Anna Valerio

Forearm Nitric Oxide Balance, Vascular Relaxation, and Glucose Metabolism in NIDDM Patients

Endothelium-dependent and -independent vascular responses were assessed in 10 NIDDM patients and 6 normal subjects with no evidence of atherosclerotic disease. Changes in forearm blood flow and arteriovenous (AV) serum nitrite/nitrate (NO2−/NO3-) concentrations were measured in response to intra-arterial infusion of acetylcholine (ACh) (7.5, 15, 30 μg/min, endothelium-dependent response) and sodium nitroprusside (SNP) (0.3, 3, 10 μg/min, endothelium-independent response). Insulin sensitivity (determined by minimal model intravenous glucose tolerance test) was lower in NIDDM patients (0.82 ± 0.20 vs. 2.97 ± 0.29 104 min · μU−1 · ml−1; P < 0.01). Baseline forearm blood flow (4.8 ± 0.3 vs. 4.4 ± 0.3 ml · 100 ml−1 tissue · min−1; NS), mean blood pressure (100 ± 4 vs. 92 ± 4 mmHg; NS), and vascular resistance (21 ± 1 vs. 21 ± 1 units; NS), as well as their increments during ACh and SNP, infusion were similar in both groups. No difference existed in baseline NO2−/NO3− concentrations (4.09 ± 0.33 ]NIDDM patients] vs. 5.00 ± 0.48 μmol/1 ]control subjects]; NS), their forearm net balance (0.31 ± 0.08 ]NIDDM patients] vs. 0.26 ± 0.08 μmol/1 · 100 ml−1 tissue · min−1; NS), and baseline forearm glucose uptake. During ACh infusion, both NO2− and NO3− concentrations and net balance significantly increased in both groups, whereas glucose uptake increased only in control subjects. When data from NIDDM and control groups were pooled together, a correlation was found between the forearm AV NO2− and NO3− differences and blood flow (r = 0.494, P = 0.024). On the contrary, no correlation was evident between NO2− and NO3− concentrations or net balance and insulin sensitivity. In summary, 1) no difference existed in basal and ACh-stimulated NO generation and endothelium-dependent relaxation between uncomplicated NIDDM patients and control subjects; 2) in both NIDDM and control groups, forearm NO2− and NO3− net balance following ACh stimulation was related to changes in the forearm blood flow; and 3) ACh-induced increase in forearm blood flow was associated with an increase in glucose uptake only in control subjects but not in NIDDM patients. In conclusion, our results argue against a role of impaired NO generation and blood flow regulation in determining the insulin resistance of uncomplicated NIDDM patients; rather, it supports an independent insulin regulation of hemodynamic and metabolic effects.

Effect of Metformin on Insulin-Stimulated Glucose Turnover and Insulin Binding to Receptors in Type II Diabetes

Euglycemic insulin glucose-clamp and insulin-binding studies on erythrocytes and monocytes were performed in seven type II (non-insulin-dependent) diabetic subjects before and after 4 wk of metformin treatment (850 mg 3 times/day) and in five obese subjects with normal glucose tolerance. Glucose turnover was also measured at basal insulin concentrations and during hyperinsulinemic euglycemic clamps. During euglycemic insulin-glucose clamps, diabetic subjects showed glucose disposal rates of 3.44 ± 0.42 and 7.34 ± 0.34 mg · kg−1 · min−1 (means ± SD) before metformin at insulin infusion rates of 0.80 and 15.37 mU · kg−1 · min−1, respectively. With the same insulin infusion rates, glucose disposal was 4.94 ± 0.55 (P < .01) and 8.99 ± 0.66 (P < .01), respectively, after metformin treatment. Glucose disposal rates in normal obese subjects were 5.76 ± 0.63 (P < .01) and 10.92 ± 1.11 (P < .01) at 0.80 and 15.37 mU · kg−1 · min−1, respectively. Insulin maximum binding to erythrocytes in diabetics was 9.6 ± 4.2 and 5.8 ± 2.6 × 109 cells (means ± SD) before and after metformin treatment, respectively (NS). Insulin maximum binding to monocytes in diabetics was 6.2 ± 2.3 × 107 cells before and 5.0 ± 1.6% after metformin. Hepatic glucose production was higher in the diabetic patients at basal insulin levels, but not at higher insulin concentrations, and was not significantly changed by drug treatment. Basal glucose and insulin concentrations decreased with metformin. Thus, metformin treatment improved glucose disposal rate without significant effect on insulin-binding capacity on circulating cells. Basal hepatic glucose output was slightly lower after metformin treatment in view of lower (9 vs. 15 μU/ml) insulin levels, potentially indicating increased sensitivity of the liver to insulin.

