Doss W. Neal

The Role of Fatty Acids in Mediating the Effects of Peripheral Insulin on Hepatic Glucose Production in the Conscious Dog

We investigated the mechanism by which a selective increase in arterial insulin can suppress hepatic glucose production in vivo. Isotopic (3-3H-glucose) and arteriovenous difference methods were used in overnight-fasted, conscious dogs. A pancreatic clamp (somatostatin, basal portal insulin, and glucagon infusions) was used to control the endocrine pancreas. Equilibration (100 min) and basal (40 min) periods were followed by a 180-min test period. In control dogs (n = 5), basal insulin delivery was continued throughout the study. In the other two groups, peripheral insulin was selectively increased at the beginning of the test period by stopping the portal insulin infusion and infusing insulin peripherally at twice the basal portal rate. One group (INS + FAT; n = 6) received an infusion of 20% intralipid + heparin (0.5 U · kg−1 · min−1) to clamp the nonesterified fatty acid (NEFA) levels during hyperinsulinemia; the other group (INS; n = 7) received only saline during the experimental period. In the INS group, a selective increase in peripheral insulin of 84 pmol/l was achieved (36 ± 6 to 120 ± 24 pmol/l, last 30 min) while portal insulin was unaltered (84 ± 18 pmol/l). In the INS + FAT group, a similar increase in peripheral insulin was achieved (36 ± 6 to 114 ± 6 pmol/l, last 30 min); again, portal insulin was unaltered (96 ± 12 pmol/l). In the control group, basal insulin did not change. Glucagon and glucose remained near basal values in all protocols. In the INS group, NEFA levels dropped from 700 ± 90 (basal) to 230 ± 65 μmol/l (last 30 min; P > 0.05), but in the INS + FAT group changed minimally (723 ± 115 [basal] to 782 ± 125 μmol/l [last 30 min]). In the INS group, net hepatic glucose output dropped by 6.7 μmol · kg−1 · min−1 (P < 0.05), whereas in the INS + FAT group it dropped by 3.9 μmol · kg−1 · min−1 (P < 0.05). When insulin levels were not increased (i.e., in the control group), net hepatic glucose output dropped 1.7 μmol · kg−1 · min−1 (P , 0.05). In all groups, the net hepatic glucose output data were confirmed by the tracer-determined glucose production data. In the INS group, net hepatic gluconeogenic substrate uptake (alanine, glutamine, glutamate, glycerol, glycine, lactate, threonine, and serine) fell slightly (10.4 ± 1.3 [basal] to 7.2 ± 1.3 μmol · kg−1 · min−1 [last 30 min]), whereas in the INS + FAT group it did not change (7.3 ±1.5 [basal] to 7.4 ± 0.6 μmol · kg−1 · min−1 [last 30 min]), and in the control group it increased slightly (9.6 ± 1.3 [basal] to 10.3 ± 1.4 μmol · kg−1 · min−1 [last 30 min]). These results indicate that peripheral insulins ability to regulate hepatic glucose production is partially linked to its inhibition of lipolysis. When plasma NEFA levels were prevented from falling during a selective arterial hyperinsulinemia, ∼55% of insulin%s inhibition of net hepatic glucose output (NHGO) was eliminated. The fall in NEFA levels brings about a redirection of glycogenolytically derived carbon within the hepatocyte such that there is an increase in lactate efflux and a corresponding decrease in NHGO.

Comparison of the time courses of insulin and the portal signal on hepatic glucose and glycogen metabolism in the conscious dog.

