Increased immunogenicity and induction of class switching by conjugation of complement C3d to pneumococcal serotype 14 capsular polysaccharide.

Previous studies have demonstrated an adjuvant effect for the C3d fragment of complement C3 when coupled to T-dependent protein antigens. In this study, we examined the antibody response to covalent conjugates of C3d and a T-independent antigen, the capsular polysaccharide of serotype 14 Streptococcus pneumoniae (PPS14). We prepared a conjugate of mouse C3d and PPS14 and compared its immunogenicity with that of a conjugate of PPS14 and ovalbumin (OVA). When BALB/c mice were immunized with PPS14-C3d, there was a significant increase in serum anti-PPS14 concentrations compared with either native PPS14 or control PPS14-glycine conjugates. This was accompanied by a switch in anti-PPS14 from predominantly immunoglobulin M (IgM) to IgG1 by day 25 following primary immunization. Following secondary immunization with PPS14-C3d, there was a marked booster response and a further increase in the ratio of IgG1 to IgM anti-PPS14. Although the primary antibody response to the PPS14-OVA conjugate exceeded that induced by immunization with PPS14-C3d, serum anti-PPS14 concentrations after a second injection of PPS14-C3d were nearly identical to those induced by secondary immunization with PPS14-OVA. Experiments with athymic nude mice suggested that T cells were not required for the adjuvant effect of C3d on the primary immune response to PPS14 but were necessary for enhancement of the memory response after a second injection of PPS14-C3d. These studies show that the adjuvant effects of C3d extend to T-independent antigens as well as T-dependent antigens. As a means of harnessing the adjuvant potential of the innate immune system, C3d conjugates may prove useful as a component of vaccines against encapsulated bacteria.

Alterations in basal glucose metabolism during late pregnancy in the conscious dog.

We assessed basal glucose metabolism in 16 female nonpregnant (NP) and 16 late-pregnant (P) conscious, 18-h-fasted dogs that had catheters inserted into the hepatic and portal veins and femoral artery approximately 17 days before the experiment. Pregnancy resulted in lower arterial plasma insulin (11 +/- 1 and 4 +/- 1 microU/ml in NP and P, respectively, P < 0.05), but plasma glucose (5.9 +/- 0.1 and 5.6 +/- 0.1 mg/dl in NP and P, respectively) and glucagon (39 +/- 3 and 36 +/- 2 pg/ml in NP and P, respectively) were not different. Net hepatic glucose output was greater in pregnancy (42.1 +/- 3.1 and 56.7 +/- 4.0 micromol. 100 g liver(-1).min(-1) in NP and P, respectively, P < 0.05). Total net hepatic gluconeogenic substrate uptake (lactate, alanine, glycerol, and amino acids), a close estimate of the gluconeogenic rate, was not different between the groups (20.6 +/- 2.8 and 21.2 +/- 1.8 micromol. 100 g liver(-1). min(-1) in NP and P, respectively), indicating that the increment in net hepatic glucose output resulted from an increase in the contribution of glycogenolytically derived glucose. However, total glycogenolysis was not altered in pregnancy. Ketogenesis was enhanced nearly threefold by pregnancy (6.9 +/- 1.2 and 18.2 +/- 3.4 micromol. 100 g liver(-1).min(-1) in NP and P, respectively), despite equivalent net hepatic nonesterified fatty acid uptake. Thus late pregnancy in the dog is not accompanied by changes in the absolute rates of gluconeogenesis or glycogenolysis. Rather, repartitioning of the glucose released from glycogen is responsible for the increase in hepatic glucose production.

Autoregulation of hepatic glucose production.