Intracellular lactate- and pyruvate-interconversion rates are increased in muscle tissue of non-insulin-dependent diabetic individuals.

The contribution of muscle tissues of non-insulin-dependent diabetes mellitus (NIDDM) patients to blood lactate appearance remains undefined. To gain insight on intracellular pyruvate/lactate metabolism, the postabsorptive forearm metabolism of glucose, lactate, FFA, and ketone bodies (KB) was assessed in seven obese non-insulin-dependent diabetic patients (BMI = 28.0 +/- 0.5 kg/m2) and seven control individuals (BMI = 24.8 +/- 0.5 kg/m2) by using arteriovenous balance across forearm tissues along with continuous infusion of [3-13C1]-lactate and indirect calorimetry. Fasting plasma concentrations of glucose (10.0 +/- 0.3 vs. 4.7 +/- 0.2 mmol/liter), insulin (68 +/- 5 vs. 43 +/- 6 pmol/liter), FFA (0.57 +/- 0.02 vs. 0.51 +/- 0.02 mmol/liter), and blood levels of lactate (1.05 +/- 0.04 vs. 0.60 +/- 0.06 mmol/liter), and KB (0.48 +/- 0.04 vs. 0.29 +/- 0.02 mmol/liter) were higher in NIDDM patients (P < 0.01). Forearm glucose uptake was similar in the two groups (10.3 +/- 1.4 vs. 9.6 +/ 1.1 micromol/min/liter of forearm tissue), while KB uptake was twice as much in NIDDM patients as compared to control subjects. Lactate balance was only slightly increased in NIDDM patients (5.6 +/- 1.4 vs. 3.3 +/- 1.0 micromol/min/liter; P = NS). A two-compartment model of lactate and pyruvate kinetics in the forearm tissue was used to dissect out the rates of lactate to pyruvate and pyruvate to lactate interconversions. In spite of minor differences in the lactate balance, a fourfold increase in both lactate- (44.8 +/- 9.0 vs. 12.6 +/- 4.6 micromol/min/liter) and pyruvate-(50.4 +/- 9.8 vs. 16.0 +/- 5.0 micromol/min/liter) interconversion rates (both P < 0.01) were found. Whole body lactate turnover, assessed by using the classic isotope dilution principle, was higher in NIDDM individuals (46 +/- 9 vs. 21 +/- 3 micromol/min/kg; P < 0.01). Insights into the physiological meaning of this parameter were obtained by using a whole body noncompartmental model of lactate/pyruvate kinetics which provides a lower and upper bound for total lactate and pyruvate turnover (NIDDM = 46 +/- 9 vs. 108 +/- 31; controls = 21 +/- 3 - 50 +/-13 micromol/min/kg). In conclusion, in the postabsorptive state, despite a trivial lactate release by muscle, lactate- and pyruvate-interconversion rates are greatly enhanced in NIDDM patients, possibly due to concomitant impairment in the oxidative pathway of glucose metabolism. This finding strongly suggest a major disturbance in intracellular lactate/pyruvate metabolism in NIDDM.

Effect of Ethanol, Acetaldehyde, and Acetate on Insulin and Glucagon Secretion in the Perfused Rat Pancreas

The effects of varying concentrations of ethanol (1,10, and 30 mM) and its metabolites (1 mM acetate and 1 and 10 mM acetaldehyde) on insulin and glucagon secretion induced by glucose (11.1 mM) and arginine (20 mM) were studied in isolated perfused pancreas of Sprague-Dawley rats Ethanol and its metabolites did not significantly modify basal secretion of the two hormones. Ethanol reduced glucose-induced insulin secretion by means of a dose-related effect. Arginine-induced insulin output did not seem to be influenced to any significant degree. Acetate and acetaldehyde significantly inhibited glucose and arginine-induced insulin secretion. While ethanol (10 and 30 mM) did not modify glucagon output during arginine perfusion, acetate and acetaldehyde markedly enhanced it. The block of insulin secretion and the increased secretion of glucagon could explain the diabetogenic effect of ethanol demonstrated in vivo. The mechanism by which ethanol acts on the pancreatic β- and α-cells is discussed.