To investigate the temporal response of the liver to insulin and portal glucose delivery, somatostatin was infused into four groups of 42-h-fasted, conscious dogs (n = 6/group), basal insulin and glucagon were replaced intraportally, and hyperglycemia was created via a peripheral glucose infusion for 90 min (period 1). This was followed by a 240-min experimental period (period 2) in which hyperglycemia was matched to period 1 and either no changes were made (CON), a fourfold rise in insulin was created (INS), a portion of the glucose (22.4 mumol.kg-1.min-1) was infused via the portal vein (Po), or a fourfold rise in insulin was created in combination with portal glucose infusion (INSPo). Arterial insulin levels were similar in all groups during period 1 (approximately 45 pM) and were 45 +/- 9, 154 +/- 20, 43 +/- 7, and 128 +/- 14 pM during period 2 in CON, INS, Po, and INSPo, respectively. The hepatic glucose load was similar between periods and among groups (approximately 278 mumol.kg-1.min-1). Net hepatic glucose output was similar among groups during period 1 (approximately 0.1 mumol.kg-1.min-1) and did not change significantly in CON during period 2. In INS net hepatic glucose uptake (NHGU; mumol.kg-1.min-1) was -3.8 +/- 3.3 at 15 min of period 2 and did not reach a maximum (-15.9 +/- 6.6) until 90 min. In contrast, NHGU reached a maximum of -13.0 +/- 3.7 in Po after only 15 min of period 2. In INSPo, NHGU reached a maximum (-23.6 +/- 3.5) at 60 min. Liver glycogen accumulation during period 2 was 21 +/- 10, 84 +/- 17, 65 +/- 16, and 134 +/- 17 mumol/gram in CON, INS, Po, and INSPo, respectively. The increment (period 1 to period 2) in the active form of liver glycogen synthase was 0.7 +/- 0.4, 6.5 +/- 1.2, 2.8 +/- 1.0, and 8.5 +/- 1.3% in CON, INS, Po, and INSPo, respectively. Thus, in contrast to insulin, the portal signal rapidly activates NHGU. In addition, the portal signal independent of a rise in insulin, can cause glycogen accumulation in the liver.

A Comparison of the Effects of Selective Increases in Peripheral or Portal insulin on Hepatic Glucose Production in the Conscious Dog

We investigated the mechanisms by which peripheral or portal insulin can independently alter liver glucose production. Isotopic ([3-3H]glucose) and arteriovenous difference methods were used in conscious overnight-fasted dogs. A pancreatic clamp (somatostatin plus basal insulin and basal glucagon infusions) was used to control the endocrine pancreas. After a 40-min basal period, a 180-min experimental period followed in which selective increases in peripheral (PERI group, n = 5) or portal-vein (PORT group, n = 5) insulin were induced. In control dogs (CONT group, n = 10), insulin was not increased. Glucagon levels were fixed in all studies, and basal euglycemia was maintained by peripheral glucose infusion in the two experimental groups. In the PERI group, arterial insulin rose from 36 ± 12 to 120 ± 12 pmol/l, while portal insulin was unaltered. In the PORT group, portal insulin rose from 108 ± 42 to 192 ± 42 pmol/l, while arterial insulin was unaltered. Neither arterial nor portal insulin changed from basal in the CONT group. With a selective rise in peripheral insulin, the net hepatic glucose output (NHGO; basal, 11.8 ± 0.7 µmol · kg−1 · min−1) did not change initially (11.8 ± 2.1 µmol · kg−1 · min−1, 30 min after the insulin increase), but eventually fell (P < 0.05) to 6.1 ± 0.9 µmol · kg−1 · min−1 (last 30 min). With a selective rise in portal insulin, NHGO dropped quickly (P < 0.05) from 10.0 ± 0.9 to 5.6 ± 0.6 µmol · kg−1 · min−1 (30 min after the insulin increase) and eventually reached 3.1 ± 1.1 µmol x kg−1 · min−1 (last 30 min). When insulin levels were not increased (CONT group), NHGO dropped progressively from 10.1 ± 0.6 to 8.3 ± 0.6 µmol · kg−1 · min−1 (last 30 min). Conclusions drawn from the net hepatic glucose balance data were confirmed by the tracer data. Net hepatic gluconeogenic substrate uptake (three carbon precursors) fell 2.0 µmol · kg−1 · min−1 in the PERI group, but rose 1.2 µmol · kg−1 · min−1 in the PORT group and 1.2 µmol · kg−1 · min−1 in the CONT group. A selective 84 pmol/l rise in arterial insulin was thus associated with a fall in NHGO of ∼ 50%, which took 1 h to manifest. Conversely, a selective 84 pmol/l rise in portal insulin was associated with a 50% fall in NHGO, which occurred quickly (15 min). From the control data, it is evident that in either case ∼ 30% of the fall in NHGO was due to a drift down in baseline and that 70% was due to the rise in insulin. In conclusion, an increment in portal insulin had a rapid inhibitory effect on NHGO, caused by the suppression of glycogenolysis, while an equal increment in arterial insulin produced an equally potent but slower effect that resulted from a small increase in hepatic sinusoidal insulin, from a suppression of gluconeogenic precursor uptake by the liver, and from a redirection of glycogenolytic carbon to lactate rather than glucose.