In vitro evidence indicates that the liver responds directly to changes in circulating glucose concentrations with reciprocal changes in glucose production and that this autoregulation plays a role in maintenance of normoglycemia. Under in vivo conditions it is difficult to separate the effects of glucose on neural regulation mediated by the central nervous system from its direct effect on the liver. Nevertheless, it is clear that nonhormonal mechanisms can cause significant changes in net hepatic glucose balance. In response to hyperglycemia, net hepatic glucose output can be decreased by as much as 60-90% by nonhormonal mechanisms. Under conditions in which hepatic glycogen stores are high (i.e. the overnight-fasted state), a decrease in the glycogenolytic rate and an increase in the rate of glucose cycling within the liver appear to be the explanation for the decrease in hepatic glucose output seen in response to hyperglycemia. During more prolonged fasting, when glycogen levels are reduced, a decrease in gluconeogenesis may occur as a part of the nonhormonal response to hyperglycemia. A substantial role for hepatic autoregulation in the response to insulin-induced hypoglycemia is most clearly evident in severe hypoglycemia (< or = 2.8 mmol/l). The nonhormonal response to hypoglycemia apparently involves enhancement of both gluconeogenesis and glycogenolysis and is capable of supplying enough glucose to meet at least half of the requirement of the brain. The nonhormonal response can include neural signaling, as well as autoregulation. However, even in the absence of the ability to secrete counterregulatory hormones (glucocorticoids, catecholamines, and glucagon), dogs with denervated livers (to interrupt neural pathways between the liver and brain) were able to respond to hypoglycemia with increases in net hepatic glucose output. Thus, even though the endocrine system provides the primary response to changes in glycemia, autoregulation plays an important adjunctive role.

Oligoclonality of serum immunoglobulin G antibody responses to Streptococcus pneumoniae capsular polysaccharide serotypes 6B, 14, and 23F.

Serum antibodies (Abs) specific for the capsular polysaccharides of Streptococcus pneumoniae provide protection against invasive pneumococcal disease. Previous studies indicate that Abs to pneumococcal polysaccharide (PPS) serotypes 1 and 6B have limited clonal diversity. To determine if restricted diversity was a feature common to other PPS specificities, we examined the light (L)-chain expression and isoelectric heterogeneity of type 6B, 14, and 23F Abs elicited in 15 adults following PPS vaccination. At the population level, both PPS-6B and PPS-14 Abs expressed kappa and lambda chains, although 6B Abs more frequently expressed lambda chains lambda and 14 Abs more frequently expressed kappa chains. In individual sera, Abs were generally skewed towards either kappa or lambda expression. 23F-specific Abs had predominantly kappa chains. Isoelectric focusing analyses showed that sera contained one or at most a few immunoglobulin G Ab spectrotypes to all three respective capsular serotypes, a result indicative of oligoclonality. A sequence analysis of a purified PPS-14-specific Ab having a single spectrotype gave uniform amino-terminal sequences for both the heavy chain (V(H)III subgroup) and the L chain (kappaIII-A27 V region). From these results we conclude that within individual adults, serum Ab responses to PPS serotypes 6B, 14, and 23F derive from a small number of dominant B-cell clones, and consequently variable-region expression is probably individually limited as well. Oligoclonality appears to be a general characteristic of human PPS-specific Ab repertoires, and we suggest that this property could lead to individual differences in Ab fine specificity and/or functional activity against encapsulated pneumococci.

Physiological changes in circulating glucagon alter hepatic glucose disposition during portal glucose delivery.

This study examined whether physiological changes in glucagon alter net hepatic glucose uptake (NHGU) or glycogen synthesis under conditions of hyperglycemia, hyperinsulinemia, and portal vein glucose concentrations exceeding those in the arterial circulation. Somatostatin was infused into 42-h-fasted dogs, insulin and glucagon were replaced intraportally at basal rates, and peripheral infusion of glucose maintained the hepatic glucose load twofold basal for 90 min (period 1). In period 2 (240 min) the insulin infusion was increased fourfold, glucose was infused intraportally, the hepatic glucose load was twofold basal, and glucagon was infused to create levels 150% basal (HiGGN, n = 6) or 40% basal (LoGGN, n = 6). NHGU rates (mg.kg-1.min-1) were low during period 1 (-0.9 +/- 0.7 in LoGGN and -0.2 +/- 0.4 in HiGGN, not significant) but increased during period 2 (-4.1 +/- 0.6 in LoGGN and -1.9 +/- 0.2 in HiGGN, P < 0.05). Endogenous glucose production (Endo Ra) declined during period 2 in LoGGN (P < 0.01 vs. basal) but did not change in HiGGN. Tracer-determined hepatic glucose uptake did not differ between groups. The poststudy increment in liver glycogen synthase I (12.5 +/- 3 vs. 6.5 +/- 2% of total) was greater in LoGGN (P < 0.05), as was net glycogen synthesis (27 +/- 8 vs. 13 +/- 3 mg/g liver, P = 0.06). An elevation in glucagon reduced NHGU (because of failure to suppress Endo Ra) and glycogen synthase activation and tended to reduce glycogen deposition.