Epinephrine Exerts Opposite Effects on Peripheral Glucose Disposal and Glucose-Stimulated Insulin Secretion: A Stable Label Intravenous Glucose Tolerance Test Minimal Model Study

Epinephrine (EPI) plays a pivotal role in regulating glucose metabolism both in splanchnic and peripheral tissues. Nevertheless, previous studies did not clarify the mechanisms by which EPI affect both glucose disposal processes in peripheral tissues and β-cell secretion. The aim of this study was to investigate, in six normal volunteers, the effects of elevated EPI concentration on peripheral glucose disposal and insulin secretion by using the stable labeled (either [6,6-2H2] or [2-2H1]glucose) intravenous glucose tolerance test (IVGTT) in conjunction with the minimal models of labeled glucose disappearance and C-peptide secretion. Elevated plasma EPI concentration significantly decreased glucose effectiveness (SG*) by 29% (0.0059 ± 0.0013 vs. 0.0083 ± 0.0011 min−1, P < 0.05), and even more, 61%, insulin sensitivity (SI*); (22 ± 6 · 10(4) vs. 54 ± 20 · 10(4) min−1.pmol.l−1; P < 0.01). These findings are not due to an isotopic effect induced by an enhanced glycogen breakdown, because the [2-2H1]glucose tracer, which is not incorporated into glycogen, gave results similar to those of [6,6-2H2]glucose tracer. No differences were observed in first phase cell sensitivity, phi 1, in the EPI study (199 ± 91 vs. 245 ± 144 10(9), NS), but there was a significant increase in the second-phase cell sensitivity to glucose phi 2, (15.2 ± 1.7 vs. 17.7 ± 4.4 10(9).min−1, P < 0.05). In conclusion, EPI selectively impairs peripheral glucose metabolism because of its unique ability to simultaneously and independently decrease glucose effectiveness and insulin sensitivity. Furthermore, EPI enhances phi 2, the ratio between the C-peptide amount secreted during the second phase and the area under the curve of the glucose signal, indicating that the observed increase of C-peptide concentration is due not only to the augmented glucose signal but also to a specific EPI-mediated enhancement of β-cell responsivity to glucose.

Altered glucose metabolism and proteolysis in pancreatic cancer cell conditioned myoblasts: searching for a gene expression pattern with a microarray analysis of 5000 skeletal muscle genes

Background and aims: We verified whether conditioned media (CM) from pancreatic cancer cell lines (MIAPaCa2, CAPAN-1, PANC-1, BxPC3) alter glucose metabolism and gene expression profiles (microarray experiment with a platform of 5000 skeletal muscle cDNA) in mice myoblasts. Methods: Myoblasts were incubated with control or pancreatic cancer CM for 24 and 48 hours. Results: Lactate significantly increased in CM compared with non-conditioned myoblasts. No variations in expression levels of the main genes involved in glycolysis were found in CM myoblasts. Propionyl coenzyme A carboxylase and isocitrate dehydrogenase 3 beta genes, which encode enzymes of the tricarboxylic acid cycle, were overexpressed, while IGFIIR and VAMP5 genes were underexpressed in CM myoblasts. PAFAH1B1 and BCL-2 genes (intracellular signal transduction) and the serine protease cathepsin G (proteolysis), were overexpressed in CM myoblasts. Tyrosine accumulation in CM myoblasts suggested that proteolysis overcomes protein synthesis. Sorcin, actin alpha, troponin T1, and filamin A were underexpressed in CM myoblasts. Conclusions: Our findings demonstrate that pancreatic cancer cell conditioned media enhanced lactate production and induced proteolysis, possibly by altering expression levels of a large number of genes, not only those involved in protein biosynthesis and degradation or glucose metabolism, but also those involved in the tricarboxylic acid cycle and in vesicle traffic.

