Effect of prior exercise on the partitioning of an intestinal glucose load between splanchnic bed and skeletal muscle.

Exercise leads to marked increases in muscle insulin sensitivity and glucose effectiveness. Oral glucose tolerance immediately after exercise is generally not improved. The hypothesis tested by these experiments is that after exercise the increased muscle glucose uptake during an intestinal glucose load is counterbalanced by an increase in the efficiency with which glucose enters the circulation and that this occurs due to an increase in intestinal glucose absorption or decrease in hepatic glucose disposal. For this purpose, sampling (artery and portal, hepatic, and femoral veins) and infusion (vena cava, duodenum) catheters and Doppler flow probes (portal vein, hepatic artery, external iliac artery) were implanted 17 d before study. Overnightfasted dogs were studied after 150 min of moderate treadmill exercise or an equal duration rest period. Glucose ([14C]glucose labeled) was infused in the duodenum at 8 mg/kg x min for 150 min beginning 30 min after exercise or rest periods. Values, depending on the specific variable, are the mean +/- SE for six to eight dogs. Measurements are from the last 60 min of the intraduodenal glucose infusion. In response to intraduodenal glucose, arterial plasma glucose rose more in exercised (103 +/- 4 to 154 +/- 6 mg/dl) compared with rested (104 +/- 2 to 139 +/- 3 mg/dl) dogs. The greater increase in glucose occurred even though net limb glucose uptake was elevated after exercise (35 +/- 5 vs. 20 +/- 2 mg/min) as net splanchnic glucose output (5.1 +/- 0.8 vs. 2.1 +/- 0.6 mg/kg x min) and systemic appearance of intraduodenal glucose (8.1 +/- 0.6 vs. 6.3 +/- 0.7 mg/kg x min) were also increased due to a higher net gut glucose output (6.1 +/- 0.7 vs. 3.6 +/- 0.9 mg/kg x min). Adaptations at the muscle led to increased net glycogen deposition after exercise [1.4 +/- 0.3 vs. 0.5 +/- 0.1 mg/(gram of tissue x 150 min)], while no such increase in glycogen storage was seen in liver [3.9 +/- 1.0 vs. 4.1 +/- 1.1 mg/(gram of tissue x 150 min) in exercised and sedentary animals, respectively]. These experiments show that the increase in the ability of previously working muscle to store glycogen is not solely a result of changes at the muscle itself, but is also a result of changes in the splanchnic bed that increase the efficiency with which oral glucose is made available in the systemic circulation.

Effects of morphine on glucose homeostasis in the conscious dog.

This study was designed to assess the effects of morphine sulfate on glucose kinetics and on glucoregulatory hormones in conscious overnight fasted dogs. One group of experiments established a dose-response range. We studied the mechanisms of morphine-induced hyperglycemia in a second group. We also examined the effect of low dose morphine on glucose kinetics independent of changes in the endocrine pancreas by the use of somatostatin plus intraportal replacement of basal insulin and glucagon. In the dose-response group, morphine at 2 mg/h did not change plasma glucose, while morphine at 8 and 16 mg/h caused a hyperglycemic response. In the second group of experiments, morphine (16 mg/h) caused an increase in plasma glucose from a basal 99 +/- 3 to 154 +/- 13 mg/dl (P less than 0.05). Glucose production peaked at 3.9 +/- 0.7 vs. 2.5 +/- 0.2 mg/kg per min basally, while glucose clearance declined to 1.7 +/- 0.2 from 2.5 +/- 0.1 ml/kg per min (both P less than 0.05). Morphine increased epinephrine (1400 +/- 300 vs. 62 +/- 8 pg/ml), norepinephrine (335 +/- 66 vs. 113 +/- 10 pg/ml), glucagon (242 +/- 53 vs. 74 +/- 14 pg/ml), insulin (30 +/- 9 vs. 10 +/- 2 microU/ml), cortisol (11.1 +/- 3.3 vs. 0.9 +/- 0.2 micrograms/dl), and plasma beta-endorphin (88 +/- 27 vs. 23 +/- 6 pg/ml); all values P less than 0.05 compared with basal. These results show that morphine-induced hyperglycemia results from both stimulation of glucose production as well as inhibition of glucose clearance. These changes can be explained by rises in epinephrine, glucagon, and cortisol. These in turn are part of a widespread catabolic response initiated by high dose morphine that involves activation of the sympathetic nervous system, the endocrine pancreas, and the pituitary-adrenal axis. Also, we report the effect of a 2 mg/h infusion of morphine on glucose kinetics when the endocrine pancreas is clamped at basal levels. Under these conditions, morphine exerts a hypoglycemic effect (25% fall in plasma glucose, P less than 0.05) that is due to inhibition of glucose production (by 25-43%, P less than 0.05). The hypoglycemia was independent of detectable changes in insulin, glucagon, epinephrine and cortisol, and was not reversed by concurrent infusion of a slight molar excess of naloxone. Therefore, we postulate that the hypoglycemic effect of morphine results from the interaction of the opiate with non-mu receptors either in the liver or the central nervous system.

