Glucagon chronically impairs hepatic and muscle glucose disposal

Defects in insulin secretion and/or action contribute to the hyperglycemia of stressed and diabetic patients, and we hypothesize that failure to suppress glucagon also plays a role. We examined the chronic impact of glucagon on glucose uptake in chronically catheterized conscious depancreatized dogs placed on 5 days of nutritional support (NS). For 3 days of NS, a variable intraportal infusion of insulin was given to maintain isoglycemia (approximately 120 mg/dl). On day 3 of NS, animals received a constant low infusion of insulin (0.4 mU.kg-1.min-1) and either no glucagon (CONT), basal glucagon (0.7 ng.kg-1.min-1; BasG), or elevated glucagon (2.4 ng.kg-1.min-1; HiG) for the remaining 2 days. Glucose in NS was varied to maintain isoglycemia. An additional group (HiG+I) received elevated insulin (1 mU.kg-1.min-1) to maintain glucose requirements in the presence of elevated glucagon. On day 5 of NS, hepatic substrate balance was assessed. Insulin and glucagon levels were 10+/-2, 9+/-1, 7+/-1, and 24+/-4 microU/ml, and 24+/-5, 39+/-3, 80+/-11, and 79+/-5 pg/ml, CONT, BasG, HiG, and HiG+I, respectively. Glucagon infusion decreased the glucose requirements (9.3+/-0.1, 4.6+/-1.2, 0.9+/-0.4, and 11.3+/-1.0 mg.kg-1.min-1). Glucose uptake by both hepatic (5.1+/-0.4, 1.7+/-0.9, -1.0+/-0.4, and 1.2+/-0.4 mg.kg-1.min-1) and nonhepatic (4.2+/-0.3, 2.9+/-0.7, 1.9+/-0.3, and 10.2+/-1.0 mg.kg-1.min-1) tissues decreased. Additional insulin augmented nonhepatic glucose uptake and only partially improved hepatic glucose uptake. Thus, glucagon impaired glucose uptake by hepatic and nonhepatic tissues. Compensatory hyperinsulinemia restored nonhepatic glucose uptake and partially corrected hepatic metabolism. Thus, persistent inappropriate secretion of glucagon likely contributes to the insulin resistance and glucose intolerance observed in obese and diabetic individuals.     

Inactivation of PKCtheta leads to increased susceptibility to obesity and dietary insulin resistance in mice

In this study, we investigated the metabolic phenotype of PKCtheta knockout mice (C57BL/6J) on chow diet and high-fat diet (HFD). The knockout (KO) mice are normal in growth and reproduction. On the chow diet, body weight and food intake were not changed in the KO mice; however, body fat content was increased with a corresponding decrease in body lean mass. Energy expenditure and spontaneous physical activity were decreased in the KO mice. On HFD, energy expenditure and physical activity remained low in the KO mice. The body weight and fat content were increased rapidly in the KO mice. At 8 wk on HFD, severe insulin resistance was detected in the KO mice with hyperinsulinemic euglycemic clamp and insulin tolerance test. Insulin action in both hepatic and peripheral tissues was reduced in the KO mice. Plamsa free fatty acid was increased, and expression of adiponectin in the adipose tissue was decreased, in the KO mice on HFD. This study suggests that loss of PKCtheta reduces energy expenditure and increases the risk of dietary obesity and insulin resistance in mice.     

The energetics and evolution of oxidoreductases in deep time

The core metabolic reactions of life drive electrons through a class of redox protein enzymes, the oxidoreductases. The energetics of electron flow is determined by the redox potentials of organic and inorganic cofactors as tuned by the protein environment. Understanding how protein structure affects oxidation–reduction energetics is crucial for studying metabolism, creating bioelectronic systems, and tracing the history of biological energy utilization on Earth. We constructed ProtReDox ( https://protein-redox-potential.web.app ), a manually curated database of experimentally determined redox potentials. With over 500 measurements, we can begin to identify how proteins modulate oxidation–reduction energetics across the tree of life. By mapping redox potentials onto networks of oxidoreductase fold evolution, we can infer the evolution of electron transfer energetics over deep time. ProtReDox is designed to include user-contributed submissions with the intention of making it a valuable resource for researchers in this field.     

