glycogen and Escherichia-coli-Infections

MAPKs are crucial for TNF-alpha and IL-6 production by innate immune cells in response to TLR ligands. MAPK phosphatase 1 (Mkp-1) deactivates p38 and JNK, abrogating the inflammatory response. We have previously demonstrated that Mkp-1(-/-) mice exhibit exacerbated inflammatory cytokine production and increased mortality in response to challenge with LPS and heat-killed Staphylococcus aureus. However, the function of Mkp-1 in host defense during live Gram-negative bacterial infection remains unclear. We challenged Mkp-1(+/+) and Mkp-1(-/-) mice with live Escherichia coli i.v. to examine the effects of Mkp-1 deficiency on animal survival, bacterial clearance, metabolic activity, and cytokine production. We found that Mkp-1 deficiency predisposed animals to accelerated mortality and was associated with more robust production of TNF-alpha, IL-6 and IL-10, greater bacterial burden, altered cyclooxygenase-2 and iNOS expression, and substantial changes in the mobilization of energy stores. Likewise, knockout of Mkp-1 also sensitized mice to sepsis caused by cecal ligation and puncture. IL-10 inhibition by neutralizing Ab or genetic deletion alleviated increased bacterial burden. Treatment with the bactericidal antibiotic gentamicin, given 3 h after Escherichia coli infection, protected Mkp-1(+/+) mice from septic shock but had no effect on Mkp-1(-/-) mice. Thus, during Gram-negative bacterial sepsis Mkp-1 not only plays a critical role in the regulation of cytokine production but also orchestrates the bactericidal activities of the innate immune system and controls the metabolic response to stress.

Topics: Animals; Cyclooxygenase 2; Dual Specificity Phosphatase 1; Enzyme-Linked Immunosorbent Assay; Escherichia coli; Escherichia coli Infections; Glucose; Glycogen; Gram-Negative Bacterial Infections; Hyperlipidemias; Inflammation; Interleukin-10; Interleukin-6; Lipid Metabolism; Mice; Mice, Knockout; Nitric Oxide Synthase Type II; Sepsis; Tumor Necrosis Factor-alpha

Mutant screens and transcriptome studies led us to consider whether the metabolism of glucose polymers, i.e., maltose, maltodextrin, and glycogen, is important for Escherichia coli colonization of the intestine. By using the streptomycin-treated mouse model, we found that catabolism of the disaccharide maltose provides a competitive advantage in vivo to pathogenic E. coli O157:H7 and commensal E. coli K-12, whereas degradation of exogenous forms of the more complex glucose polymer, maltodextrin, does not. The endogenous glucose polymer, glycogen, appears to play an important role in colonization, since mutants that are unable to synthesize or degrade glycogen have significant colonization defects. In support of the hypothesis that E. coli relies on internal carbon stores to maintain colonization during periods of famine, we found that by providing a constant supply of a readily metabolized sugar, i.e., gluconate, in the animal's drinking water, the competitive disadvantage of E. coli glycogen metabolism mutants is rescued. The results suggest that glycogen storage may be widespread in enteric bacteria because it is necessary for maintaining rapid growth in the intestine, where there is intense competition for resources and occasional famine. An important implication of this study is that the sugars used by E. coli are present in limited quantities in the intestine, making endogenous carbon stores valuable. Thus, there may be merit to combating enteric infections by using probiotics or prebiotics to manipulate the intestinal microbiota in such a way as to limit the availability of sugars preferred by E. coli O157:H7 and perhaps other pathogens.

Topics: Animals; Drug Resistance, Bacterial; Escherichia coli Infections; Escherichia coli O157; Gluconates; Glycogen; Intestines; Male; Maltose; Mice; Mutation; Phenotype; Polysaccharides; Streptomycin; Time Factors