Unraveling the structures and modes of action of bacterial toxins.

The mechanism by which a soluble protein converts into a protein that spans a membrane remains a central question in understanding the molecular mechanism of toxicity of bacterial protein toxins. Using crystallographic structures of soluble toxins as templates, the past year has seen a number of experiments that are designed to probe the membrane state using other structural methods. In addition, crystallographic information concerning the clostridial neurotoxins has emerged, suggesting a novel mechanism of pore formation and new relationships between toxin binding domains.

Impact of insulin deficiency on glucose fluxes and muscle glucose metabolism during exercise.

Exercise in the insulin-deficient diabetic state is characterized by a further increase in elevated circulating glucose and NEFA levels and by excessive counterregulatory hormone levels. The aim of this study was to distinguish the direct glucoregulatory effects of insulinopenia during exercise from the indirect effects that result from the metabolic and hormonal environment that accompanies insulin deficiency. For this purpose, dogs underwent 90 min of treadmill exercise during SRIF infusion with (SRIF + INS, n = 8) or without (SRIF - INS, n = 6) intraportal insulin replacement. Glucagon was not replaced, thus allowing assessment of the direct effect of insulinopenia at the liver independent of the potentiation of glucagon action. Glucose was infused to maintain euglycemia. Hepatic glucose production (Ra); glucose utilization (Rd); and LGlcU, LGlcE, and LGlcO were assessed with tracers ([3H]glucose, [14C]glucose) and arteriovenous differences. With exercise, insulin fell from 66 +/- 6 to 42 +/- 6 pM in the SRIF + INS group, and was undetectable in the SRIF - INS group. Plasma glucose was 6.33 +/- 0.38 and 6.26 +/- 0.30 mM at rest in the SRIF + INS and SRIF - INS groups, respectively, and was unchanged with exercise. Ra rose from 7.5 +/- 2.3 to 16.5 +/- 2.2 mumol.kg-1.min-1 and 9.1 +/- 2.0 to 31.4 +/- 3.9 mumol.kg-1.min-1 with exercise in the SRIF + INS and SRIF - INS groups, whereas Rd rose from 19.5 +/- 2.0 to 46.8 +/- 3.9 mumol.kg-1.min-1 and 15.1 +/- 1.8 to 29.9 +/- 3.3 mumol.kg-1.min-1. LGlcU rose from 36 +/- 9 to 112 +/- 25 mumol/min and 15 +/- 4 to 59 +/- 13 mumol/min and LGlcO rose from 5 +/- 2 to 61 +/- 12 mumol/min and 5 +/- 3 to 32 +/- 9 mumol/min with exercise in the SRIF+INS and SRIF-INS groups, respectively. Arterial levels and limb balances of NEFAs and glycerol were similar in the two groups. In summary, during exercise: 1) marked insulinopenia attenuates the increases in muscle glucose uptake and oxidation by approximately 50%, independent of changes in circulating metabolic substrate levels; 2) substantial increases in muscle glucose uptake and oxidation are, however, still present even in the absence of detectable insulin levels; and 3) insulinopenia facilitates the increase in Ra, independent of the potentiation of basal glucagon action. In conclusion, marked insulinopenia contributes directly to the exacerbation of glucoregulation during exercise in the diabetic state by limiting the rises in glucose uptake and metabolism and by enhancing hepatic glucose production.

Exercise-induced fall in insulin and increase in fat metabolism during prolonged muscular work.

The role of the exercise-induced fall in insulin in fat metabolism was studied in dogs during 150 min of treadmill exercise alone (controls) or with insulin clamped at basal levels by an intraportal infusion to prevent the normal fall in insulin concentration (ICs). To counteract the suppressive effect of insulin on glucagon release, glucagon was supplemented by an intraportal infusion in ICs. In all dogs, catheters were placed in a carotid artery and in the portal and hepatic veins for sampling and in the vena cava and the splenic vein for infusion purposes. Glucose levels were clamped in ICs to recreate the glycemic response evident in controls. In controls, insulin fell by 7 +/- 1 microU/ml but was unchanged from basal levels in ICs (0 +/- 2 microU/ml). Glucagon, norepinephrine, epinephrine, and cortisol rose similarly in controls and ICs. Arterial free-fatty acid (FFA) levels rose by 644 +/- 126 mu eq/L in controls but did not increase in ICs (-12 +/- 148 mu eq/L). Arterial glycerol levels rose by 337 +/- 43 and 183 +/- 19 microM in controls and ICs. Hepatic FFA delivery and fractional extraction increased by 17 +/- 3 and 0.06 +/- 0.02 mumol.kg-1.min-1, respectively, in controls. In ICs, hepatic FFA delivery increased by only 1 +/- 2 mumol.kg-1.min-1, whereas hepatic fractional extraction fell slightly (-0.03 +/- 0.03). Consequently, net hepatic FFA uptake rose by 4.8 +/- 1.5 mumol.kg-1.min-1 in controls but decreased slightly in ICs (-0.5 +/- 1.1 mumol.kg-1.min-1).(ABSTRACT TRUNCATED AT 250 WORDS)

Exercise-induced rise in glucagon and ketogenesis during prolonged muscular work.