Insulin's direct effects on the liver dominate the control of hepatic glucose production

Insulin inhibits glucose production through both direct and indirect effects on the liver; however, considerable controversy exists regarding the relative importance of these effects. The first aim of this study was to determine which of these processes dominates the acute control of hepatic glucose production (HGP). Somatostatin and portal vein infusions of insulin and glucagon were used to clamp the pancreatic hormones at basal levels in the nondiabetic dog. After a basal sampling period, insulin infusion was switched from the portal vein to a peripheral vein. As a result, the arterial insulin level doubled and the hepatic sinusoidal insulin level was reduced by half. While the arterial plasma FFA level and net hepatic FFA uptake fell by 40-50%, net hepatic glucose output increased more than 2-fold and remained elevated compared with that in the control group. The second aim of this study was to determine the effect of a 4-fold rise in head insulin on HGP during peripheral hyperinsulinemia and hepatic insulin deficiency. Sensitivity of the liver was not enhanced by increased insulin delivery to the head. Thus, this study demonstrates that the direct effects of insulin dominate the acute regulation of HGP in the normal dog.

Brain insulin action augments hepatic glycogen synthesis without suppressing glucose production or gluconeogenesis in dogs

In rodents, acute brain insulin action reduces blood glucose levels by suppressing the expression of enzymes in the hepatic gluconeogenic pathway, thereby reducing gluconeogenesis and endogenous glucose production (EGP). Whether a similar mechanism is functional in large animals, including humans, is unknown. Here, we demonstrated that in canines, physiologic brain hyperinsulinemia brought about by infusion of insulin into the head arteries (during a pancreatic clamp to maintain basal hepatic insulin and glucagon levels) activated hypothalamic Akt, altered STAT3 signaling in the liver, and suppressed hepatic gluconeogenic gene expression without altering EGP or gluconeogenesis. Rather, brain hyperinsulinemia slowly caused a modest reduction in net hepatic glucose output (NHGO) that was attributable to increased net hepatic glucose uptake and glycogen synthesis. This was associated with decreased levels of glycogen synthase kinase 3β (GSK3β) protein and mRNA and with decreased glycogen synthase phosphorylation, changes that were blocked by hypothalamic PI3K inhibition. Therefore, we conclude that the canine brain senses physiologic elevations in plasma insulin, and that this in turn regulates genetic events in the liver. In the context of basal insulin and glucagon levels at the liver, this input augments hepatic glucose uptake and glycogen synthesis, reducing NHGO without altering EGP.