Pig brain aldose reductase: purification, significance of the amino acid composition, substrate specificity and mechanism

1. Pig brain aldose reductase (ALR2, EC 1.1.1.21) has been purified from fresh tissue with a approximately 60% improvement in specific activity over an acetone-powder preparation. 2. Dead-end inhibition and alternate substrate studies rule out an iso Theorell-Chance mechanism but are compatible with an ordered bi bi mechanism where NADPH and NADP+ function as the outside reactants in the direction of xylitol formation. 3. Subtle but significant differences are shown to exist in the distribution of apolar and mixed amino acid residues between aldose and aldehyde reductases when the mean fractional area loss [Rose et al., 1985] is used as the measure of compositional relatedness.     

Bioinformatic analysis and in vitro site-directed mutagenesis of conserved amino acids in BphK, a specific bacterial glutathione transferase

Glutathione transferases [GSTs: EC 2.5.1.18)] are ubiquitous multifunctional prokaryotic and eukaryotic enzymes involved in the cellular detoxification and excretion of a large variety of compounds. However, our understanding of the role of bacterial GSTs in metabolism is still in its infancy. The association of bacterial GST DNA with other genes involved in degradation of toxic pollutants, including polychlorinated biphenyls (PCBs), indirectly suggests a role for bacterial GSTs in biodegradation. Previously, in this laboratory, a specific bacterial GST, BphK^LB400 isolated from Burkholderia xenovorans LB400, was shown to be capable of dehalogenating chlorinated organic substrates rendering them less toxic. However, little is known about the specific amino acids in BphK^LB400 involved in catalysis in vitro. In this study, bioinformatic analysis of BphK^LB400 and other bacterial GSTs, including PCB degraders, identified a number of amino acids that were identical in all bacterial GST sequences analysed. Two amino acids, Cys10 and His106, were selected for in vitro site-directed mutagenesis studies. In vitro GST activity assay results suggest that these two amino acids play a role in determining the catalytic activity of BphK^LB400. Studies of bacterial cell extracts expressing BphK^LB400 (wildtype and mutant) identified a specific mutant, Cys10Phe, with increased GST activity towards 1-chloro-2,4-dinitrobenzene (the model substrate for GSTs). BphK^LB400 (mutant) with increased activity towards toxic chlorinated organic compounds could have potential for bioremediation of contaminated soil in the environment.     

Insulin secretion in the conscious mouse is biphasic and pulsatile

Islets in most species respond to increased glucose with biphasic insulin secretion, marked by a sharp first-phase peak and a slowly rising second phase. Mouse islets in vitro, however, lack a robust second phase. To date, this observation has not been extended in vivo. We thus compared insulin secretion from conscious mice with isolated mouse islets in vitro. The arterial plasma insulin response to a hyperglycemic clamp was measured in conscious mice 1 wk after surgical implantation of carotid artery and jugular vein catheters. Mice were transfused using clamps with blood from a donor mouse to maintain blood volume, allowing frequent arterial sampling. When plasma glucose in vivo was raised from approximately 5 to approximately 13 mM, insulin rose to a first-phase peak of 403+/-73% above basal secretion (n=5), followed by a rising second phase of mean 289+/- 41%. In contrast, perifused mouse islets ( approximately 75 islets/trial) responded with a similar first phase of 508+/- 94% (n=4) but a smaller and virtually flat second phase of 169+/- 9% (n=4, P<0.05). Furthermore, the slope of the second-phase response differed significantly from zero in mice (2.63+/-0.39%/min, P<0.01), in contrast to perifused islets (0.18+/- 0.14%/min, P>0.30). Mice also displayed pulsatile patterns in insulin concentration (period: 4.2+/- 0.4 min, n=8). Conscious mice thus responded to increased glucose with biphasic and pulsatile insulin secretion, as in other species. The robust second phase observed in vivo suggests that the processes needed to generate second-phase insulin secretion may be abrogated by islet isolation.