During chronic total parenteral nutrition (TPN), net hepatic glucose uptake (NHGU) and net hepatic lactate release (NHLR) are markedly reduced (downward arrow approximately 45 and approximately 65%, respectively) with infection. Because small quantities of fructose are known to augment hepatic glucose uptake and lactate release in normal fasted animals, the aim of this work was to determine whether acute fructose infusion with TPN could correct the impairments in NHGU and NHLR during infection. Chronically catheterized conscious dogs received TPN for 5 days via the inferior vena cava at a rate designed to match daily basal energy requirements. On the third day of TPN administration, a sterile (SHAM, n = 12) or Escherichia coli-containing (INF, n = 11) fibrin clot was implanted in the peritoneal cavity. Forty-two hours later, somatostatin was infused with intraportal replacement of insulin (12 +/- 2 vs. 24 +/- 2 microU/ml, SHAM vs. INF, respectively) and glucagon (24 +/- 4 vs. 92 +/- 5 pg/ml) to match concentrations previously observed in sham and infected animals. After a 120-min basal period, animals received either saline (Sham+S, n = 6; Inf+S, n = 6) or intraportal fructose (0.7 mg x kg(-1) x min(-1); Sham+F, n = 6; Inf+F, n = 5) infusion for 180 min. Isoglycemia of 120 mg/dl was maintained with a variable glucose infusion. Combined tracer and arteriovenous difference techniques were used to assess hepatic glucose metabolism. Acute fructose infusion with TPN augmented NHGU by 2.9 +/- 0.4 and 2.5 +/- 0.3 mg x kg(-1) x min(-1) in Sham+F and Inf+F, respectively. The majority of liver glucose uptake was stored as glycogen, and NHLR did not increase substantially. Therefore, despite an infection-induced impairment in NHGU and different hormonal environments, small amounts of fructose enhanced NHGU similarly in sham and infected animals. Glycogen storage, not lactate release, was the preferential fate of the fructose-induced increase in hepatic glucose disposal in animals adapted to TPN.

Topics: Animals; Blood Glucose; Dogs; Escherichia coli Infections; Female; Fructose; Glucose; Glycogen; Hindlimb; Hormones; Kinetics; Lactic Acid; Liver; Parenteral Nutrition, Total

The effect of infection on hepatic uptake and disposal of a continuous (180-min) intravenous glucose infusion (8 mg.kg-1.min-1) was examined in conscious, 54-h-fasted, chronically catheterized dogs. Thirty-six hours before a study, either infection was induced by implantation of an Escherichia coli-containing (INF; 2 x 10(9) organisms/kg body wt; n = 6) fibrinogen clot, or a sterile (SH; n = 6) clot was implanted into the peritoneal cavity. Hepatic glucose metabolism was assessed using tracer ([3-3H]glucose and [U-14C]glucose) and arteriovenous difference techniques. Infection increased the basal rate of glucose appearance (45%); glucose levels were not altered. In response to glucose infusion, average blood glucose levels increased to similar levels (140 +/- 9 vs. 147 +/- 11 mg/dl in INF and SH, respectively), whereas arterial insulin levels were higher in the infected group during the last hour of the glucose infusion (77 +/- 10 vs. 41 +/- 5 microU/ml in INF vs. SH). Infection impaired net hepatic glucose uptake (0.6 +/- 0.5 and 2.7 +/- 0.7 mg.kg-1.min-1 in INF and SH; P < 0.05). The liver remained a persistent lactate consumer (4.1 +/- 1.8 mumol.kg-1.min-1), whereas the sham group became a net producer of lactate (-3.8 +/- 1.3 mumol.kg-1.min-1). Infection decreased net hepatic glycogen deposition by 53%. In conclusion, infection impairs net hepatic glucose uptake and glycogen deposition despite an exaggerated increase in insulin levels.

Topics: Animals; Dogs; Escherichia coli Infections; Gluconeogenesis; Glucose; Glycogen; Hemodynamics; Hormones; Kinetics; Liver; Liver Circulation; Oxidation-Reduction; Pancreatic Hormones

This study examined the acute role of glucagon in sustaining the increased hepatic gluconeogenesis observed in the conscious infected dog. After a basal sampling period, arterial glucagon levels were selectively decreased for 180 min by a peripheral infusion of somatostatin and basal intraportal infusion of insulin (GGN deficient; n = 6). In a separate protocol (GGN replaced; n = 5) glucagon was also infused intraportally to maintain the glucagon level at that seen during sepsis. Tracer and arteriovenous difference techniques were used to assess hepatic glucose metabolism and gluconeogenesis. In the GGN-deficient group the arterial plasma glucagon level fell from 416 +/- 49 to 88 +/- 21 pg/ml, whereas in the GGN-replaced group it remained elevated throughout (321 +/- 48 to 248 +/- 22 pg/ml). When glucagon was reduced, endogenous glucose production decreased by 1.6 +/- 0.3 mg.kg-1.min-1, and an exogenous glucose infusion was required to maintain euglycemia. Glucose metabolism remained unaltered when glucagon was replaced. When glucagon was deleted, net hepatic gluconeogenic precursor uptake was not altered. In contrast, the efficiency of gluconeogenesis was decreased by 33% compared with the GGN-replaced group. Liver biopsies taken at the end of the experiment indicated that a diversion of gluconeogenic carbon to glycogen accounted for 50% of the fall in gluconeogenic efficiency. In summary, the basal hyperglucagonemia seen during an infection helps sustain glucose production both through its effects on hepatic glycogen metabolism and on gluconeogenic efficiency.

