DiscussionIn islets isolated from t

Discussion
In islets isolated from the pancreas of seven multiorgan donors who were affected by type 2 diabetes, we observed a clearly reduced insulin release in response to glucose, whereas the secretion of the hormone during stimulation with the non-fuel secretagogue arginine was only slightly affected. In order to investigate the basis of this selective defect, since mitochondrial metabolism, and the subse- quent rise of ATP and of ATP/ADP ratio plays a central role in glucose-induced insulin release, we measured several key steps of the mitochondrial events that lead to ATP synthesis and correlated them with insulin secretion. The energy for ATP production is provided by oxidation of reducing equivalents via the electron-transport chain. The enzyme complexes I to V are located at the inner mitochondrial membrane and the flux of electrons along the respiratory chain establishes the proton gradient, which generates the membrane potential. Glucose stimulation results in the transfer of reducing equivalents to the res- piratory chain, leading to hyperpolarization of the mito- chondrial membrane (ΔΨm) and generation of ATP. In islets from diabetic subjects we found that glucose-in- duced hyperpolarization of the mitochondrial membrane was reduced. We also found that ATP levels were lower, at high glucose, and the ATP/ADP ratio was blunted, in response to glucose stimulation. These defects could con- ceivably be due to a reduced electron flux through the res-
piratory chain, or to an over-expression of proteins (such as UCP-2) that tends to diminish the proton gradient gen- erated by the respiratory chain. To test the first possibility we measured the protein expression of complex I and complex V of the respiratory chain and we found an in- creased expression that makes this hypothesis unlikely. To test the second possibility, we measured the protein ex- pression of UCP-2, and we found, indeed, an increased expression of this protein. UCP-2 is a member of a family of proteins located in the mitochondrial inner membrane, which uncouples mitochondrial oxidative phosphoryla- tion. By this mechanism, energy is wasted through heat and cellular ATP synthesis is decreased. UCP-2 protein expression could be activated by an increased formation of reactive oxygen species [41]. In agreement with this in- terpretation, in our model we found increased levels of nitrotyrosine (a marker of oxidative stress) in diabetic is- lets. According to these data, therefore, it is possible to suppose that in beta cells from diabetic patients the in- creased expression of UCP-2 is responsible of the reduced hyperpolarization of the mitochondrial membrane, lower ATP levels, ATP/ADP ratio, and eventually, of the reduced insulin release in response to glucose. This sequence of events is coherent with several data obtained in vitro or in animal models, and recently put in perspective [42]. Increased UCP-2 levels in beta cells are associated with decreased insulin secretion [43, 44], and UCP-2 overexpression in rat pancreatic islets has been shown to inhibit glucose-stimulated insulin secretion by de- creasing ATP formation [45]. Moreover, in rodent pan- creatic islets chronically exposed to high glucose or NEFA glucose-induced impairment of insulin secretion is asso- ciated with altered mitochondrial function, including over- expression of the UCP-2 protein and a consequent decrease of ATP production [46]. In islets from hyperglycaemic 90% pancreatectomized rats [47] or in human islets ex- posed to high glucose [48], UCP-2 mRNA or protein ex- pression was increased, in accordance with a decrease of glucose-induced insulin release. In a tumoral beta cell line, chronic exposure to high NEFA both reduced insulin secretion and increased UCP-2 levels by regulating glu- cose-induced ATP formation [49, 50]. In other reports, UCP-2 overexpression by enhancing ATP/ADP ratio re- stores insulin secretion in islets from ZDF rat [51].