In the absence of counterregulatory hormones, the increase in hepatic glucose production during insulin-induced hypoglycemia in the dog is initiated in the liver rather than the brain.

We have previously demonstrated that the liver can release glucose in response to insulin-induced hypoglycemia, despite the absence of glucagon, epinephrine, cortisol, and growth hormone. The aim of this study was to determine whether this is activated by liver or brain hypoglycemia. We assessed the response to insulin-induced hypoglycemia in the absence of counterregulatory hormones in overnight-fasted conscious adrenalectomized dogs that were given somatostatin and intraportal insulin (30 pmol x kg(-1) x min(-1)) for 360 min. Glucose was infused to maintain euglycemia for 3 h and then to allow limited peripheral hypoglycemia for the next 3 h. During peripheral hypoglycemia, five dogs received glucose via both carotid and vertebral arteries to maintain cerebral euglycemia (H-EU group) concurrently with peripheral hypoglycemia, while six dogs received saline in these vessels to allow simultaneous cerebral and peripheral hypoglycemia (H-HY group). Throughout the study, arterial insulin was 1,675 +/- 295 and 1,440 +/- 310 pmol/l in the H-HY and H-EU groups, respectively. Glucose fell from 6.2 +/- 0.3 to 2.1 +/- 0.0 mmol/l and from 5.8 +/- 0.3 to 1.9 +/- 0.1 mmol/l in the last hour in the H-HY and H-EU groups, respectively (P < 0.05 for both). Norepinephrine rose from 1.12 +/- 0.35 to 2.44 +/- 0.69 nmol/l and from 1.09 +/- 0.07 to 1.74 +/- 0.16 nmol/l in the last hour in the H-HY and H-EU groups, respectively (P < 0.05 for both; no difference between groups). Glucagon, epinephrine, and cortisol were below the limits of detection. The liver switched from uptake to output of glucose during peripheral hypoglycemia in both the H-HY (-7.1 +/- 2.1 to 5.4 +/- 3.1 micromol x kg(-1) x min(-1)) and H-EU (-7.9 +/- 3.5 to 3.4 +/- 1.7 micromol x kg(-1) x min(-1)) groups (P < 0.05 for both; no difference between groups). Alanine levels and net hepatic alanine uptake fell similarly in both groups. There were increases (P < 0.05) in glycerol (12 +/- 3 to 258 +/- 47 micromol/l) and nonesterified fatty acid (194 +/- 10 to 540 +/- 80 micromol/l) levels and in total ketone production (0.4 +/- 0.1 to 1.1 +/- 0.2 micromol x kg(-1) x min(-1)) in the H-HY group, but these parameters did not change in the H-EU group. These data clearly indicate that the lipolytic and hepatic responses to hypoglycemia are driven by differential sensing mechanisms. Thus, during insulin-induced hypoglycemia, when counterregulatory hormones are absent, liver hypoglycemia triggers the increase in hepatic glucose production, whereas cerebral hypoglycemia causes the increases in lipolysis and ketogenesis.

Counterregulation by epinephrine and glucagon during insulin-induced hypoglycemia in the conscious dog.

