ABSTRACT:

Objective

Pharmacological activation of adenosine signaling has been shown to increase ?-cell proliferation and thereby ?-cell regeneration in zebrafish and rodent models of diabetes. However, whether adenosine has an endogenous role in regulating ?-cell proliferation is unknown. The objective of this study was to determine whether endogenous adenosine regulates ?-cell proliferation-either in the basal state or states of increased demand for insulin-and to delineate the mechanisms involved.

Methods

We analyzed the effect of pharmacological adenosine agonists on ?-cell proliferation in in vitro cultures of mouse islets and in zebrafish models with ?- or ?-cell ablation. In addition, we performed physiological and histological characterization of wild-type mice and mutant mice with pancreas- or ?-cell-specific deficiency in Adora2a (the gene encoding adenosine receptor A2a). The mutant mice were used for in vivo studies on the role of adenosine in the basal state and during pregnancy (a state of increased demand for insulin), as well as for in vitro studies of cultured islets.

Results

Pharmacological adenosine signaling in zebrafish had a stronger effect on ?-cell proliferation during ?-cell regeneration than in the basal state, an effect that was independent of the apoptotic microenvironment of the regeneration model. In mice, deficiency in Adora2a impaired glucose control and diminished compensatory ?-cell proliferation during pregnancy but did not have any overt phenotype in the basal state. Islets isolated from Adora2a-deficient mice had a reduced baseline level of ?-cell proliferation in vitro, consistent with our finding that UK432097, an A2a-specific agonist, promotes the proliferation of mouse ?-cells in vitro.

Conclusions

This is the first study linking endogenously produced adenosine to ?-cell proliferation. Moreover, we show that adenosine signaling via the A2a receptor has an important role in compensatory ?-cell proliferation, a feature that could be harnessed pharmacologically for ?-cell expansion and future therapeutic development for diabetes.