cell workload, defined as the amount of insulin that an individual β-cell must secrete to maintain euglycaemia, is the primary determinant of replication, survival and mass. We also propose that a cell-autonomous pathway, similar to that regulating replication, appears to be responsible for at least some of the toxic effects of glucose on β-cells. Understanding and uncoupling the mitogenic and toxic effects of glucose metabolism on β-cells may allow for the development of effective regenerative therapies for diabetes.
KW - Activating mutations
KW - Diabetes
KW - Glucokinase
KW - Glucokinase activators
KW - Glucose metabolism
KW - Glucotoxicity
KW - β-cell regeneration
KW - β-cell replication
UR - http://www.scopus.com/inward/record.url?scp=84865601606&partnerID=8YFLogxK
U2 - 10.1111/j.1463-1326.2012.01646.x
DO - 10.1111/j.1463-1326.2012.01646.x
M3 - مقالة مرجعية
C2 - 22928570
SN - 1462-8902
VL - 14
SP - 101
EP - 108
JO - Diabetes, Obesity and Metabolism
JF - Diabetes, Obesity and Metabolism
IS - SUPPL.3
ER -