An Unidentified Pancreatic Cancer Cell Product Alters Some Intracellular Pathways of Glucose Metabolism in Isolated Rat Hepatocytes

In this study we assessed whether conditioned media from a human pancreatic cancer cell line (MIA PaCa 2) can interfere with some intracellular pathways involved in glucose metabolism in isolated rat hepatocytes. The hepatocytes, isolated from Male Wistar rats, were incubated with MIA PaCa 2-conditioned or nonconditioned media. Conditioned and nonconditioned hepatocytes were run for 120 min in the presence or absence of insulin (100 mM) and were sampled at fixed time intervals. Supernatant glucose levels decreased to a similar extent over time in both conditioned and nonconditioned hepatocytes, while lactate levels significantly increased in nonconditioned hepatocytes with respect to conditioned hepatocytes. A pyruvate kinase activity increase was observed only in nonconditioned hepatocytes and was biphasic in nature, since this increased activity was detected both after a few and after 30 min following insulin stimulation. The cyclic AMP level increase was significantly higher in conditioned than in non-conditioned hepatocytes. It appears that MIA PaCa 2 cells produce a factor(s) that may interfere with one of the insulin-mediated intracellular pathways of glucose metabolism, namely, glycolysis. This detrimental effect on glycolysis is supported by the blunted rise in lactate concentration in the medium after the glucose challenge. This substance(s) probably transfers its signal inside the target cells, activating the adenylate cyclase pathway. These results support the hypothesis that pancreatic cancer is the cause rather than the consequence of diabetes mellitus.

Metabolic Control of Kidney Hemodynamics in Normal and Insulin-Dependent Diabetic Subjects: Effects of Acetoacetic, Lactic, and Acetic Acids

Diabetes mellitus is associated with important changes in renal hemodynamics. The purpose of this study was to determine whether an increase in blood concentration patterns of ketone bodies and lactic acid, organic acids often elevated in poorly controlled insulin-dependent diabetes mellitus (IDDM), could contribute to increase glomerular filtration rate (GFR) and renal plasma flow (RPF) regardless of changes in circulating levels of glucose and insulin. Six IDDM patients and six normal subjects were given a saline infusion (15 μmol · min−1 · kg−1) for 2 h, an acetoacetic acid infusion (15 μmol · min−1 · kg−1) for another 2 h, and then a saline infusion after an overnight fast during euglycemic insulin-glucose clamp. Acetoacetic acid infusion resulted in an increase of blood ketone bodies in the range of 0.7–1.5 mM from a basal value of 0.1–0.3 mM. GFR was 125 ± 16 and 136 ± 17 ml · min−1 · 1.73 m−2 in normal and IDDM subjects, respectively, during baseline saline infusion and 138 ± 21 (P < .01 vs. basal level) and 158 ± 15 ml · min−1 · 1.73 m−2 (P < .001 vs. basal level) during acetoacetic acid infusion. During the last saline infusion, renal hemodynamic patterns decreased again to baseline levels. Another six IDDM patients and six normal subjects were given saline, lactic acid, and saline infusions at the same rates of infusion after an overnight fast during euglycemic insulin-glucose clamp. Lactic acid concentration increased from ∼0.5–0.8 to 1.0–1.5 mM in both groups. GFR was 125 ± 9 and 144 ± 18 ml · min−1 · 1.73 m−2 in normal and IDDM subjects, respectively, during baseline saline infusion and 135 ± 8 and 158 ± 16 ml · min1 · 1.73 m−2 during lactic acid infusion (P < .01 vs. basal level). Acetoacetic acid and lactic acid infusion resulted in a 14.7 and 7.6% increase, respectively, in RPF compared with baseline values in normal subjects and in a 12.6 and 6.9% increase, respectively in IDDM subjects. With the same protocol of the previous organic acid infusion, another five normal and six IDDM patients were given an acetic acid infusion (15 μmol · kg−1 · min−1), resulting in an increase of plasma circulating levels of acetic acid from 0.1–0.2 to 0.3–0.4 mM, which was associated with negligible changes in ketone body and lactic acid concentrations. Neither GFR nor RPF were influenced by acetic acid administration. During acetoacetic acid and lactic acid infusion, both lactic and ketone body acid tubular reabsorption rates were three to five times higher than during saline infusion. In conclusion, lactic acid and acetoacetic acid infusion resulting in circulating patterns of these intermediate metabolites comparable with those often found in poorly controlled IDDM subjects induced a significant increase in GFR and RPF in normal and IDDM subjects. The increased GFR was associated with stimulation of organic acid tubular reabsorption rate and was not related to sodium and liquid overload, because it returned to basal value when saline alone was administered again.

