Insulin is required for the liver to respond to intraportal glucose delivery in the conscious dog.

To determine whether insulin is essential for the augmented hepatic glucose uptake observed in the presence of intraportal glucose delivery, SRIF was used to induce acute insulin deficiency in 5 conscious dogs, and glucose was infused into the portal vein or a peripheral vein in two sequential, randomized periods. Insulin and C-peptide levels were below the limits of detection after SRIF infusion, and the load of glucose presented to the liver was approximately doubled and equivalent during the portal and peripheral periods. Net hepatic glucose output was 2.9 +/- 0.9 and 2.1 +/- 1.1 mumol.kg-1.min-1 during portal and peripheral glucose delivery, respectively. In an additional set of protocols, pancreatectomized dogs were used to investigate the effects of prolonged insulin deficiency (n = 5) and acute insulin replacement (n = 4) on the hepatic response to intraportal glucose delivery. In the prolonged insulin deficiency protocol, SRIF was used to lower glucagon and thereby reduce circulating glucose levels, and glucose was infused into the portal or peripheral circulations in two sequential, randomized periods. As with acute insulin deficiency, net hepatic glucose output was still evident and similar (3.6 +/- 1.1 and 4.2 +/- 1.3 mumol.kg-1.min-1) during portal and peripheral glucose delivery, respectively. When the pancreatectomized dogs were restudied using a similar protocol, but one in which insulin was replaced (4X-basal), and the glucose load to the liver was matched to that which occurred in the prolonged insulin deficiency protocol, net hepatic glucose uptake was 23.6 +/- 6.1 mumol.kg-1.min-1 during portal glucose delivery but only 10.3 +/- 3.5 mumol.kg-1.min-1 during peripheral glucose delivery. These results suggest that the induction of net hepatic glucose uptake and the augmented hepatic response to intraportal glucose delivery require the presence of insulin.     

Alpha- and beta-cell responses to small changes in plasma glucose in the conscious dog

The responses of the pancreatic alpha- and beta-cells to small changes in glucose were examined in overnight-fasted conscious dogs. Each study consisted of an equilibration (-140 to -40 min), a control (-40 to 0 min), and a test period (0 to 180 min), during which BAY R3401 (10 mg/kg), a glycogen phosphorylase inhibitor, was administered orally, either alone to create mild hypoglycemia or with peripheral glucose infusion to maintain euglycemia or create mild hyperglycemia. Drug administration in the hypoglycemic group decreased net hepatic glucose output (NHGO) from 8.9 +/- 1.7 (basal) to 6.0 +/- 1.7 and 5.8 +/- 1.0 pmol x kg(-1) x min(-1) by 30 and 90 min. As a result, the arterial plasma glucose level decreased from 5.8 +/- 0.2 (basal) to 5.2 +/- 0.3 and 4.4 +/- 0.3 mmol/l by 30 and 90 min, respectively (P < 0.01). Arterial plasma insulin levels and the hepatic portal-arterial difference in plasma insulin decreased (P < 0.01) from 78 +/- 18 and 90 +/- 24 to 24 +/- 6 and 12 +/- 12 pmol/l over the first 30 min of the test period and decreased to 18 +/- 6 and 0 pmol/l by 90 min, respectively. The arterial glucagon levels and the hepatic portal-arterial difference in plasma glucagon increased from 43 +/- 5 and 4 +/- 2 to 51 +/- 5 and 10 +/- 5 ng/l by 30 min (P < 0.05) and to 79 +/- 16 and 31 +/- 15 ng/l by 90 min (P < 0.05), respectively. In euglycemic dogs, the arterial plasma glucose level remained at 5.9 +/- 0.1 mmol/l, and the NHGO decreased from 10 +/- 0.6 to -3.3 +/- 0.6 pmol x kg(-1) x min(-1) (180 min). The insulin and glucagon levels and the hepatic portal-arterial differences remained constant. In hyperglycemic dogs, the arterial plasma glucose level increased from 5.9 +/- 0.2 to 6.2 +/- 0.2 mmol/l by 30 min, and the NHGO decreased from 10 +/- 1.7 to 0 pmol x kg(-1) x min(-1) by 30 min. The arterial plasma insulin levels and the hepatic portal-arterial difference in plasma insulin increased from 60 +/- 18 and 78 +/- 24 to 126 +/- 30 and 192 +/- 42 pmol/l by 30 min, after which they averaged 138 +/- 24 and 282 +/- 30 pmol/l, respectively. The arterial plasma glucagon levels and the hepatic portal-arterial difference in plasma glucagon decreased slightly from 41 +/- 7 and 4 +/- 3 to 34 +/- 7 and 3 +/- 2 ng/l during the test period. These data show that the alpha- and beta-cells of the pancreas respond as a coupled unit to very small decreases in the plasma glucose level.     