These experiments examined the role of the exercise-induced increment in glucagon in the control of ketogenesis during prolonged moderate-intensity (100 m/min, 12% grade) treadmill exercise. Dogs were studied during 150 min of exercise with saline infusion alone (C; n = 6) with the glucagon levels clamped at basal values (somatostatin infusion with basal glucagon replacement and the normal fall in insulin simulated; BG; n = 5) or with the normal exercise-induced rise in glucagon simulated (somatostatin infusion with the rise in glucagon and the fall in insulin simulated; SG; n = 5). Glucose was infused as needed in SG and BG to maintain the glycemic response seen in C. In all dogs, catheters were inserted into the carotid artery and the portal and hepatic veins for blood sampling and the vena cava and the splenic vein for infusions. Glucagon rose from 62 +/- 5 and 57 +/- 4 pg/ml at rest to 104 +/- 20 and 120 +/- 12 pg/ml during exercise in C and SG but did not deviate from basal in BG (56 +/- 3 pg/ml). Insulin fell similarly from rest to the end of exercise in C (13 +/- 2 to 5 +/- 1 microU/ml), SG (11 +/- 1 to 6 +/- 1 microU/ml), and BG (10 +/- 1 to 6 +/- 1 microU/ml). In C, SG, and BG, free-fatty acid (FFA) levels rose from 941 +/- 81, 1240 +/- 155, and 938 +/- 36 mu eq/L at rest to 1615 +/- 149, 1558 +/- 175, and 1391 +/- 160 mu eq/L with exercise.2+n C,

Effects of an acute increase in epinephrine and cortisol on carbohydrate metabolism during insulin deficiency.

This study was undertaken to investigate the effects of an acute increase in the plasma epinephrine level, with or without an accompanying increase in the plasma cortisol level, during selective insulin deficiency on glycogenolysis and gluconeogenesis in conscious overnight-fasted dogs. Experiments consisted of an 80-min tracer and dye equilibration period, a 40-min basal period, and a 180-min experimental period. In all protocols, selective insulin deficiency was created during the experimental period by infusing somatostatin peripherally (0.8 micrograms.kg-1.min-1) with basal replacement of glucagon intraportally (0.65 ng.kg-1.min-1). In EPI+SAL (n = 6), an additional infusion of epinephrine (0.04 micrograms.kg-1.min-1) was infused during the experimental period along with saline. In EPI+CORT (n = 6), hydrocortisone (3.0 microgram.kg-1.min-1) was infused in addition to epinephrine during the experimental period. In SAL+CORT (n = 5), hydrocortisone was infused during the experimental period. In SALINE (n = 5), neither epinephrine nor cortisol was infused. [3-3H]glucose, [U-14C]alanine, and indocyanine green dye were used to assess glucose production (rate of appearance [Ra]) and gluconeogenesis using tracer and arteriovenous difference techniques. During selective insulin deficiency in SALINE, the arterial plasma glucose level increased from 6.0 +/- 0.1 to 15.8 +/- 1.1 mmol/l; Ra increased from 14.7 +/- 0.7 to 24.9 +/- 1.7 mumol.kg-1.min-1. Gluconeogenic efficiency and the conversion of alanine and lactate to glucose increased to 300 +/- 55 and 355 +/- 67% of basal. In EPI+SAL and EPI+CORT, plasma glucose increased from 6.2 +/- 0.1 to 19.8 +/- 0.9 mmol/l and from 6.3 +/- 0.1 to 19.5 +/- 0.9 mmol/l. In EPI+SAL and EPI+CORT, Ra increased from 16.5 +/- 1.1 to 29.3 +/- 3.2 mumol.kg-1.min-1 and from 15.4 +/- 1.3 to 28.3 +/- 2.5 mumol.kg-1.min-1. The rise in gluconeogenic efficiency was similar to the rise that occurred in SALINE, but gluconeogenic conversion increased 17-fold in each of the two epinephrine groups. During the epinephrine infusion, gluconeogenesis accounted for a maximum of 55% of total glucose production as opposed to 31% during insulin deficiency alone. An increase in cortisol alone during insulin deficiency (SAL+CORT) had no effect on glucose level, glucose production, or gluconeogenesis. These results suggest that small increases in the plasma epinephrine level during insulin deficiency can significantly worsen the resulting hyperglycemia through stimulation of both glycogenolysis and gluconeogenesis.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of glucose uptake and metabolism by working muscle. An in vivo analysis.

