The proteomic signature of insulin-resistant human skeletal muscle reveals increased glycolytic and decreased mitochondrial enzymes.

AIMS/HYPOTHESIS: The molecular mechanisms underlying insulin resistance in skeletal muscle are incompletely understood. Here, we aimed to obtain a global picture of changes in protein abundance in skeletal muscle in obesity and type 2 diabetes, and those associated with whole-body measures of insulin action. METHODS: Skeletal muscle biopsies were obtained from ten healthy lean (LE), 11 obese non-diabetic (OB), and ten obese type 2 diabetic participants before and after hyperinsulinaemic-euglycaemic clamps. Quantitative proteome analysis was performed by two-dimensional differential-gel electrophoresis and tandem-mass-spectrometry-based protein identification. RESULTS: Forty-four protein spots displayed significant (p < 0.05) changes in abundance by at least a factor of 1.5 between groups. Several proteins were identified in multiple spots, suggesting post-translational modifications. Multiple spots containing glycolytic and fast-muscle proteins showed increased abundance, whereas spots with mitochondrial and slow-muscle proteins were downregulated in the OB and obese type 2 diabetic groups compared with the LE group. No differences in basal levels of myosin heavy chains were observed. The abundance of multiple spots representing glycolytic and fast-muscle proteins correlated negatively with insulin action on glucose disposal, glucose oxidation and lipid oxidation, while several spots with proteins involved in oxidative metabolism and mitochondrial function correlated positively with these whole-body measures of insulin action. CONCLUSIONS/INTERPRETATION: Our data suggest that increased glycolytic and decreased mitochondrial protein abundance together with a shift in muscle properties towards a fast-twitch pattern in the absence of marked changes in fibre-type distribution contribute to insulin resistance in obesity with and without type 2 diabetes. The roles of several differentially expressed or post-translationally modified proteins remain to be elucidated.

In vitro phage display in a rat beta cell line: a simple approach for the generation of a single-chain antibody targeting a novel beta cell-specific epitope.

AIMS/HYPOTHESIS: The aim of the present study was to evaluate in vitro phage display in a beta cell line as a novel strategy for the isolation of beta cell-specific agents/biomarkers. METHODS: A single-chain antibody (SCA) library was pre-incubated with AR42J cells in order to eliminate SCAs with exocrine binding properties. It was then panned against INS-1 cells to select beta cell-targeted antibodies. RESULTS: By these means, we isolated a novel antibody, SCA B5, that binds rapidly (6.0 min) and with a 450-fold higher specificity to beta cells relative to exocrine cells. We estimated for SCA B5 a binding affinity in the low micromol/l range and 858 binding sites per beta cell. Confocal microscopy showed binding to the beta cell surface and confirmed subsequent internalisation. Moreover, staining of rat and human pancreatic tissue sections with SCA B5 suggests that the target epitope is presented in pancreatic beta cells of different origins. Infrared imaging revealed that labelling of beta cells with tracer SCA B5 is strictly dependent on beta cell mass. With competition assays we excluded insulin, glutamate decarboxylase, C-peptide and islet amyloid polypeptide as SCA B5 targets. In accordance with these predictions, SCA B5 homed in vivo highly selectively to normal beta cells and dysfunctional beta cells of diabetic rats. Moreover, accumulation of radioactively labelled SCA B5 in the pancreas was reduced by 80% after pre-injection with unlabelled SCA B5, thereby confirming the specific uptake in the pancreas. CONCLUSIONS/INTERPRETATION: We report a simple strategy for the generation of an SCA targeting a novel beta cell-specific epitope.

Synthesis and evaluation of a glibenclamide glucose-conjugate: a potential new lead compound for substituted glibenclamide derivatives as islet imaging agents.

The search for novel SUR1-ligands originates from the idea to influence the in vivo behaviour by adding new structural moieties to the glibenclamide structure while preserving its binding affinity. Important application of novel conjugates might be their use as radioactively labelled tracer probes in the non-invasive investigation of the islet mass. It is known that the imaging quality of a tracer could be improved by increasing its hydrophilicity, which leads to a reduced plasma protein binding and diminished the unspecific uptake by various organs. In this study the glucose molecule was chosen as a substitute of glibenclamide to enhance hydrophilicity. As expected glucose conjugation leads to a 12-fold increase of the hydrophilicity. In vitro evaluation showed that the conjugate binds with high affinity to SUR1. Interestingly, in vivo the hypoglycaemic action of the conjugate was of significant shorter duration compared to glibenclamide. In accordance, the conjugate was cleared much faster from the blood stream, due to a significant lower plasma protein binding. In conclusion, glycosylation proved to be a powerful tool for the development of a high affinity glibenclamide ligand with completely different pharmacodynamics. Therefore, the glucose-conjugate could be a potential lead compound for the design of substituted glibenclamide derivatives as islet imaging ligands.

Prolonged glucose infusion into conscious rats inhibits early steps in insulin signalling and induces translocation of GLUT4 and protein kinase C in skeletal muscle.

AIMS/HYPOTHESIS: Previous studies on diabetic patients have shown that hyperglycaemia increases glucose uptake in an apparently insulin-independent manner. However, the molecular mechanism has not been clarified. METHODS: We studied rats receiving continuous glucose infusion to address this question. In this animal model, rats accommodate systemic glucose oversupply and rapidly develop insulin resistance. RESULTS: Glucose infusion increased both plasma glucose and insulin concentrations to peak after one day. In spite of continuous glucose infusion normoglycaemia was reached after 5 days while insulin concentrations remained higher. Focusing our studies in day 2 (hyperglycaemia/hyperinsulinaemia) and day 5 (normoglycaemia/hyperinsulinaemia) we found, particularly in day 5, that the early steps of the insulin signalling cascade in skeletal muscle of glucose-infused rats were not more activated when compared to control animals as assessed by a comparable phosphorylation of the insulin receptor, IRS-1 and PKB and by an unaltered IRS-1-associated Ptd(Ins) 3' kinase activity. Continuous glucose infusion induced GLUT4 protein expression and translocation to the plasma membrane while neither expression nor translocation of GLUT1 was affected. Translocation of PKC- betaI, - betaII (> threefold) and -alpha, -theta (to a lesser extent) to the plasma membrane was significantly induced after 2 days but not after 5 days of glucose infusion when normoglycaemia was reached. CONCLUSIONS/INTERPRETATION: Our data support the hypothesis that continuous glucose infusion induces translocation of GLUT4 while the early steps of the insulin signalling cascade were not increased. These effects could be mediated by activation of PKC.