Glucagonocentric restructuring of diabetes: a pathophysiologic and therapeutic makeover
Roger H. Unger, Alan D. Cherrington
Roger H. Unger, Alan D. Cherrington
View: Text | PDF
Science in Medicine

Glucagonocentric restructuring of diabetes: a pathophysiologic and therapeutic makeover

Abstract

The hormone glucagon has long been dismissed as a minor contributor to metabolic disease. Here we propose that glucagon excess, rather than insulin deficiency, is the sine qua non of diabetes. We base this on the following evidence: (a) glucagon increases hepatic glucose and ketone production, catabolic features present in insulin deficiency; (b) hyperglucagonemia is present in every form of poorly controlled diabetes; (c) the glucagon suppressors leptin and somatostatin suppress all catabolic manifestations of diabetes during total insulin deficiency; (d) total β cell destruction in glucagon receptor–null mice does not cause diabetes; and (e) perfusion of normal pancreas with anti-insulin serum causes marked hyperglucagonemia. From this and other evidence, we conclude that glucose-responsive β cells normally regulate juxtaposed α cells and that without intraislet insulin, unregulated α cells hypersecrete glucagon, which directly causes the symptoms of diabetes. This indicates that glucagon suppression or inactivation may provide therapeutic advantages over insulin monotherapy.

Authors

Roger H. Unger, Alan D. Cherrington

×

Figure 5

Why insulin monotherapy in T1DM cannot restore normal glycemic stability.

Options: View larger image (or click on image) Download as PowerPoint
Why insulin monotherapy in T1DM cannot restore normal glycemic stability...
(A) Concentration disparity of secreted insulin normally delivered to target organs. Normal α cells receive 100 times more insulin than do peripheral tissues. (B) In T1DM, all targets receive the same concentration of injected insulin. Levels high enough to suppress α cells are too high for the liver and the peripheral tissues. (C) By lowering the insulin dose and suppressing hyperglucagonemia with a noninsulin glucagon suppressor, glycemic stability is achieved. (D) Suppression of glycemic volatility in T1DM. NOD mice were treated with optimal insulin dose (0.2 U twice daily); other mice were treated with a suboptimal insulin dose (0.02 U twice daily) and a subcutaneous infusion of leptin. Mean glucose values were determined at 10 a.m. and 5 p.m. Leptin suppressed glucose volatility in these mice by preventing hyperglucagonemia, and hypoglycemia was prevented by reducing the insulin. Figure adapted with permission from Proceedings of the National Academy of Sciences of the United States of America (51).