To assess the mechanisms whereby muscular work stimulates glucose uptake and metabolism in vivo, dogs were studied during rest (-40-0 min), moderate exercise (0-90 min), and exercise recovery (90-180 min) with plasma glucose clamped at 5.0, 6.7, 8.3, and 10.0 mM (n = 5 at 5.0 mM and n = 4 at all other levels) using a variable glucose infusion. Basal insulin was maintained with somatostatin and insulin replacement. Whole-body glucose uptake, limb glucose uptake, and oxidative and nonoxidative glucose plus lactate metabolism, were assessed with tracers ([3H]glucose and [14C]glucose) and arteriovenous differences. The combined effects of glucose and exercise on the increment above resting values for limb glucose uptake, arteriovenous glucose difference, LGO, LGNO, and rate of glucose disappearance were synergistic (approximately 112, 90, 125, 76, and 90% greater than the additive values, respectively). Neither exercise nor recovery affected the Km for limb glucose uptake (4.7 +/- 1.1, 4.8 +/- 0.4, and 5.2 +/- 0.3 mM during rest, exercise, and recovery, respectively), but both conditions increased the Vmax (44 +/- 16, 217 +/- 30, and 118 +/- 14 mumol/min during rest, exercise, and recovery, respectively). Similarly, the Km for arteriovenous glucose differences were unaffected by exercise recovery (4.9 +/- 0.6, 5.0 +/- 0.4, and 5.3 +/- 0.3 mM during rest, exercise, and recovery, respectively), but the maximum rose (272 +/- 50, 650 +/- 78, and 822 +/- 111 microM during rest, exercise, and recovery, respectively). The LGO was unchanged by glycemia at rest (15 +/- 4 mumol/min at 10.0 mM). The Km for LGO during exercise was 5.1 +/- 0.3 mM, and the Vmax was 163 +/- 15. The capacity for LGO returned to basal during recovery. LGNO increased gradually with increasing glycemia during rest, exercise, and recovery and did not approach saturation (38 +/- 13, 105 +/- 36, and 132 +/- 45 mumol/min during rest, exercise, and recovery, respectively, at 10.0 mM). In general, the LGNO was elevated at every glucose level during exercise (approximately twofold) and recovery (approximately threefold) compared with rest. Arterial free fatty acid and glycerol levels decreased with increasing glycemia within all periods. Free fatty acids were suppressed by a greater amount during exercise compared with rest and recovery.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence that carotid bodies play an important role in glucoregulation in vivo.

The carotid bodies are sensitive to glucose in vitro and can be stimulated to cause hyperglycemia in vivo. The aim of this study was to determine if the carotid bodies are involved in basal glucoregulation or the counterregulatory response to an insulin-induced decrement in arterial glucose in vivo. Dogs were surgically prepared >16 days before the experiment. The carotid bodies and their associated nerves were removed (carotid body resected [CBR]) or left intact (Sham), and infusion and sampling catheters were implanted. Removal of carotid bodies was verified by the absence of a ventilatory response to NaCN. Experiments were performed in 18-h fasted conscious dogs and consisted of a tracer ([3-3H]glucose) equilibration period (-120 to -40 min), a basal period (-40 to 0 min), and an insulin infusion (1 mU x kg(-1) x min(-1)) period (0-150 min) during which glucose was infused as needed to clamp at mildly hypoglycemic (65 mg/dl) or euglycemic (105 mg/dl) levels. Basal (8 microU/ml) and clamp (40 microU/ml) insulin levels were similar in both groups. Basal arterial glucagon was reduced in CBR compared with Sham (30 + 2 vs. 40 +/- 2 pg/ml) and remained reduced in CBR during hypoglycemia (peak levels of 36 +/- 3 vs. 52 +/- 7 pg/ml). Cortisol levels were not significantly different between the 2 groups in the basal state, but were reduced during the hypoglycemic clamp in CBR. Catecholamine levels were not significantly different between the 2 groups in the basal and hypoglycemic periods. The glucose infusion rate required to clamp glucose at 65 mg/dl was 2.5-fold greater in CBR compared with Sham (4.0 +/- 0.4 vs. 1.6 +/- 0.4 mg x kg(-1) x min(-1)). Basal endogenous glucose appearance (R(a)) was equal in CBR and Sham (2.5 +/- 0.1 vs. 2.5 +/- 0.2 mg x kg(-1) x min(-1)). During the hypoglycemic clamp, insulin suppressed R(a) in CBR but not Sham (1.1 +/- 0.2 vs. 2.5 +/- 0.2 mg x kg(-1) x min(-1) during the last 30 min of the clamp), reflecting impaired counterregulation. Glucose disappearance (R(d)) in the basal state was similar in CBR and Sham, whereas it was elevated in CBR during the hypoglycemic clamp (4.8 +/- 0.1 vs. 3.9 +/- 0.1 mg x kg(-1) x min(-1) during the last 30 min of the clamp). R(d) was also elevated in euglycemic clamp studies, indicating an effect of carotid body resection independent of hypoglycemia. There were no other measured systematic endocrine or metabolic effects of carotid body resection during euglycemic clamps. In conclusion, we found that the carotid bodies (or receptors anatomically close by) play an important role in the insulin-induced counterregulatory response to mild hypoglycemia.