Nonesterified fatty acids and hepatic glucose metabolism in the conscious dog

We used tracer and arteriovenous difference techniques in conscious dogs to determine the effect of nonesterified fatty acids (NEFAs) on net hepatic glucose uptake (NHGU). The protocol included equilibration ([3-(3)H]glucose), basal, and two experimental periods (-120 to -30, -30 to 0, 0-120 [period 1], and 120-240 min [period 2], respectively). During periods 1 and 2, somatostatin, basal intraportal insulin and glucagon, portal glucose (21.3 micromol.kg(-1).min(-1)), peripheral glucose (to double the hepatic glucose load), and peripheral nicotinic acid (1.5 mg.kg(-1).min(-1)) were infused. During period 2, saline (nicotinic acid [NA], n = 7), lipid emulsion (NA plus lipid emulsion [NAL], n = 8), or glycerol (NA plus glycerol [NAG], n = 3) was infused peripherally. During period 2, the NA and NAL groups differed (P < 0.05) in rates of NHGU (10.5 +/- 2.08 and 4.7 +/- 1.9 micromol.g(-1).min(-1)), respectively, endogenous glucose R(a) (2.3 +/- 1.4 and 10.6 +/- 1.0 micromol.kg(-1).min(-1)), net hepatic NEFA uptakes (0.1 +/- 0.1 and 1.8 +/- 0.2 micromol.kg(-1).min(-1)), net hepatic beta-hydroxybutyrate output (0.1 +/- 0.0 and 0.4 +/- 0.1 micromol.kg(-1).min(-1)), and net hepatic lactate output (6.5 +/- 1.7 vs. -2.3 +/- 1.2 micromol.kg(-1).min(-1)). Hepatic glucose uptake and release were 2.6 micro mol. kg(-1). min(-1) less and 3.5 micro mol. kg(-1). min(-1) greater, respectively, in the NAL than NA group (NS). The NAG group did not differ significantly from the NA group in any of the parameters listed above. In the presence of hyperglycemia and relative insulin deficiency, elevated NEFAs reduce NHGU by stimulating hepatic glucose release and suppressing hepatic glucose uptake.     

Interaction of somatostatin, glucagon, and insulin on hepatic glucose output in the normal dog.

The interaction of insulin and glucagon during infusion of somatostatin (SRIF), which suppresses secretion of these hormones, was investigated in normal, postabsorptive, concious dogs. Hepatic glucose output (production) and over-all glucose uptake by the tissues was measured with 3-3H-glucose, administered by a priming injection along with a constant infusion. Infusion of SRIF (1.5-5.0 mug/min) for 90 minutes resulted in a moderate hypoglycemia associated with a decrease in glucose production. In some animals glucose production and plasma glucose levels returned to normal before the end of SRIF infusion. Glucose uptake tended to follow plasma glucose levels. Upon termination of SRIF infusion, glucose production and uptake and plasma glucose increased sharply.     

Insulin's effect on Leucine turnover changes during early fasting in the conscious dog

To study the effects of insulin on leucine turnover during fasting, acute insulin deficiency was induced by the simultaneous infusion of somatostatin and glucagon in conscious dogs fasted 18 h (N = 10) and 48 h (N = 11). Insulin levels during the basal period (before hormone perturbation) were similar in both groups of dogs (12 +/- 3 versus 10 +/- 3 microU/ml, respectively). Glucagon levels were similar in the two groups (94 +/- 9 versus 106 +/- 19 pg/ml). Leucine levels rose from 118 +/- 9 mumol/L to 155 +/- 12 mumol/L as fasting progressed (P less than 0.005). Its rate of appearance also increased by 30% (P less than 0.005) from 3.4 +/- 0.3 to 4.3 +/- 0.4 mumol/kg/min (P less than 0.005), while its clearance remained unchanged. Acute insulin deficiency caused an increase in leucine levels in both 18-h and 48-h-fasted dogs by 55% (to 181 +/- 10 mumol/L) and 45% (to 225 +/- 20 mumol/L), respectively (P less than 0.005). However, while the rate of appearance of leucine remained unchanged in dogs fasted overnight, it rose to 5.1 +/- 0.3 mumol/kg/min (P less than 0.01) in those fasted 48 h. The metabolic clearance rate fell in both groups, although this drop was twice as great in the 18-h group (from 28 +/- 3 to 17 +/- 3 ml/kg/min, P less than 0.005) as in the 48-h group (from 28 +/- 3 to 23 +/- 2 ml/kg/min, P less than 0.005). We conclude that insulin has disparate effects on protein turnover as fasting becomes more prolonged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential time course of glucagon's effect on glycogenolysis and gluconeogenesis in the conscious dog