Molecular Characterization of Insulin-Mediated Suppression of Hepatic Glucose Production In Vivo

OBJECTIVE Insulin-mediated suppression of hepatic glucose production (HGP) is associated with sensitive intracellular signaling and molecular inhibition of gluconeogenic (GNG) enzyme mRNA expression. We determined, for the first time, the time course and relevance (to metabolic flux) of these molecular events during physiological hyperinsulinemia in vivo in a large animal model. RESEARCH DESIGN AND METHODS 24 h fasted dogs were infused with somatostatin, while insulin (basal or 8× basal) and glucagon (basal) were replaced intraportally. Euglycemia was maintained and glucose metabolism was assessed using tracer, 2H2O, and arterio-venous difference techniques. Studies were terminated at different time points to evaluate insulin signaling and enzyme regulation in the liver. RESULTS Hyperinsulinemia reduced HGP due to a rapid transition from net glycogen breakdown to synthesis, which was associated with an increase in glycogen synthase and a decrease in glycogen phosphorylase activity. Thirty minutes of hyperinsulinemia resulted in an increase in phospho-FOXO1, a decrease in GNG enzyme mRNA expression, an increase in F2,6P2, a decrease in fat oxidation, and a transient decrease in net GNG flux. Net GNG flux was restored to basal by 4 h, despite a substantial reduction in PEPCK protein, as gluconeogenically-derived carbon was redirected from lactate efflux to glycogen deposition. CONCLUSIONS In response to acute physiologic hyperinsulinemia, 1) HGP is suppressed primarily through modulation of glycogen metabolism; 2) a transient reduction in net GNG flux occurs and is explained by increased glycolysis resulting from increased F2,6P2 and decreased fat oxidation; and 3) net GNG flux is not ultimately inhibited by the rise in insulin, despite eventual reduction in PEPCK protein, supporting the concept that PEPCK has poor control strength over the gluconeogenic pathway in vivo.

Effects of Insulin on the Metabolic Control of Hepatic Gluconeogenesis In Vivo

OBJECTIVE Insulin represses the expression of gluconeogenic genes at the mRNA level, but the hormone appears to have only weak inhibitory effects in vivo. The aims of this study were 1) to determine the maximal physiologic effect of insulin, 2) to determine the relative importance of its effects on gluconeogenic regulatory sites, and 3) to correlate those changes with alterations at the cellular level. RESEARCH DESIGN AND METHODS Conscious 60-h fasted canines were studied at three insulin levels (near basal, 4×, or 16×) during a 5-h euglycemic clamp. Pancreatic hormones were controlled using somatostatin with portal insulin and glucagon infusions. Glucose metabolism was assessed using the arteriovenous difference technique, and molecular signals were assessed. RESULTS Insulin reduced gluconeogenic flux to glucose-6-phosphate (G6P) but only at the near-maximal physiological level (16× basal). The effect was modest compared with its inhibitory effect on net hepatic glycogenolysis, occurred within 30 min, and was associated with a marked decrease in hepatic fat oxidation, increased liver fructose 2,6-bisphosphate level, and reductions in lactate, glycerol, and amino acid extraction. No further diminution in gluconeogenic flux to G6P occurred over the remaining 4.5 h of the study, despite a marked decrease in PEPCK content, suggesting poor control strength for this enzyme in gluconeogenic regulation in canines. CONCLUSIONS Gluconeogenic flux can be rapidly inhibited by high insulin levels in canines. Initially decreased hepatic lactate extraction is important, and later reduced gluconeogenic precursor availability plays a role. Changes in PEPCK appear to have little or no acute effect on gluconeogenic flux.