Role of gluconeogenesis in sustaining glucose production during hypoglycemia caused by continuous insulin infusion in conscious dogs.

The roles of glycogenolysis and gluconeogenesis in sustaining glucose production during insulin-induced hypoglycemia were assessed in overnight-fasted conscious dogs. Insulin was infused intraportally for 3 h at 5 mU.kg-1.min-1 in five animals, and glycogenolysis and gluconeogenesis were measured by using a combination of tracer [( 3-3H]glucose and [U-14C]alanine) and hepatic arteriovenous difference techniques. In response to the elevated insulin level (263 +/- 39 microU/ml), plasma glucose level fell (41 +/- 3 mg/dl), and levels of the counterregulatory hormones glucagon, epinephrine, norepinephrine, and cortisol increased (91 +/- 29 to 271 +/- 55 pg/ml, 83 +/- 26 to 2356 +/- 632 pg/ml, 128 +/- 31 to 596 +/- 81 pg/ml, and 1.5 +/- 0.4 to 11.1 +/- 1.0 micrograms/dl, respectively; for all, P less than .05). Glucose production fell initially and then doubled (3.1 +/- 0.3 to 6.1 +/- 0.5 mg.kg-1.min-1; P less than .05) by 60 min. Net hepatic gluconeogenic precursor uptake increased approximately eightfold by the end of the hypoglycemic period. By the same time, the efficiency with which the liver converted the gluconeogenic precursors to glucose rose twofold. Five control experiments in which euglycemia was maintained by glucose infusion during insulin administration (5.0 mU.kg-1.min-1) provided baseline data. Glycogenolysis accounted for 69-88% of glucose production during the 1st h of hypoglycemia, whereas gluconeogenesis accounted for 48-88% of glucose production during the 3rd h of hypoglycemia. These data suggest that gluconeogenesis is the key process for the normal counterregulatory response to prolonged and marked hypoglycemia.

Stimulation of glucose production through hormone secretion and other mechanisms during insulin-induced hypoglycemia.

To assess the role of counterregulatory hormones per se in the response to continuous insulin infusion, overnight-fasted dogs were given 5 mU.kg-1.min-1 insulin intraportally either alone (INS, n = 5), with glucose to maintain euglycemia (INS + GLU, n = 5), or with glucose and hormone replacement [i.e., glucagon, epinephrine, norepinephrine, and cortisol infusions (INS + GLU + HR, n = 6)]. The increases in counterregulatory hormones that occurred during insulin-induced hypoglycemia were simulated in the latter group. In this way, it was possible to separate the effects of hypoglycemia per se from those due to the associated counterregulatory hormone response. Glycogenolysis and gluconeogenesis were measured with a combination of tracer ([ 3-3H]glucose and [U-14C]alanine) and hepatic arteriovenous (AV) difference techniques during a 40-min control and a 180-min experimental period. Insulin levels increased similarly in all groups (to congruent to 250 microU/ml), whereas plasma glucose levels decreased in INS (115 +/- 3 to 41 +/- 3 mg/dl; P less than .05) and rose slightly in both INS + GLU (108 +/- 2 to 115 +/- 4 mg/dl; P less than .05) and INS + GLU + HR (111 +/- 3 to 120 +/- 3 mg/dl; P less than .05) due to glucose infusion. Glucagon, epinephrine, norepinephrine, and cortisol were replaced in INS + GLU + HR so that the increments in their levels were 102 +/- 6, 106 +/- 14, 117 +/- 9, and 124 +/- 37%, respectively, of their increments in INS. At no time was there a significant difference between the hormone levels in INS and INS + GLU + HR. The rise in the counterregulatory hormones per se accounted for only half (53 +/- 9% by the AV difference method and 54 +/- 10% by tracer method) of the glucose production associated with hypoglycemia resulting from insulin infusion. The rate and efficiency of alanine conversion to glucose in the hormone-replacement studies were only 29 +/- 10 and 50 +/- 27% of what occurred during hypoglycemia induced by insulin infusion. In conclusion, the counterregulatory hormones alone (i.e., without accompanying hypoglycemia) can account for only 50% of the glucose production that is present during insulin-induced hypoglycemia. The remaining 50%, therefore, must result from effects of hypoglycemia other than its ability to trigger hormone release.

Similar dose responsiveness of hepatic glycogenolysis and gluconeogenesis to glucagon in vivo.