The evanescence of glucagon's effect on glucose production (GP) is well documented, but it is unclear (1) whether this response involves both glycogenolysis and gluconeogenesis and (2) whether the liver becomes dependent on the increased glucagon level for the maintenance of a basal supply of glucose. To answer these questions, conscious overnight-fasted dogs were given somatostatin (0.8 microgram/kg . min) plus basal intraportal replacement amounts of insulin (273 microU/kg . min) and glucagon (0.65 ng/kg . min) for 2 h, after which the rate of glucagon infusion was increased fourfold for 3 h and then returned to basal for 1.5 h. GP was determined using a primed infusion of [3-3H]glucose, and gluconeogenesis (GNG) was estimated by determining the conversion rate of alanine and lactate to glucose. An increase in the plasma glucagon level from 55 to 206 pg/ml resulted in an initial 180% increase in GP, followed by a decline such that after 3 h of hyperglucagonemia GP was increased by only 41%. Contrary to overall GP, gluconeogenesis increased progressively throughout the hyperglucagonemic period, eventually reaching a rate 3 times basal. Restoration of the basal glucagon level (63 pg/ml) caused a marked decline in GP and GNG. In fact, GP fell to a level 29% below the initial control rate and consequently the plasma glucose level fell rapidly. The data suggest that (1) the downregulation of glucagon-stimulated GP is attributable to a decline in glycogenolysis and not gluconeogenesis, and (2) following adaptation to the hormone, the liver becomes dependent on the elevated glucagon concentration for the maintenance of basal glucose production.     

Prostaglandin synthesis inhibitors impair hepatic glucose production in response to glucagon and epinephrine stimulation

To investigate whether inhibition of prostaglandin synthesis affects hormone-induced glucose dynamics, we measured glucose turnover in response to glucagon alone (5 ng . kg-1 min-1) or combined with epinephrine (0.1 microgram . kg-1 min-1) in conscious trained dogs (N = 6) on three separate occasions in each animal: (1) during a control saline infusion, (2) during infusion of indomethacin, and (3) during infusion of sodium salicylate. Glucose production (Ra) and utilization (Rd) were determined by isotope dilution using the nonrecycling label 3-3H glucose. In controls, glucagon levels (IRG) rose from a basal of 44 +/- 12 to 260 +/- 40 pg/ml (mean +/- SEM) during glucagon infusion; basal epinephrine levels (EPI) of 150 +/- 20 pg/ml were unaffected by glucagon infusion but rose four- to fivefold during combined glucagon/epinephrine infusion. Plasma glucose rose transiently from 95 +/- 1 to a peak of 136 +/- 13 mg/dl after 20 min of glucagon; infusion of EPI resulted in a second glycemic response with a peak of 148 +/- 9 mg/dl. Ra increased transiently from 2.9 +/- 0.2 to a peak of 7.9 +/- 1.4 mg . kg-1 min-1 during glucagon alone with a second rise to 6.2 +/- 0.8 mg . kg-1 min-1 10 min after beginning EPI. With glucagon alone, Rd paralleled Ra but addition of EPI resulted in a relative fall in Rd. Insulin (IRI) rose from 9 +/- 1 microU/ml to 29 +/- 6 microU/ml with glucagon but IRI fell despite the second glycemic response during EPI. When either indomethacin or salicylate was infused, basal IRI, IRG, EPI, glucose, Ra and Rd were unaffected and were similar to controls. Although plasma levels of IRG and EPI during glucagon or glucagon plus epinephrine infusion were also similar to controls, the glycemic response was reduced (P less than 0.05). This attenuation of glycemic response was due to a reduction of stimulated Ra (P less than 0.05) and not to an increase in Rd. Changes in IRI paralleled the reduction in glycemic response. Thus, both indomethacin and salicylate blunt the glycemic response to glucagon and glucagon plus epinephrine by attenuating glucose production and not by enhancing glucose utilization or insulin secretion. These results with two prostaglandin synthesis inhibitors suggest that prostaglandins modulate the hepatic effects of glucagon and epinephrine.     