Sildenafil citrate does not affect cardiac contractility in human or dog heart

SUMMARY Objective: This study evaluated whether sildenafil citrate, an oral treatment for erectile dysfunction and a selective inhibitor of phosphodiesterase type 5 (PDE5) with modest vasodilating properties, affects cardiac contractility in vitro. Research design and methods: Slices of freshly obtained human (n = 2) or dog (n = 3) atrial appendage were suspended in organ baths containing Krebs—Ringer bicarbonate buffer (pH 7.4, 37°C) bubbled continuously with 95% O2 and 5% CO2, and isometric tension was recorded using a Gould physiograph. Contractions were elicited by 1-Hz electric pacing. After 15min of equilibration, 1\M sildenafil was added to the bath, followed 15min later (human and dog) by 5|iM epinephrine, an inotropic agent, and 10min later (dog) by 88|iM 3-isobutyl-1 -methylxanthine (IBMX), a nonselective PDE inhibitor. In a separate experiment, cyclic guanosine monophosphate levels and PDE, protein kinase G, and protein kinase A activities were determined. Results: Addition of 1 |iM sildenafil to isolated dog or human atrial tissue had no significant effect on force of cardiac contraction, whereas epinephrine produced a robust increase in contractile force in the same muscle strip. The addition of IBMX produced a marked stimulation of contractile force in dog atrial tissue. Very low amounts of PDE5 were found in extracts of human heart, consistent with its known primary location in the smooth muscle of systemic vasculature. Conclusions: Sildenafil is unlikely to directly produce inotropic effects on cardiac muscle in patients being treated for erectile dysfunction.

Magnitude of Negative Arterial-Portal Glucose Gradient Alters Net Hepatic Glucose Balance in Conscious Dogs

To examine the relationship between the magnitude of the negative arterial-portal glucose gradient and net hepatic glucose uptake, two groups of 42-h fasted, conscious dogs were infused with somatostatin, to suppress endogenous insulin and glucagon secretion, and the hormones were replaced intraportally to create hyperinsulinemia (3- to 4-fold basal) and basal glucagon levels. The hepatic glucose load to the liver was doubled and different negative arterial-portal glucose gradients were established by altering the ratio between portal and peripheral vein glucose infusions. In protocol 1 (n = 6) net hepatic glucose uptake was 42.2 ± 6.7, 35.0 ± 3.9, and 33.3 ± 4.4 μmol · kg−1 · min−1 at arterial-portal plasma glucose gradients of −4.1 ± 0.9, −1.8 ± 0.4, and −0.8 ± 0.1 mM, respectively. In protocol 2 (n = 6) net hepatic glucose uptake was 26.1 ± 2.8 and 12.2 ± 1.7 μmol · kg−1 · min−1 at arterial-portal plasma glucose gradients of −0.9 ± 0.2 and −0.4 ± 0.1 mM, respectively. No changes in the hepatic insulin or glucose loads were evident within a given protocol. Although net hepatic glucose uptake was lower in protocol 2 when compared with protocol 1 (26.1 ± 2.8 vs. 33.3 ± 4.4 μmol · kg−1 · min−1) in the presence of a similar arterial-portal plasma glucose gradient (−0.9 vs. −0.8 mM) the difference could be attributed to the hepatic glucose load being lower in protocol 2 (i.e., hepatic fractional glucose extraction was not significantly different) primarily as a result of lower hepatic blood flow. In conclusion, in the presence of fixed hepatic glucose and insulin loads, the magnitude of the negative arterial-portal glucose gradient can modify net hepatic glucose uptake in vivo.

Compartmental Modeling of Glucagon Kinetics in the Conscious Dog

The aim of the present study was to examine glucagon metabolism and distribution using both compartmental-modeling approaches and steady-state organ-balance techniques in conscious, overnight-fasted dogs. Arterial plasma glucose concentrations were clamped at 14 mmol/L with a variable exogenous glucose infusion. Somatostatin was infused to block endogenous secretion of insulin and glucagon. Insulin was replaced intraportally at 2.4 pmol.kg-1.min-1 to maintain basal insulin concentrations in the range from 70 +/- 4 to 95 +/- 12 pmol/L. Glucagon was not given during the control period, but was subsequently infused peripherally in four 1-hour steps of 1.0, 3.0, 6.0, and 3.0 ng.kg-1.min-1. Glucagon levels increased from 0 to 68 +/- 6, 195 +/- 19, 378 +/- 47, and 181 +/- 20 ng/mL. Compartmental analysis of glucagon concentrations showed that glucagon was distributed in one compartment with a volume approximately equal to the plasma volume. The metabolic clearance rate of glucagon was 17.6 mL.kg-1.min-1. The liver cleared 24% of glucagon, and the kidneys, 17%.