This study was undertaken to determine whether the dose-dependent effect of glucagon on gluconeogenesis parallels its effect on hepatic glycogenolysis in conscious overnight-fasted dogs. Endogenous insulin and glucagon secretion were inhibited by somatostatin (0.8 micrograms X kg-1 X min-1), and intraportal replacement infusions of insulin (213 +/- 28 microU X kg-1 X min-1) and glucagon (0.65 ng X kg-1 X min-1) were given to maintain basal hormone concentrations for 2 h (12 +/- 2 microU/ml and 108 +/- 23 pg/ml, respectively). The glucagon infusion was then increased 2-, 4-, 8-, or 12-fold for 3 h, whereas the rate of insulin infusion was left unchanged. Glucose production (GP) was determined with 3-[3H]glucose, and gluconeogenesis (GNG) was assessed with tracer (U-[14C]alanine conversion to [14C]glucose) and arteriovenous difference (hepatic fractional extraction of alanine, FEA) techniques. Increases in plasma glucagon of 53 +/- 8, 199 +/- 48, 402 +/- 28, and 697 +/- 149 pg/ml resulted in initial (15-30 min) increases in GP of 1.1 +/- 0.4 (N = 4), 4.9 +/- 0.5 (N = 4), 6.5 +/- 0.6 (N = 6), and 7.7 +/- 1.4 (N = 4) mg X kg-1 X min-1, respectively; increases in GNG (approximately 3 h) of 48 +/- 19, 151 +/- 50, 161 +/- 25, and 157 +/- 7%, respectively; and increases in FEA (3 h) of 0.14 +/- 0.07, 0.37 +/- 0.05, 0.42 +/- 0.04, and 0.40 +/- 0.17, respectively. In conclusion, GNG and glycogenolysis were similarly sensitive to stimulation by glucagon in vivo, and the dose-response curves were markedly parallel.

Sequence homology and structural analysis of the clostridial neurotoxins.

The clostridial neurotoxins (CNTs), comprised of tetanus neurotoxin (TeNT) and the seven serotypes of botulinum neurotoxin (BoNT A-G), specifically bind to neuronal cells and disrupt neurotransmitter release by cleaving proteins involved in synaptic vesicle membrane fusion. In this study, multiple CNT sequences were analyzed within the context of the 1277 residue BoNT/A crystal structure to gain insight into the events of binding, pore formation, translocation, and catalysis that are required for toxicity. A comparison of the TeNT-binding domain structure to that of BoNT/A reveals striking differences in their surface properties. Further, the solvent accessibility of a key tryptophan in the C terminus of the BoNT/A-binding domain refines the location of the ganglioside-binding site. Data collected from a single frozen crystal of BoNT/A are included in this study, revealing slight differences in the binding domain orientation as well as density for a previously unobserved translocation domain loop. This loop and the conservation of charged residues with structural proximity to putative pore-forming sequences lend insight into the CNT mechanism of pore formation and translocation. The sequence analysis of the catalytic domain revealed an area near the active-site likely to account for specificity differences between the CNTs. It revealed also a tertiary structure, highly conserved in primary sequence, which seems critical to catalysis but is 30 A from the active-site zinc ion. This observation, along with an analysis of the 54 residue "belt" from the translocation domain are discussed with respect to the mechanism of catalysis.

Structure and function of anthrax toxin.

Anthrax toxin is a binary A-B toxin comprised of protective antigen (PA) and two enzymatic moieties, edema factor (EF) and lethal factor (LF). In the presence of a host cell-surface receptor, PA can mediate the delivery of EF and LF from the extracellular milieu into the host cell cytosol to effect toxicity. In this delivery, PA undergoes multiple structural changes--from a monomer to a heptameric prepore to a membrane-spanning heptameric pore. The catalytic factors also undergo dramatic structural changes as they unfold to allow for their translocation across the endosomal membrane and refold to preserve their catalytic activity within the cytosol. In addition to these gross structural changes, the intoxication mechanism depends on the ability of PA to form specific interactions with the host cell receptor, EF, and LF. This chapter presents a review of experiments probing these structural interactions and rearrangements in the hopes of gaining a molecular understanding of toxin action.

Hepatic release of tumor necrosis factor in the endotoxin-treated conscious dog.