Relationship between decrements in glucose level and metabolic response to hypoglycemia in absence of counterregulatory hormones in the conscious dog.

To determine the relationship between decreases in glucose and metabolic regulation in the absence of counterregulatory hormones, we infused overnight-fasted, conscious, adrenalectomized dogs (lacking cortisol and EPI) with somatostatin (to eliminate glucagon and growth hormone) and intraportal insulin (30 pmol.kg-1.min-1), creating arterial insulin levels of approximately 2000 pM. Glucose was infused during one 120-min period, two 90-min periods, and one 45-min period to establish levels of 5.9 +/- 0.1, 3.4 +/- 0.1, 2.5 +/- 0.1, and 1.7 +/- 0.1 mM, respectively. NE levels were 1.24 +/- 0.23, 1.85 +/- 0.27, 2.04 +/- 0.26, and 2.50 +/- 0.20 nM, respectively. During the euglycemic control period, the liver took up glucose (7.5 +/- 1.9 mumol.kg-1.min-1), but hypoglycemia triggered successively greater rates of net hepatic glucose output (3.0 +/- 0.7, 4.6 +/- 0.9, and 6.9 +/- 1.4 mumol.kg-1.min-1). Total gluconeogenic precursor uptake by the liver increased with hypoglycemia. Intrahepatic gluconeogenic efficiency rose progressively (by 106 +/- 42, 199 +/- 56, and 268 +/- 55%). Both glycerol and NEFA levels rose, indicating lipolysis was enhanced. Net hepatic NEFA uptake and ketone production increased proportionally, but the ketone level rose only with severe hypoglycemia. In conclusion, despite marked hyperinsulinemia and the absence of glucagon, EPI, and cortisol, we observed that lipolysis and glucose and ketone production increase in response to decreases in glucose. This suggests that neural and/or autoregulatory mechanisms can play a role in combating hypoglycemia.     

Inclusion of low amounts of fructose with an intraduodenal glucose load markedly reduces postprandial hyperglycemia and hyperinsulinemia in the conscious dog.

Intraportal infusion of small amounts of fructose markedly augmented net hepatic glucose uptake (NHGU) during hyperglycemic hyperinsulinemia in conscious dogs. In this study, we examined whether the inclusion of catalytic amounts of fructose with a glucose load reduces postprandial hyperglycemia and the pancreatic beta-cell response to a glucose load in conscious 42-h-fasted dogs. Each study consisted of an equilibration (-140 to -40 min), control (-40 to 0 min), and test period (0-240 min). During the latter period, glucose (44.4 micromol x kg(-1) x min(-1)) was continuously given intraduodenally with (2.22 micromol x kg(-1) x min(-1)) or without fructose. The glucose appearance rate in portal vein blood was not significantly different with or without the inclusion of fructose (41.3 +/- 2.7 vs. 37.3 +/- 8.3 micromol x kg(-1) x min(-1), respectively). In response to glucose infusion without the inclusion of fructose, the net hepatic glucose balance switched from output to uptake (from 10 +/- 2 to 11 +/- 4 micromol x kg(-1) x min(-1)) by 30 min and averaged 17 +/- 6 micromol x kg(-1) x min(-1). The fractional extraction of glucose by the liver during the infusion period was 7 +/- 2%. Net glycogen deposition was 2.44 mmol glucose equivalent/kg body wt; 49% of deposited glycogen was synthesized via the direct pathway. Net hepatic lactate production was 1.4 mmol/kg body wt. Arterial blood glucose rose from 4.1 +/- 0.2 to 7.3 +/- 0.4 mmol/l, and arterial plasma insulin rose from 42 +/- 6 to 258 +/- 66 pmol/l at 30 min, after which they decreased to 7.0 +/- 0.5 mmol/l and 198 +/- 66 pmol/l, respectively. Arterial plasma glucagon decreased from 54 +/- 7 to 32 +/- 3 ng/l. In response to intraduodenal glucose infusion in the presence of fructose, net hepatic glucose balance switched from 9 +/- 1 micromol x kg(-1) x min(-1) output to 12 +/- 3 and 28 +/- 5 micromol x kg(-1) x min(-1) uptake by 15 and 30 min, respectively. The average NHGU (28 +/- 5 micromol x kg(-1) x min(-1)) and fractional extraction during infusion period (12 +/- 2%), net glycogen deposition (3.68 mmol glucose equivalent/kg body wt), net hepatic lactate production (3.27 mmol/kg), and glycogen synthesis via the direct pathway (68%) were significantly higher (P < 0.05) compared to that in the absence of fructose. The increases in arterial blood glucose (from 4.4 +/- 0.1 to 6.4 +/- 0.2 mmol/l at 30 min) and arterial plasma insulin (from 48 +/- 6 to 126 +/- 30 pmol/l at 30 min) were significantly smaller (P < 0.05). In summary, the inclusion of small amounts of fructose with a glucose load augmented NHGU, increased hepatic glycogen synthesis via the direct pathway, and augmented hepatic glycolysis. As a result, postprandial hyperglycemia and insulin release by the pancreatic beta-cell were reduced. In conclusion, catalytic amounts of fructose have the ability to improve glucose tolerance.     