Topics: Animals; Blood Glucose; Dogs; Escherichia coli Infections; Female; Glucagon; Gluconeogenesis; Glycogen; Hormones; Liver; Liver Circulation; Male

The responsiveness of septic rats to epinephrine-induced alterations in carbohydrate metabolism was studied. Nonlethal sepsis was produced by subcutaneous injections of live Escherichia coli over 18 hours in conscious catheterized rats. Glucose kinetics were assessed by IV infusion of [6-3H]-glucose. After two hours of tracer infusion, blood samples were taken for basal values. Thereafter, epinephrine was infused at 0, 0.05, 0.2, or 1.0 microgram/min/kg for an additional four hours. Compared with nonseptic rats, septic animals had increased basal values for glucose rate of appearance (Ra, 63%), glucose clearance (86%), and plasma lactate concentration (133%). Infusion of epinephrine resulted in dose-dependent increases in glucose Ra, as well as plasma glucose and lactate concentrations, and decreases in glucose clearance and muscle glycogen content. At each dose of epinephrine, the increases in response from basal of plasma glucose and glucose Ra in septic rats were 50% or less of that observed in nonseptic animals. There were no differences between septic and nonseptic rats in plasma lactate and glucose clearance responses from basal or in circulating levels of catecholamines achieved during the epinephrine infusion. The present results indicate that septic rats are less responsive than control animals to epinephrine-induced increases in glucose turnover.

Topics: Animals; Blood Glucose; Blood Pressure; Epinephrine; Escherichia coli Infections; Glucose; Glycogen; Heart Rate; Lactates; Lactic Acid; Male; Muscles; Osmolar Concentration; Rats; Rats, Inbred Strains; Time Factors

Topics: Animals; Escherichia coli Infections; Glycogen; Microscopy, Electron; Mitochondria; Muscles; Myocardium; Myofibrils; Rats; Rats, Inbred Strains; Sepsis

To determine whether extrapulmonary infection alters antibacterial defenses of the lung, we challenged mice with peritonitis due to Escherichia coli by aerosol inhalation with either Staphylococus aureus or Pseudomonas aeruginosa. In animals without peritonitis, 14% +/- 5% and 11% +/- 1% of the initially deposited viable S. aureus and P. aeruginosa, respectively, remained in the lungs at 4 hr. In contrast, in mice with peritonitis, at 4 hr 45% +/- 9% of the staphylococci were recoved, and the P. aeruginosa had increased to 948% +/- 354% of the initial inoculum. Proliferation of P. aeruginosa in mice with peritonitis was associated with impaired recruitment of polymorphonuclear neutrophils (PMNs) into the lungs. In contrast, a noninfectious stimulus induced more PMNs into the peritoneal cavity than did intraabdominal sepsis but only minimally impaired PMN recruitment into the lungs after aerosol challenge with P. aeruginosa. Sterile intraperitoneal stimulation did not significantly impair intrapulmonary killing of P. aeruginosa. Levels of antigenic C3 and functionally active C5 were significantly depleted in mice with peritonitis due to E. coli. We conclude that the systemic effects of sepsis, including complement depletion, contribute to the decreased pulmonary PMN recruitment and to impaired intrapulmonary bacterial killing of animals with peritonitis due to E. coli.

Topics: Animals; Caseins; Complement C3; Complement C5; Escherichia coli Infections; Female; Glycogen; Lung; Lung Diseases; Macrophages, Peritoneal; Mice; Neutrophils; Peritoneal Cavity; Peritonitis; Pseudomonas Infections; Staphylococcal Infections

Topics: Animals; Blood Glucose; Enteritis; Escherichia coli Infections; Glycogen; Liver; Mucus; Rabbits

Topics: Animals; Breast; Endotoxins; Escherichia coli Infections; Female; Glycogen; Liver; Mastitis; Pregnancy; Rabbits