Glucagon infusion alters the circulating metabolome and urine amino acid excretion in dogs.

Glucagon plays a central role in amino acid (AA) homeostasis. The dog is an established model of glucagon biology, and recently, metabolomic changes in people associated with glucagon infusions have been reported. Glucagon also has effects on the kidney; however, changes in urinary AA concentrations associated with glucagon remain under investigation. Therefore, we aimed to fill these gaps in the canine model by determining the effects of glucagon on the canine plasma metabolome and measuring urine AA concentrations. Employing two constant rate glucagon infusions (CRI) - low-dose (CRI-LO: 3 ng/kg/min) and high-dose (CRI-HI: 50 ng/kg/min) on five research beagles, we monitored interstitial glucose and conducted untargeted liquid chromatography-tandem mass spectrometry (LC-MS/MS) on plasma samples and urine AA concentrations collected pre- and post-infusion. The CRI-HI induced a transient glucose peak (90-120 min), returning near baseline by infusion end, while only the CRI-LO resulted in 372 significantly altered plasma metabolites, primarily reductions (333). Similarly, CRI-HI affected 414 metabolites, with 369 reductions, evidenced by distinct clustering post-infusion via data reduction (PCA and sPLS-DA). CRI-HI notably decreased circulating AA levels, impacting various AA-related and energy-generating metabolic pathways. Urine analysis revealed increased 3-methyl-l-histidine and glutamine, and decreased alanine concentrations post-infusion. These findings demonstrate glucagon's glucose-independent modulation of the canine plasma metabolome and highlight the dog's relevance as a translational model for glucagon biology. Understanding these effects contributes to managing dysregulated glucagon conditions and informs treatments impacting glucagon homeostasis.

Urine C-peptide creatinine ratio is an alternative to stimulated serum C-peptide measurement in late-onset, insulin-treated diabetes.

AIMS: Serum C-peptide measurement can assist clinical management of diabetes, but practicalities of collection limit widespread use. Urine C-peptide creatinine ratio may be a non-invasive practical alternative. The stability of C-peptide in urine allows outpatient or community testing. We aimed to assess how urine C-peptide creatinine ratio compared with serum C-peptide measurement during a mixed-meal tolerance test in individuals with late-onset, insulin-treated diabetes. METHODS: We correlated the gold standard of a stimulated serum C-peptide in a mixed-meal tolerance test with fasting and stimulated (mixed-meal tolerance test, standard home meal and largest home meal) urine C-peptide creatinine ratio in 51 subjects with insulin-treated diabetes (diagnosis after age 30 years, median age 66 years, median age at diagnosis 54, 42 with Type 2 diabetes, estimated glomerular filtration rate > 60 ml min(-1) 1.73 m(-2) ). RESULTS: Ninety-minute mixed-meal tolerance test serum C-peptide is correlated with mixed-meal tolerance test-stimulated urine C-peptide creatinine ratio (r = 0.82), urine C-peptide creatinine ratio after a standard breakfast at home (r = 0.73) and urine C-peptide creatinine ratio after largest home meal (r = 0.71). A stimulated (largest home meal) urine C-peptide creatinine ratio cut-off of 0.3 nmol/mmol had a 100% sensitivity and 96% specificity (area under receiver operating characteristic curve = 0.99) in identifying subjects without clinically significant endogenous insulin secretion (mixed-meal tolerance test-stimulated C-peptide < 0.2 nmol/l). In detecting a proposed serum C-peptide threshold for insulin requirement (stimulated serum C-peptide < 0.6 nmol/l), a stimulated (largest home meal) urine C-peptide creatinine ratio cut-off of 0.6 nmol/mmol had a sensitivity and specificity of 92%. CONCLUSION: In patients with insulin-treated diabetes diagnosed after age 30 years, urine C-peptide creatinine ratio is well correlated with serum C-peptide and may provide a practical alternative measure to detect insulin deficiency for use in routine clinical practice.

Twenty-four-hour profile of plasma glucose and glucoregulatory hormones during normal living conditions in trained and untrained men.

Compared with untrained (UT) subjects, in trained (T) subjects the increased insulin sensitivity and decreased glucose induced insulin secretion would tend to promote health by decreasing glucose levels and insulin secretion whereas the increased food intake would tend to increase these variables. To study the net effect of training, blood was sampled from seven T and eight UT young men [VO2max: 76 +/- 2 (T) vs. 48 +/- 1 (UT) mL.kg-1.min-1] for 24 h during ordinary living conditions. Athletes exercised 204 +/- 20 min and ate 50% more calories and 130% more carbohydrate than UT subjects (P less than 0.05). However, 24-h integrated plasma concentrations of glucose, C-peptide, glucagon, free fatty acids, and glycerol as well as glycosylated hemoglobin levels were identical in T and UT subjects. Mean insulin concentration was 41% lower in T than in UT but levels differed significantly (P less than 0.05) only late during the night. Urinary excretion of pancreatic peptides paralleled plasma concentrations. In conclusion, during training adaptations in pancreas- and insulin-sensitive tissues allow the necessary increase in food intake without harmful hyperglycemia and overloading of beta-cells, but sparing of insulin secretion and reductions in glucose levels are only relative to food intake. However, training may be wholesome by increasing hepatic insulin extraction and thereby decreasing arterial insulin levels. Training-induced beta-cell adaptation is not caused by diminished average glucose levels. Finally, renal handling of insulin, C-peptide, and glucagon is not influenced by training.

Renal extraction of glucagon in rats with normal and reduced renal function.

To examine the role of the kidney in the mechanism of impaired metabolic clearance of glucagon in renal failure, the renal handling of endogenous pancreatic glucagon was studied in rats with normal renal function and rats with renal insufficiency produced by 70% surgical ablation. Mean +/- SE renal extraction of glucagon in animals with normal renal function was 39 +/- 5%. Urinary losses of glucagon accounted for less than 2% of renal extraction. In contrast, in the animals with renal insufficiency (glomerular filtration rate reduced to one-third of normal), arterial glucagon increased 40% and renal extraction and extraction rate per gram kidney weight of glucagon were negligible, despite filtered loads of 204 +/- 42 pg/min per g kidney wt. These findings indicate a major role of the kidney in the metabolic clearance of glucagon under normal conditions and suggest that during renal insufficiency elevated plasma levels of glucagon occur, at least in part, as a result of a decreased renal turnover of the hormone.