Insulin sensitively controls the glucagon response to mild hypoglycemia in the dog

In the present study, we examined how the arterial insulin level alters the alpha-cell response to a fall in plasma glucose in the conscious overnight fasted dog. Each study consisted of an equilibration (-140 to -40 min), a control (-40 to 0 min), and a test period (0 to 180 min), during which BAY R 3401 (10 mg/kg), a glycogen phosphorylase inhibitor, was administered orally to decrease glucose output in each of four groups (n = 5). In group 1, saline was infused. In group 2, insulin was infused peripherally (3.6 pmol. kg(- 1). min(-1)), and the arterial plasma glucose level was clamped to the level seen in group 1. In group 3, saline was infused, and euglycemia was maintained. In group 4, insulin (3.6 pmol. kg(-1). min(-1)) was given, and euglycemia was maintained by glucose infusion. In group 1, drug administration decreased the arterial plasma glucose level (mmol/l) from 5.8 +/- 0.2 (basal) to 5.2 +/- 0.3 and 4.4 +/- 0.3 by 30 and 90 min, respectively (P < 0.01). Arterial plasma insulin levels (pmol/l) and the hepatic portal-arterial difference in plasma insulin (pmol/l) decreased (P < 0.01) from 78 +/- 18 and 90 +/- 24 to 24 +/- 6 and 12 +/- 6 over the first 30 min of the test period. The arterial glucagon levels (ng/l) and the hepatic portal-arterial difference in plasma glucagon (ng/l) rose from 43 +/- 5 and 5 +/- 2 to 51 +/- 5 and 10 +/- 5 by 30 min (P < 0.05) and to 79 +/- 16 and 31 +/- 15 (P < 0.05) by 90 min, respectively. In group 2, in response to insulin infusion, arterial insulin (pmol/l) was elevated from 48 +/- 6 to 132 +/- 6 to an average of 156 +/- 6. The hepatic portal-arterial difference in plasma insulin was eliminated, indicating a complete inhibition of endogenous insulin release. The arterial glucagon level (ng/l) and the hepatic portal-arterial difference in plasma glucagon (ng/l) did not rise significantly (40 +/- 5 and 7 +/- 4 at basal, 44 +/- 4 and 9 +/- 4 at 90 min, and 44 +/- 8 and 15 +/- 7 at 180 min). In group 3, when euglycemia was maintained, the insulin and glucagon levels and the hepatic portal-arterial difference remained constant. In group 4, the arterial plasma glucose level remained basal (5.9 +/- 1.1 mmol/l) throughout, whereas insulin infusion increased the arterial insulin level to an average of 138 +/- 6 pmol/l. The hepatic portal-arterial difference in plasma insulin was again eliminated. Arterial glucagon level (ng/l) and the hepatic portal-arterial difference in plasma glucagon (ng/l) did not change significantly (43 +/- 2 and 9 +/- 2 at basal, 39 +/- 3 and 9 +/- 2 at 90 min, and 37 +/- 3 and 7 +/- 2 at 180 min). Thus, a difference of approximately 120 pmol/l in arterial insulin completely abolished the response of the alpha-cell to mild hypoglycemia.     