The effects of a 4 h intraportal infusion of Escherichia coli lipopolysaccharide (LPS, .21 mu g/kg/min) on the release of tumor necrosis factor (TNF) by hepatic and nonhepatic splanchnic tissues was assessed in the chronically catheterized conscious dog (n = 7) using arteriovenous difference techniques. TNF levels were measured using both a WEHI-164 cytotoxicity assay (WEHI) and a h-TNF-alpha EIA kit (ELISA; Biosource, Camarillo, CA). Using WEHI, arterial TNF levels increased from 10 + or - 6 pg/mL to a peak of 4667 + or - 1442 pg/mL 100 min after LPS and fell to 443 + or - 199 pg/mL by 240 min. Using ELISA, arterial TNF levels increased from 5 + or - 5 pg/mL to a peak of 12,234 + or - 2046 pg/mL at 100 min and fell to 3511 + or - 991 pg/mL by 240 min. WEHI could not be used to assess organ TNF release due to excessive assay variability. Based upon ELISA, net hepatic TNF output increased from undetectable release at basal to 23.0 + or - 10.7 ng/kg/min at 60 min and returned toward basal by 240 min (4.7 + or - 3.8 ng/kg/min). Net release of TNF by the nonhepatic splanchnic bed was not observed. One compartment analysis of the arterial TNF response indicated that net release of TNF by the liver accounted for the majority of the increase in the arterial TNF levels. In summary, after intraportal LPS infusion, it was determined that 1) both assays predict similar qualitative TNF response, while the quantitative response differs, 2) the liver is the major site of TNF production, and 3) the nonhepatic splanchnic bed is not a net producer of TNF.

Alterations in hepatic gluconeogenic amino acid uptake and gluconeogenesis in the endotoxin treated conscious dog.

We examined the effect of a 240 min intraportal infusion of a nonlethal dose of Escherichia coli endotoxin (.21 g x kg(-1) x min[-1]) on hepatic amino acid and glucose metabolism in chronically catheterized 42 h fasted conscious dogs (n = 8). Hepatic metabolism was assessed using tracer (3-[3H]glucose [U-14C]alanine) and arteriovenous difference techniques. After endotoxin administration net hepatic glucose output increased twofold. Arterial plasma insulin levels decreased by 25%, whereas arterial plasma glucagon and cortisol levels increased 10- and 6-fold, respectively. Arterial lactate levels increased 6.4-fold, whereas net hepatic lactate uptake was not increased. Arterial alanine levels (1.6-fold) and net hepatic alanine uptake (1.3-fold) increased, whereas net hepatic alanine fractional extraction was unaltered. In contrast, the arterial levels of the other gluconeogenic amino acids (glutamine, glycine, serine, and threonine) decreased. Despite this decrease, net uptake of these amino acids by the liver did not decrease, because net hepatic amino acid fractional extraction increased. Total net hepatic gluconeogenic precursor uptake was unaltered (1.1 +/- .1 to 1.3 +/- .3 mg x kg(-1) x min(-1) expressed in glucose equivalents). In summary, gluconeogenesis does not increase after endotoxin administration. Thus, an increase in net hepatic glycogenolysis accounts for the majority of the increase in hepatic glucose production. The lack of an increase in alanine fractional extraction, despite hyperglucagonemia and a rise in the fractional extraction of other gluconeogenic amino acids, suggests that endotoxin specifically impairs hepatic alanine entry in vivo.

Interaction of gut and liver in nitrogen metabolism during exercise.

The role of the gut and liver in nitrogen metabolism was studied during rest, 150 minutes of moderate-intensity treadmill exercise, and 90 minutes of recovery in 18 hour-fasted dogs (n = 6). Dogs underwent surgery 16 days before an experiment for implantation of catheters in a carotid artery and in the portal and hepatic veins, and Doppler flow cuffs on the hepatic artery and portal vein. Arterial glutamine, alanine, and alpha-amino nitrogen (AAN) levels decreased gradually with exercise (P less than .05), while arterial glutamate, NH3, and urea were unchanged. Net gut glutamine uptake was 1.3 +/- 0.5 mumol/kg.min at rest, and increased transiently to 2.5 +/- 0.3 mumol/kg.min at 60 minutes of exercise (P less than .05) as gut extraction increased. Net hepatic glutamine uptake was 0.6 +/- 0.4 mumol/kg.min at rest, and increased to 3.4 +/- 0.6 and 2.6 +/- 0.5 mumol/kg.min after 60 and 150 minutes of exercise (P less than .05) as hepatic extraction increased. Net gut glutamate and NH3 output both increased transiently with exercise (P less than .05). These increases were matched by parallel increments in the net hepatic uptakes of these compounds. Alanine output by the gut and uptake by the liver were unchanged with exercise. Net gut AAN output was -2.1 +/- 1.8 mumol/kg.min at rest (uptake occurred), and increased transiently to 11.2 +/- 3.5 mumol/kg.min after 30 minutes of exercise (P less than .05).(ABSTRACT TRUNCATED AT 250 WORDS)

The role of glucagon in the control of protein and amino acid metabolism in vivo.