We assessed the combined role of epinephrine and glucagon in regulating gluconeogenic precursor metabolism during insulin-induced hypoglycemia in the overnight-fasted, adrenalectomized, conscious dog. In paired studies (n = 5), insulin was infused intraportally at 5 mU.kg-1.min-1 for 3 h. Epinephrine was infused at a basal rate (B-EPI) or variable rate to simulate the normal epinephrine response to hypoglycemia (H-EPI), whereas in both groups the hypoglycemia-induced rise in cortisol was simulated by cortisol infusion. Plasma glucose fell to approximately 42 mg/dl in both groups. Glucagon failed to rise in B-EPI, but increased normally in H-EPI. Hepatic glucose release fell in B-EPI but increased in H-EPI. In B-EPI, the normal rise in lactate levels and net hepatic lactate uptake was prevented. Alanine and glycerol metabolism were similar in both groups. Since glucagon plays little role in regulating gluconeogenic precursor metabolism during 3 h of insulin-induced hypoglycemia, epinephrine must be responsible for increasing lactate release from muscle, but is minimally involved in the lipolytic response. In conclusion, a normal rise in epinephrine appears to be required to elicit an increase in glucagon during insulin-induced hypoglycemia in the dog. During insulin-induced hypoglycemia, epinephrine plays a major role in maintaining an elevated rate of glucose production, probably via muscle lactate release and hepatic lactate uptake.

Hepatic denervation does not significantly change the response of the liver to glucagon in conscious dogs.

In view of the increasing frequency of liver transplantation, and the importance of glucagon in the minute-to-minute regulation of glucose production, we assessed the effect of hepatic denervation on the liver's response to a physiological rise in glucagon in 18-h fasted dogs. Before study (2 wk), the dogs underwent liver denervation (DN; n = 6) or sham operation (SH; n = 5). Endogenous insulin and glucagon secretion were inhibited using somatostatin, and the two hormones were replaced intraportally in basal amounts. After the control period the glucagon infusion rate was tripled for 3 h. Glucagon increased from 41 +/- 8 to 128 +/- 8 and 54 +/- 4 to 129 +/- 9 pg/ml in SH and DN, respectively (P < 0.05), causing tracer-determined glucose production to increase from 2.5 +/- 0.1 to 4.9 +/- 0.5 and 2.3 +/- 0.1 to 5.8 +/- 0.8 mg.kg-1.min-1 by 15 min, respectively (P < 0.05). Glucose clearance fell slightly during glucagon infusion in DN, causing a somewhat greater increase in the plasma glucose level (to 175 +/- 15 vs. 207 +/- 20 mg/dl). The changes in gluconeogenic efficiency increased 65-90% in both groups (P < 0.05). In conclusion, denervation of the liver failed to significantly alter the metabolic response of that organ to a half-maximally effective increment in the plasma glucagon level.

Counterregulation during hypoglycemia is directed by widespread brain regions.

Previous studies have demonstrated the importance of the brain in directing counterregulation during insulin-induced hypoglycemia in dogs. The capability of selective carotid or vertebrobasilar hypoglycemia in triggering counterregulation was assessed in this study using overnight-fasted dogs. Insulin (21 pM.kg-1.min-1) was infused for 3 h to create peripheral hypoglycemia in the presence of 1) selective carotid hypoglycemia (vertebral glucose infusion, n = 5), 2) selective vertebrobasilar hypoglycemia (carotid glucose infusion, n = 5), 3) the absence of brain hypoglycemia (carotid and vertebral glucose infusion, n = 4), or 4) total brain hypoglycemia (no head glucose infusion, n = 5). Glucose was infused via a leg vein as needed in each group to minimize the differences in peripheral glucose levels (2.6 +/- 0.1, 3.0 +/- 0.2, 2.7 +/- 0.1, and 2.5 +/- 0.1 mM, respectively). The humoral responses (cortisol, glucagon, catecholamines, and pancreatic polypeptide) to hypoglycemia were minimally attenuated (< 40%) by selective carotid or vertebrobasilar euglycemia. In addition, the increase in hepatic glucose production, as assessed using [3-3H]glucose, was attenuated by only 41 and 34%, respectively, during selective carotid or vertebrobasilar hypoglycemia. These observations offer support for the hypothesis that more than one center is important in hypoglycemic counterregulation in the dog and that they are located in brain regions supplied by the carotid and vertebrobasilar arteries, because significant counterregulation occurred when hypoglycemia developed in either of these circulations. Counterregulation during hypoglycemia, therefore, is probably directed by widespread brain regions that contain glucose-sensitive neurons such that the sensing sites are redundant.

