The role of glucagon in the pathological condition of diabetes is gaining interest, and it has been recently reported that its action is essential for hyperglycemia to occur. Glucagon levels, which are elevated in some diabetic models, are reduced following leptin therapy. Likewise, hyperglycemia is corrected in type 1 diabetic mice treated with leptin, although the mechanisms have not been fully determined. A direct inhibitory effect of leptin on mouse and human α-cells has been demonstrated at the levels of electrical activity, calcium signaling and glucagon secretion. In the present study we employed the Cre-loxP strategy to generate Lepr^flox/flox Gcg-cre mice, which specifically lack leptin receptors in glucagon-secreting α-cells, in order to determine whether leptin resistance in α-cells contributes to hyperglucagonemia, and also whether leptin action in α-cells is required to improve glycemia in type 1 diabetes with leptin therapy. Immunohistochemical analysis of pancreas sections revealed Cre-mediated recombination in ~43% of the α-cells. We observed that in vivo Lepr^flox/flox Gcg-cre mice display normal glucose and lipid homeostasis. In addition, leptin administration in streptozotocin (STZ)-induced diabetic Lepr^flox/flox Gcg-cre mice restored euglycemia similarly to control mice. These findings suggest that loss of leptin receptor signaling in close to half of α-cells does not alter glucose metabolism in vivo, nor is it sufficient to prevent the therapeutic action of leptin in type 1 diabetes.