The relative contribution of hyperglucagonemia to the mechanisms of nitrogen loss during catabolic states has not been clearly established. The present study examines the independent effect of physiologic elevations of plasma glucagon on whole-body protein kinetics, as well as on net amino acid balance across the liver and gastrointestinal tract tissues, in conscious 18-hour-fasted dogs (n = 7). Each study consisted of a 120-minute equilibration period, a 30-minute basal period, and a 150-minute experimental period. Leucine kinetics were measured using L-[1-14C]leucine. Pancreatic hormones were maintained by infusing intravenous somatostatin (0.8 micrograms/kg.min), intraportal insulin (275 microU/kg.min), and intraportal glucagon (0.65 ng/kg.min basally and 2.5 experimentally). Dextrose was infused to maintain plasma glucose constant (14.1 +/- 0.3 mumol/L), thereby providing a consistent metabolic steady state for the study of protein and amino acid metabolism. In the experimental period, plasma glucagon was fourfold basal levels (112 +/- 10 v 32 +/- 6 pg/mL), whereas plasma insulin remained stable (mean, 10 +/- 1 microU/mL). Hepatic glucose production was increased 30%, but leucine rates of appearance ([Ra] proteolysis), oxidative disappearance (Rd), and nonoxidative Rd (protein synthesis) were not altered during the experimental period. Furthermore, the net release of amino acids by the gastrointestinal tract was not increased by glucagon. However, uptake and extraction of amino acids by the liver were increased, resulting in a 17% decrease in total plasma amino acids.(ABSTRACT TRUNCATED AT 250 WORDS)

Impact of suprapharmacological androgenic steroid administration on basal and insulin-stimulated glucose and amino acid metabolism.

Effects of androgenic steroids at doses used by athletes were studied in a canine model system in which dosage, diet, and activity were controlled. Dogs were treated with 19-nortestosterone (200 mg/wk intramuscularly) or vehicle and were studied at 18 (n = 4 in steroid and vehicle) or 32 (n = 6 in steroid and n = 4 in vehicle) days. A laparotomy was performed under general anesthesia 17 days before experimentation, and catheters were placed in an artery, portal vein, and hepatic vein. Studies consisted of an equilibration (120 minutes) and a control (40 minutes) period and a three-step immunoreactive insulin euglycemic clamp (1, 2, and 15 mU/kg.min). Step 1 was 150 minutes, and steps 2 and 3 were 90 minutes. Data were collected during the last 30 minutes of each step. Glucose and leucine kinetics were assessed with 3H-glucose and 14C-leucine. Plasma glucose in steroid and vehicle groups was 104 +/- 5 (mean +/- SE) versus 108 +/- 3 mg/dL and 100 +/- 5 versus 107 +/- 4 mg/dL at 18 and 32 days. Glucose turnover was similar at 18 days in steroid and vehicle groups (3.9 +/- 0.3 v 3.6 +/- 0.3 mg/kg.min, respectively), but was elevated in the steroid group at 32 days (5.4 +/- 0.5 v 3.2 +/- 0.4 mg/kg.min). Glucose infusion rates were lower in the steroid group with 15 mU/kg.min immunoreactive insulin at 32 days (15.0 +/- 1.1 v 21.2 +/- 1.4 mU/kg.min). Immunoreactive insulin-independent glucose utilization (Rd) was unaffected at 18 days of steroid treatment, but was increased by almost fourfold at 32 days.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of acute elevations in plasma cortisol levels on alanine metabolism in the conscious dog.

The present study was undertaken to determine whether an acute physiological increase in plasma cortisol level had significant effects on alanine metabolism and gluconeogenesis within 3 hours in conscious, overnight-fasted dogs. Each experiment consisted of an 80-minute tracer and dye equilibration period, a 40-minute basal period, and a 3-hour experimental period. A primed, continuous infusion of [3-3H]glucose and continuous infusions of [U-14C]alanine and indocyanine green dye were initiated at the start of the equilibration period and continued throughout the experiment. Dogs were studied with (1) a hydrocortisone infusion ([CORT] 3.0 micrograms.kg-1.min-1, n = 5), (2) hydrocortisone infused as in CORT, but with pancreatic hormones clamped using somatostatin and basal intraportal replacement of insulin and glucagon (CLAMP+CORT, n = 5), or (3) saline infusion during a pancreatic clamp (CLAMP, n = 5). Glucose production and gluconeogenesis were determined using tracer and arteriovenous difference techniques. During CLAMP, all parameters were stable except for a modest 67% +/- 6% increase in gluconeogenic conversion of alanine to glucose and a 53% +/- 26% increase in gluconeogenic efficiency. When plasma cortisol levels were increased fourfold during CLAMP+CORT, there was no change in the concentration, production, or clearance of glucose. Gluconeogenic conversion of alanine to glucose increased 10% +/- 34% and gluconeogenic efficiency increased 65% +/- 43%, while net hepatic alanine uptake (NHAU) increased 60% +/- 19% and hepatic fractional extraction of alanine increased 38% +/- 12%. Cortisol did not cause an increase in the arterial glycerol level or net hepatic glycerol uptake.(ABSTRACT TRUNCATED AT 250 WORDS)