The effects of lactate loading on alanine and glucose metabolism in the conscious dog.

The effect of lactate per se on alanine and glucose metabolism was studied in five overnight-fasted conscious dogs. Somatostatin was infused to inhibit endogenous pancreatic insulin and glucagon release and the hormones were replaced intraportally at basal rates. Saline (n = 5) or lactate (at 25 and 50 mumol.kg-1.min-1 for 90 minutes each) was infused, and blood samples were taken during the last 30 minutes of each 90-minute period. Insulin, epinephrine, norepinephrine, and cortisol levels remained unchanged during saline or lactate infusion. Glucagon level decreased slightly during lactate (94 +/- 7 to 74 +/- 9 and 79 +/- 8 pg/mL) and saline (91 +/- 8 to 90 +/- 4 and 81 +/- 11 pg/mL) infusions. There were no significant changes in lactate or alanine levels or net hepatic balances with saline infusion. Blood lactate level increased from 657 +/- 74 to 1,718 +/- 126 and 3,300 +/- 321 mumol/L (both P < .05) during the low- and high-lactate infusion periods, respectively. The liver produced lactate during the control (5.57 +/- 2.92 mumol.kg-1 x min-1) and low-lactate infusion (1.75 +/- 2.58 mumol.kg-1 x min-1) periods, but consumed lactate (3.89 +/- 3.31 mumol.kg-1 x min -1; P < .05) during the high-lactate infusion period.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Role of hepatic nerves in response of liver to intraportal glucose delivery in dogs.

Net hepatic glucose uptake (NHGU) is much greater during oral or intraportal glucose loading than during peripheral intravenous glucose delivery even when similar glucose loads and hormone levels reaching the liver are maintained. To determine whether this difference is influenced by the hepatic nerves, nine conscious 42-h-fasted dogs in which a surgical denervation of the liver (liver norepinephrine levels postdenervation averaged 2.4% of normal) had been performed were subjected to a 40-min control period and two randomized 90-min test periods during which somatostatin (0.8 microgram.kg-1.min-1), intraportal insulin (1.2 mU.kg-1.min-1), and intraportal glucagon (0.5 ng.kg-1.min-1) were infused. The glucose load to the liver was increased twofold by infusing glucose into a peripheral vein (Pe) or the portal vein (Po). Arterial insulin and glucagon concentrations were 39 +/- 2 and 39 +/- 3 microU/ml and 55 +/- 5 and 54 +/- 7 pg/ml during Pe and Po, respectively. The hepatic glucose loads were 50.3 +/- 4.4 and 51.4 +/- 5.8 mg.kg-1.min-1 while NHGU was 2.1 +/- 0.5 and 2.2 +/- 0.7 mg.kg-1.min-1 during Pe and Po, respectively. Similar hormone levels and glucose loads reaching the liver in dogs with intact hepatic nerve supplies were previously shown to be associated with NHGU of 1.4 +/- 0.7 and 3.5 +/- 0.8 mg.kg-1.min-1 in the presence of peripheral and portal glucose delivery, respectively. In conclusion, an intact nerve supply to the liver appears to be vital for the normal response of the liver to intraportal glucose delivery.

Regulation of glucose metabolism by norepinephrine in conscious dogs.

