Whether impaired postprandial glucagon suppression in prediabetes and T2DM is an attempt to overcome resistance to glucagon's actions on hepatic AA catabolism, a defect in α-cell function, or a combination of both are important, unanswered questions. NAFLD is associated with T2DM risk and impaired insulin action. Unfortunately, it is unclear if glucagon resistance is caused by obesity, hepatic steatosis or both. The experiments outlined will determine if glucagon's actions on hepatic amino acid catabolism and EGP interact with hepatic lipid metabolism in lean and obese subjects with and without T2DM (and with varying degrees of hepatic steatosis).
T2DM and prediabetes are characterized by abnormal post-prandial suppression of glucagon, which contributes to postprandial hyperglycemia by increasing EGP. Although these effects are magnified by decreased and delayed insulin secretion, they are also apparent when insulin secretion is intact. In rodents, altered glucagon signaling changes α-cell function and mass - an effect mediated by changes in circulating AA concentrations. Are the elevated concentrations of branched-chain AA and other AA metabolites in T2DM a cause or an effect of global α-cell dysfunction? Could altered glucagon signaling precipitate a vicious cycle resulting in T2DM?
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
21
Please see information in group descriptions
Mayo Clinic in Rochester
Rochester, Minnesota, United States
Rate of Amino acid catabolism in the presence / absence of glucagon
Tracer-dependent measurement of amino-acid clearance
Time frame: 240 minutes of study
Effect of Diabetes on amino-acid catabolism
Tracer-dependent measurement of amino-acid clearance
Time frame: 240 minutes of study
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