Ketone bodies increase glomerular filtration rate in normal man and in patients with Type 1 (insulin-dependent) diabetes mellitus

SummaryThe purpose of this study was to investigate whether the administration of acetoacetic and hydrochloric acids in a group of control and Type 1 (insulin-dependent) diabetic patients influenced renal haemodynamics. Renal plasma flow increased from 657±88 to 762±81 ml·min−1. 1.73 m−2 in diabetic patients (p<0.01) and from 590±71 to 691±135 in control subjects (p<0.01). Glomerular filtration rate increased from 135±9 to 180±8 ml·min−1·1.73 m−2 in diabetic patients (p< 0.001) and from 117±8 to 145±7 in control subjects (p<0.01). Similar effects on renal haemodynamics, even if less pronounced, were observed with low dose acetoacetic but not with hydrochloric acid infusion. Total protein, β2-microglobulin but not albumin excretion rates were increased by acetoacetic acid. We conclude that an acute increase in blood concentration of ketone bodies within the range found in diabetic patients with poor metabolic control (1) increases renal plasma flow and glomerular filtration rate both in control subjects and diabetic patients and (2) causes a tubular proteinuria.

The effects of different plasma insulin concentrations on lipolytic and ketogenic responses to epinephrine in normal and Type 1 (insulin-dependent) diabetic humans

SummaryThis study was performed to verify: (1) the ability of different insulin concentrations to restrict the lipolytic and ketogenic responses to exogenous epinephrine administration; (2) whether the ability of insulin to suppress the lipolytic and ketogenic responses during epinephrine administration is impaired in Type 1 (insulin-dependent) diabetic patients. Each subject was infused on separate occasions with insulin at rates of 0.2, 0.4, and 0.8 mU·kg−1·min−1 while normoglycaemic. To avoid indirect adrenergic effects on endocrine pancreas secretions, the so-called “islet clamp” technique was used. Rates of appearance of palmitic acid, acetoacetate, and 3-hydroxybutyrate were simultaneously measured with an infusion of 13C-labelled homologous tracers. After a baseline observation period epinephrine was exogenously administered at a rate of 16 ng·kg−1·min−1. At low insulin levels (20 μU/ml) the lipolytic response of comparable magnitude was detected in normal and Type 1 diabetic patients. However, the ketogenic response was significantly higher in Type 1 diabetic patients. During epinephrine administration, similar plasma glucose increments were observed in the two groups (from 4.74±0.53 to 7.16±0.77 mmol/l (p<0.05) in Type 1 diabetic patients and from 4.94±0.20 to 7.11±0.38 mmol/l (p<0.05) in normal subjects, respectively). At intermediate insulin levels (35 μU/ml) no significant differences were found between Type 1 diabetic patients and normal subjects, whereas plasma glucose levels rose from 4.98±0.30 to 6.27±0.66 mmol/l (p<0.05) in Type 1 diabetic patients, and from 5.05±0.13 to 6.61±0.22 mmol/l (p<0.05) in normal subjects. At high insulin levels (70 μU/ml) the lipolytic response was detectable only in Type 1 diabetic patients; the ketogenic response was reduced in both groups. During the third clamp, a significant rise in plasma glucose concentration during epinephrine infusion was observed in both groups. In conclusion this study shows that at low insulin levels Type 1 diabetic patients show an increased ketogenic response to epinephrine, despite their normal nonesterified fatty acid response. Instead, high insulin levels are able to restrict the ketogenic response to epinephrine in both normal and Type 1 diabetic subjects, although there is a still detectable lipolytic response in the latter. In the presence of plasma free insulin levels that completely restrict the ketogenic response in the same group, there is still a distinct glycaemic response. Plasma insulin levels in Type 1 diabetic patients are a major determinant of the metabolic response to epinephrine.