The effects of norepinephrine (NE) at levels present in the circulation and synaptic cleft during stress on glucose metabolism were examined in overnight-fasted conscious dogs with fixed basal levels of insulin and glucagon. Plasma NE rose from 132 +/- 14 to 442 +/- 85 pg/ml and 100 +/- 20 to 3,244 +/- 807 pg/ml during 3 h of low (n = 6) and high (n = 5) NE infusion, respectively. Plasma glucose and glucose production rose only with high NE infusion (from 108 +/- 4 to 159 +/- 15 mg/dl and 2.78 +/- 0.24 to 3.41 +/- 0.38 mg.kg-1.min-1, respectively). NE infusion caused dose-dependent net hepatic lactate consumption, but net hepatic alanine uptake fell only with high NE infusion (31%). Alanine conversion to glucose rose by 67 +/- 13, 136 +/- 20, and 412 +/- 104%, and intrahepatic gluconeogenic efficiency rose by 42 +/- 27, 299 +/- 144, and 212 +/- 21% with saline and with low and high NE infusion, respectively. In conclusion, NE enhances gluconeogenesis by stimulating peripheral precursor release, by increasing substrate movement into the hepatocyte, and by increasing intrahepatic gluconeogenic efficiency. However, only the higher NE levels affected glucose metabolism profoundly enough to stimulate glucose production and to elevate the glucose level.

Role of glucagon in countering hypoglycemia induced by insulin infusion in dogs.

The aim of the present study was to characterize the role of glucagon in countering the prolonged hypoglycemia resulting from insulin infusion and to determine whether its effect is manifest through glycogenolysis and/or gluconeogenesis. Two groups of 18-h fasted somatostatin-treated dogs were given intraportal insulin at 5 mU.kg-1.min-1. In one group (SimGGN; n = 6), glucagon was infused intraportally so as to mimic the normal response to hypoglycemia. In a second group (BasGGN; n = 6), glucagon was infused at a basal rate. Glucose turnover and gluconeogenesis were assessed by combining tracer and hepatic balance techniques. Exogenous glucose was infused as needed to maintain equivalent hypoglycemia at approximately 45 mg/dl in the two groups. Although glucagon concentrations were significantly different, the levels of other counterregulatory hormones were equivalent in both experimental protocols. Endogenous glucose production (EGP) in SimGGN doubled from 2.4 +/- 0.2 to 5.4 +/- 0.8 mg.kg-1.min-1 by 1 h before dropping to 4.5 +/- 0.2 mg.kg-1.min-1 in the 3rd h of insulin infusion. EGP in BasGGN was initially 2.5 +/- 0.1 mg.kg-1.min-1, unchanged by 1 h, and increased to 3.9 +/- 0.2 mg.kg-1.min-1 by the 3rd h of insulin infusion. In the 1st h of insulin infusion, the rise in gluconeogenesis in both groups was equal and represented only a small part of total EGP. By the 3rd h, gluconeogenesis was the major contributor to total EGP, and gluconeogenic efficiency increased significantly more in SimGGN than BasGGN (261 vs. 140%, P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of lipolysis and ketogenesis by norepinephrine in conscious dogs.

The lipolytic and ketogenic effects of norepinephrine (NE) at levels present in the circulation or the synaptic cleft during stress were examined in the overnight-fasted conscious dog. Insulin and glucagon were maintained at basal levels while NE, at a rate of either 0.04 (n = 6) or 0.32 micrograms.kg-1.min-1 (n = 5), or saline (n = 6) was infused for 3 h. NE rose from 129 +/- 17 to 442 +/- 85 pg/ml (P less than 0.05) and 100 +/- 24 to 3,244 +/- 807 pg/ml (P less than 0.05) with the low and high infusion rates, respectively (unchanged with saline infusion). There were no significant changes in lipolysis or ketogenesis with saline infusion. Both low and high NE infusion produced sustained increases in glycerol (from 72 +/- 20 to 119 +/- 24 microM and 59 +/- 19 to 248 +/- 32 microM, respectively, both P less than 0.05), while nonesterified fatty acids (NEFA) rose from 609 +/- 85 to 952 +/- 100 and 767 +/- 140 to 2,054 +/- 199 microM (both P less than 0.05). Ketone levels and net hepatic production rose significantly only with the high NE infusion (from 88 +/- 10 to 266 +/- 46 microM and 1.30 +/- 0.26 to 7.62 +/- 1.48 mumol.kg-1.min-1, respectively, both P less than 0.05). The ratio of net hepatic ketone production to NEFA uptake rose 54% with high NE infusion. In conclusion, at circulating levels seen during stress, NE stimulates lipolysis but does not directly influence ketogenesis. At circulating levels projected to exist in the synaptic cleft during stress, NE has a potent lipolytic effect and stimulates ketogenesis.