Relationship of hepatic glucose uptake to intrahepatic glucose concentration in fasted rats after glucose load

Glucose concentration gradients across the liver and hepatic blood flow were measured to characterize the relationship of hepatic glucose uptake to hepatic glucose concentration for 240 min after administration of a large oral glucose load to fasted rats. Extraction of glucose occurred only transiently, from 20 to 80 min after glucose administration. The liver changed from net glucose output to net glucose removal only when the intracellular hepatic glucose concentration exceeded 12.5 mumol/ml water. Even when arteriovenous glucose concentrations gradients were compatible with net direct hepatic uptake of glucose, the hepatic glucose concentration always exceeded the inflow glucose concentration. These data indicate that direct glucose uptake occurred against a concentration gradient when the liver is considered as a whole. The hepatic intracellular-to-extracellular glucose concentration gradient changed very little, suggesting that this is not being regulated by glucose, insulin, or other effectors. The mechanism by which the hepatic glucose concentration and net hepatic glucose uptake versus output are coordinated is unknown. The rate of glycogen synthesis was linear for 120 min after administration of the glucose load. This occurred in the presence of direct uptake of glucose early in the time course and later in the presence of net glucose output by the liver. Net direct uptake of glucose by the liver could account for, at most, 37-55% of the glycogen formed. Fractional extraction of both lactate and alanine decreased after glucose was given, but net hepatic uptake of these metabolites could account for 33-49 and 7-10%, respectively, of the glycogen formed, depending on plasma versus blood water flow.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of glucose on the glucagon response to L-dopa in normal and diabetic subjects

The effect of an oral dose of 1 gm. L-dopa either without or after a concomitant oral administration of 100 gm. glucose on the plasma level of pancreatic glucagon, plasma immunoreactive insulin (IRI), and plasma growth hormone (GH) was assessed in eight normal and 10 insulin-treated diabetic subjects. In the normal group the stimulatory effect o L-dopa on pancreatic glucagon release was reconfirmed. Moreover, in the diabetics essentially the same plasma glucagon increase after drug administration was found, such a response being inhibited in both groups by glucose. The increase of plasma GH after L-dopa in both healthy persons and diabetics and the inhibition of this response by glucose in healthy subjects was reconfirmed. Furthermore, the same effect of exogenous glucose on the L-dopa induced GH release was observed in diabetics. It may be concluded that glucagon may play a pathogenetic role in the worsening of parkinsonian diabetic patients during the treatment with L-dopa and that diabetic hyperglycemia per se seems to be insufficient for an inhibition of the release of both glucagon and GH AFTer L-dopa.     

The greater contribution of gluconeogenesis to glucose production in obesity is related to increased whole-body protein catabolism

Obesity is associated with an increase in the fractional contribution of gluconeogenesis (GNG) to glucose production. We tested if this was related to the altered protein metabolism in obesity. GNG(PEP) (via phosphoenol pyruvate [PEP]) was measured after a 17-h fast using the deuterated water method and 2H nuclear magnetic resonance spectroscopy of plasma glucose. Whole-body 13C-leucine and 3H-glucose kinetics were measured in the postabsorptive state and during a hyperinsulinemic-euglycemic-isoaminoacidemic clamp in 19 (10 men and 9 women) lean and 16 (7 men and 9 women) obese nondiabetic subjects. Endogenous glucose production was not different between groups. Postabsorptive %GNG(PEP) and GNG(PEP) flux were higher in obese subjects, and glycogenolysis contributed less to glucose production than in lean subjects. GNG(PEP) flux correlated with all indexes of adiposity and with postabsorptive leucine rate of appearance (Ra) (protein catabolism). GNG(PEP) was negatively related to the clamp glucose rate of disposal (Rd) and to the protein anabolic response to hyperinsulinemia. In conclusion, the increased contribution of GNG to glucose production in obesity is linked to increased postabsorptive protein catabolism and insulin resistance of both glucose and protein metabolism. Due to increased protein turnover rates, greater supply of gluconeogenic amino acids to the liver may trigger their preferential use over glycogen for glucose production.     

