Differential expression of glucagon and glucagon-like peptide 1 receptors in mouse pancreatic alpha and beta cells in two models of alpha cell hyperplasia.

Glucose homeostasis is determined by a balance between insulin and glucagon, produced by beta and alpha cells of the pancreas respectively. The levels of circulating hormones is partly determined by the mass of these two endocrine cell types. However, in contrast to beta cells, the identity of the signals regulating alpha cell number is not known. Mice with a global deletion of the glucagon receptor (Gcgr-/-) and mice with ablation of prohormone convertase 2 (PC2), the enzyme involved in the conversion of proglucagon into mature glucagon, develop alpha cell hyperplasia. These observations and the fact that Gcgr-/- mice exhibit high levels of circulating glucagon-like peptide-1 (GLP-1) suggested that members of the glucagon family of peptides could be directly involved in the regulation of alpha cell number. In this study we sought to determine whether alpha cells express receptors for Glucagon (Gcgr) and/or the glucagon-like peptide-1 (GLP1r). We examined the expression of these receptors in islets of Gcgr-/-, PC2-/- mice and control littermates, in an alpha (alphaTC1/9) and in a beta (betaTC3) cell line. Gcgr was expressed exclusively by islet beta cells, but not by alpha cells, of the two lines of mice lacking glucagon signaling. Similarly, betaTC but not alphaTC cells, expressed Gcgr. The expression of GLP1r by alpha cells was determined by the genotype and age of the mice. In embryos, GLU+ cells of Gcgr+/+ mice cells express GLP1r during early development, but not in adults. In contrast, alpha cells of Gcgr-/- mice were GLP1r+ throughout life, reflecting the immature state of GLU+ cells when Gcgr is deleted. Unlike alpha cells, beta cells of all mice lines examined initiate GLP1r expression after birth. These results suggest that GLP-1 may affect the maturation of postnatal but not prenatal beta cells. In addition, they also suggest that the incretin could mediate alpha cell proliferation, inducing the development of alpha cell hyperplasia in Gcgr-/- mice.