Regulation of hepatic lactate balance during exercise.

The rate of exchange of lactate across the liver gives important insights into intracellular processes during muscular work. At the onset of exercise hepatic glycogenolysis increases rapidly, resulting in high rates of glycolytic flux and a transient rise in lactate output. With increasing exercise duration, gluconeogenesis is accelerated and the liver gradually shifts from a lactate-producing to a lactate-consuming state. Exercise-induced changes in hormone levels are critical in the regulation of hepatic glycogenolysis and gluconeogenesis and, therefore, net hepatic lactate balance. The fall in insulin stimulates hepatic glycogenolysis, glycolytic flux, and, as a result, hepatic lactate output. On the other hand, the stimulatory effects of glucagon on gluconeogenesis elicit an increase in hepatic lactate uptake. The rise in epinephrine may regulate gluconeogenesis during prolonged exercise by stimulating peripheral lactate mobilization, thereby providing gluconeogenic substrate to the liver. Chronic hepatic-denervation leads to an increase in gluconeogenesis and net hepatic lactate uptake at rest without altering total glucose production. However, the response to exercise is unaffected by the absence of hepatic nerves. Hence, the direction and magnitude of the hepatic lactate balance during exercise yields important information regarding flux through the gluconeogenic and glycolytic pathways, such that high rates of gluconeogenesis correspond to accelerated rates of hepatic lactate uptake and high rates of hepatic glycolytic flux lead to increased rates of hepatic lactate output.

Dose-related effects of epinephrine on glucose production in conscious dogs.

The effects of increases in plasma epinephrine from 78 +/- 32 to 447 +/- 75, 1,812 +/- 97, or 2,495 +/- 427 pg/ml on glucose production, including gluconeogenesis, were determined in the conscious, overnight-fasted dog, using a combination of tracer [( 3-3H]glucose and [U-14C]alanine) and arteriovenous difference techniques. Insulin and glucagon were fixed at basal levels using a pancreatic clamp. Plasma glucose levels rose during the 180-min epinephrine infusion by 47 +/- 7, 42 +/- 22, and 74 +/- 25 mg/dl, respectively, in association with increases in hepatic glucose output of 1.04 +/- 0.22, 1.87 +/- 0.23, and 3.70 +/- 0.83 mg.kg-1.min-1 (at 15 min). Blood lactate levels rose by 1.52 +/- 0.24, 4.29 +/- 0.49, and 4.60 +/- 0.45 mmol/l, respectively, by 180 min, despite increases in hepatic uptake of lactate of 3.47 +/- 5.73, 12.83 +/- 3.46, and 37.00 +/- 4.20 mumol.kg-1.min-1. The intrahepatic gluconeogenic efficiency with which the liver converted the incoming alanine to glucose had risen by 84 +/- 40, 77 +/- 24, and 136 +/- 34% at 180 min, respectively. The latter effect plus the effect on net hepatic lactate uptake point to an intrahepatic action of high levels of the hormone in vivo. In conclusion, epinephrine produces dose-dependent increments in overall glucose production, which involve a progressive stimulation of both glycogenolysis (as assessed by glucose production at 15 min) and gluconeogenesis (assessed in the last 30 min of the study). The latter involves a peripheral action of the catecholamine to increase gluconeogenic substrate supply to the liver and may also involve a hepatic effect when high epinephrine levels are present.