Relative importance of first- and second-phase insulin secretion in glucose homeostasis in conscious dog. II. Effects on gluconeogenesis

The normal pancreatic response to an exogenous glucagon infusion is a biphasic release of insulin. In our study the ability of each component of insulin release to counter the effects of the glucagon on gluconeogenesis and alanine metabolism was assessed by mimicking first- and/or second-phase insulin release with infusions of somatostatin and intraportal insulin. When a fourfold increase in glucagon was brought about in the presence of fixed basal insulin release, there was a large increase in overall glucose production and gluconeogenesis. The increase in the conversion of [14C]alanine into [14C]glucose (169 +/- 42%, P less than .05) was accompanied by an increase in the fractional extraction of alanine by the liver (FEA 0.32 +/- 0.06 to 0.66 +/- 0.10, P less than .05) and net hepatic alanine uptake (NHAU 2.97 +/- 0.45 to 4.61 +/- 0.48 mumol . kg-1 . min-1, P less than .05). Simulated first-phase insulin release had no effect on the ability of glucagon to increase FEA (0.32 +/- 0.03 to 0.66 +/- 0.03, P less than .05) or NHAU (3.69 +/- 0.80 to 5.10 +/- 0.69 mumol . kg-1 . min-1, P less than .05) but did limit the increase in overall gluconeogenic conversion (114 +/- 37%). Second-phase insulin release had no effect on either the glucagon-induced increase in FEA (0.35 +/- 0.08 to 0.73 +/- 0.04) or NHAU (3.35 +/- 0.92 to 5.13 +/- 0.85 mumol . kg-1 . min-1) but completely inhibited the increase in overall gluconeogenic conversion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the relation between late dumping syndrome and glucagon responses to glucose

This study was planned in pursuit of the relation between glucagon responses to glucose and the late dumping syndrome. Clinically, 75 g oral glucose tolerance test to seven late dumpers, ten gastrectomized patients and ten normal subjects were performed. And experimentary, 20 ml 25% glucose was put into small intestinal blind loops prepared in dogs, which were made the jejunum region and then the ileum region. 1. The mean oral glucose tolerance curve in gastrectomized patients was oxyhyperglycemic, and this tendency was seen in late dumpers. But, for only late dumpers, the low blood glucose concentration which was under 50 mg/dl appeared within one and half to three hours after oral glucose load. 2. The change of serum IRI in gastrectomized patients displayed the initial hyperinsulinemia, that was similar in late dumpers. 3. Pancreatic glucagon (GI) levels were within normal limits in normal subjects and late dumpers, but were significantly increased in gastrectomized patients. 4. Enteroglucagon (gutGLI) levels were not so increased in normal subjects, but were significantly increased in gastrectomized patients and late dumpers as well. 5. GutGLI levels were increased only by putting into the ileum loop. But hypersecretion of gutGLI did not affect the blood glucose curve and the change of serum IRI significantly. These results described above suggest that the pathogenesis of the hypoglycemia in the late dumping syndrome may be responsible for no hypersecretion of GI, for some reason, to prevent hypoglycemia against hyperinsulinemia with oxyhyperglycemia, and that gutGLI may not play so important part in the regulation of the blood glucose level.     

Small increases in insulin inhibit hepatic glucose production solely caused by an effect on glycogen metabolism

Based on our earlier work, a 2.5-fold increase in insulin secretion should completely inhibit hepatic glucose production through the hormone's direct effect on hepatic glycogen metabolism. The aim of the present study was to test the accuracy of this prediction and to confirm that gluconeogenic flux, as measured by three independent techniques, was unaffected by the increase in insulin. A 40-min basal period was followed by a 180-min experimental period in which an increase in insulin was induced, with euglycemia maintained by peripheral glucose infusion. Arterial and hepatic sinusoidal insulin levels increased from 10 +/- 2 to 19 +/- 3 and 20 +/- 4 to 45 +/- 5 microU/ml, respectively. Net hepatic glucose output decreased rapidly from 1.90 +/- 0.13 to 0.23 +/- 0.16 mg. kg(-1). min(-1). Three methods of measuring gluconeogenesis and glycogenolysis were used: 1) the hepatic arteriovenous difference technique (n = 8), 2) the [(14)C]phosphoenolpyruvate technique (n = 4), and 3) the (2)H(2)O technique (n = 4). The net hepatic glycogenolytic rate decreased from 1.72 +/- 0.20 to -0.28 +/- 0.15 mg. kg(-1). min(-1) (P < 0.05), whereas none of the above methods showed a significant change in hepatic gluconeogenic flux (rate of conversion of phosphoenolpyruvate to glucose-6-phosphate). These results indicate that liver glycogenolysis is acutely sensitive to small changes in plasma insulin, whereas gluconeogenic flux is not.     

Inhibition of dipeptidyl peptidase-4 by vildagliptin during glucagon-like Peptide 1 infusion increases liver glucose uptake in the conscious dog

OBJECTIVE—This study investigated the acute effects of treatment with vildagliptin on dipeptidyl peptidase-4 (DPP-4) activity, glucagon-like peptide 1 (GLP-1) concentration, pancreatic hormone levels, and glucose metabolism. The primary aims were to determine the effects of DPP-4 inhibition on GLP-1 clearance and on hepatic glucose uptake.RESEARCH DESIGN AND METHODS—Fasted conscious dogs were studied in the presence (n = 6) or absence (control, n = 6) of oral vildagliptin (1 mg/kg). In both groups, GLP-1 was infused into the portal vein (1 pmol · kg⁻¹ · min⁻¹) for 240 min. During the same time, glucose was delivered into the portal vein at 4 mg · kg⁻¹ · min⁻¹ and into a peripheral vein at a variable rate to maintain the arterial plasma glucose level at 160 mg/dl.RESULTS—Vildagliptin fully inhibited DPP-4 over the 4-h experimental period. GLP-1 concentrations were increased in the vildagliptin-treated group (50 ± 3 vs. 85 ± 7 pmol/l in the portal vein in control and vildagliptin-treated dogs, respectively; P < 0.05) as a result of a 40% decrease in GLP-1 clearance (38 ± 5 and 22 ± 2 ml · kg⁻¹ · min⁻¹, respectively; P < 0.05). Although hepatic insulin and glucagon levels were not significantly altered, there was a tendency for plasma insulin to be greater (hepatic levels were 73 ± 10 vs. 88 ± 15 μU/ml, respectively). During vildagliptin treatment, net hepatic glucose uptake was threefold greater than in the control group. This effect was greater than that predicted by the change in insulin.CONCLUSIONS—Vildagliptin fully inhibited DPP-4 activity, reduced GLP-1 clearance by 40%, and increased hepatic glucose disposal by means beyond the effects of GLP-1 on insulin and glucagon secretion.Glucagon-like peptide 1 (GLP-1) is a gut-derived hormone shown to enhance glucose-dependent insulin secretion, suppress inappropriately high glucagon secretion, slow gastric emptying, and reduce food intake (1). In some type 2 diabetic patients, GLP-1 levels are reduced, and elevation of GLP-1 by continuous infusion of the peptide leads to reductions in fasting glucose, postprandial glucose excursions, and A1C (2). The therapeutic potential of GLP-1 is limited, however, because it is rapidly inactivated by dipeptidyl peptidase-4 (DPP-4) (3,4).Vildagliptin is an orally effective selective DPP-4 inhibitor. In diabetic patients, vildagliptin improved glycemic control, increased the plasma insulin–to–glucagon molar ratio, and reduced A1C levels (5,6). During a meal tolerance test, it augmented insulin secretion and decreased glucagon release, resulting in enhanced suppression of endogenous glucose production compared with placebo (7).Ingested glucose and endogenously secreted GLP-1 are released from the gut into the hepatic portal vein, which then perfuses the liver. Typically, studies have investigated the effects of DPP-4 inhibition after a meal, when GLP-1 secretion is increased. In the present study, GLP-1 and glucose were infused directly into the hepatic portal vein in the presence or absence of DPP-4 inhibition. The first aim was to examine the effect of vildagliptin on GLP-1 clearance under these carefully controlled conditions. In addition, although GLP-1 can increase glucose disposal by stimulation of insulin secretion, the hormone has been suggested to affect glucose metabolism by actions over and above its effects on the pancreas. Therefore, the second aim of this study was to investigate the effect of DPP-4 inhibition on glucose disposal, in particular by the liver.     

Effect of diuresis and glucagon on upper urinary tract dynamics in the dog

The effect of glucagon on upper urinary tract peristalsis during extreme diuresis was studied in an unsedated dog preparation. In all experiments glucagon inhibited the peristaltic contraction waves without affecting urine propulsion, suggesting that peristalsis, at least for short periods, is not necessary for effective urine transport during extreme diuresis.