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Query: UMLS:C0243026 (
sepsis
)
52,417
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1. In
sepsis
various processes of carbohydrate metabolism, such as hepatic gluconeogenesis and glycolysis, are altered. Phosphofructokinase-1, a key glycolytic enzyme, is controlled in the long term via regulation of synthesis and degradation of the protein itself, while in the short term it is regulated by allosteric effectors, such as fructose 2,6-bisphosphate (the most potent). In the present study hepatic
phosphofructokinase
-1 activity as well as
phosphofructokinase
-2 activity and the concentration of fructose 2,6-bisphosphate were assayed to determine if they might contribute to the derangement of carbohydrate metabolism seen commonly in
sepsis
. 2. The levels of glycogen and fructose 2,6-bisphosphate and the activity of
phosphofructokinase
-1 and
phosphofructokinase
-2 were determined in hepatic biopsies obtained at laparotomy from six patients with and seven patients without abdominal septic foci. 3. A significant increase in plasma lactate concentration was observed in the septic patients, whereas no significant differences in tissue glycogen content or plasma glucose concentration were seen between the groups. 4. No significant change in plasma insulin concentration was observed. However, levels of the counter-regulatory hormones (glucagon, cortisol and adrenaline) were elevated in the septic patients. 5. A 60% decrease in hepatic
phosphofructokinase
-1 activity was seen in the septic patients. However, no significant changes in hepatic
phosphofructokinase
-2 activity and fructose 2,6-bisphosphate content were observed in the septic patients. 6. The present results demonstrate that the decrease in hepatic
phosphofructokinase
-1 activity occurring in
sepsis
does not appear to reflect alterations in the concentration of fructose 2,6-bisphosphate.
...
PMID:Hepatic phosphofructokinase-1 activity and fructose 2,6-bisphosphate levels in patients with abdominal sepsis. 185 Jun 80
The intestinal metabolism of glucose and glutamine was studied in rats made septic by cecal ligation and puncture technique.
Sepsis
resulted in negative nitrogen balance and produced increases in the concentrations of blood pyruvate, lactate, alanine, and glutamine, and decreases in those of 3-hydroxybutyrate and acetoacetate. Both plasma insulin and glucagon concentrations were increased by 2.2- and 3.2-fold in septic rats, respectively. Portal-drained visceral blood flow increased in septic rats, and was accompanied by a decrease in the rates of utilization of glutamine and production of lactate, glutamate, and ammonia compared with those rates in sham-operated animals. Enterocytes isolated from septic rats showed decreased rates of glucose and glutamine utilization compared with cells isolated from corresponding controls. The maximal activities of hexokinase,
6-phosphofructokinase
, pyruvate kinase, and glutaminase were decreased in intestinal mucosal scrapings of septic rats. It is concluded that a moderate form of
sepsis
decreases the rates of glucose and glutamine utilization (both in vivo and in vitro) by the epithelial cells of the small intestine. This may be caused by changes in the maximal activities of key enzymes in the pathways of glucose and glutamine metabolism in these cells as a metabolic adaptation to spare glucose and glutamine for use by other tissues.
...
PMID:Glucose and glutamine metabolism in the small intestine of septic rats. 236 28
The possible role of inhibited gluconeogenic enzymes in rat liver during preterminal peritonitis septic shock was investigated. There was no difference in maximal activity of the enzymes
phosphofructokinase
and fructose biphosphatase in septic and control, fasted rats. Rats with
sepsis
showed a decrease in hexose monophosphates and an increase in fructose biphosphate. There was an unexpected increase in fructose 2,6-bisphosphate despite the hyperglucagonemic state of
sepsis
. This suggested a dissociation in the coordination of extracellular hormonal and intracellular effector mechanisms in the control of glucose metabolism during the preterminal phase of septic shock. This dissociation may be responsible for the metabolic dyshomeostasis in septic shock.
...
PMID:Hepatic fructose 2,6-bisphosphate in rats with peritonitis and septic shock. 609 Dec 86
Recent findings support the view that the bioenergetic part of septic organ failure is not caused by insufficient supply of oxygen but by disturbances of the mitochondrial function. Therefore, the aim of the present study was to investigate key enzymes of energy metabolism in septic hearts to answer the question whether or not impairment of mitochondrial or glycolytic enzymes occur under these conditions. For this purpose the well established model of septic baboons was used. Baboons under general anesthesia were made septic by infusion of Escherichia coli. Single challenge with infusion of high amounts of bacteria was compared with a multiple challenge protocol (less bacteria infused). Some animals obtained no E. coli (sham). The hearts of the baboons were removed after 72 h (survival: yes) or after death (survival: no) of the animals, frozen in liquid nitrogen, and stored at -80 degrees C until spectrophotometrical measurement of nine mitochondrial and glycolytic enzymes. A reduction of the activity of NADH:cytochrome-c-reductase (Complex I + III) to 67% and succinate:cytochrome-c-reductase (Complex II + III) to 45% was found in the hearts of surviving animals after infusion of high amounts of bacteria. After multiple challenge with lesser amounts of bacteria, no significant changes in enzyme activity were detectable. After lethal septic shock, activities of Complex I + III (12%) and Complex II + III (13%) as well as of
phosphofructokinase
(16%) were found to be strongly diminished. Decylubiquinol:cytochrome-c-reductase (Complex III, 59%), cytochrome-c-oxidase (51%), succinate dehydrogenase (60%), glucosephosphate isomerase (61%), lactate dehydrogenase (61%), and citrate synthase (120%) were less or unaffected. Similar but less pronounced effects were found after infusion of lesser amounts of bacteria. By means of inhibitor titrations of succinate: cytochrome-c-reductase, it was shown that the loss of activity is not caused by Complex III but by disturbances in Complex II. It is concluded that E. coli-induced
sepsis
causes decreased activities of Complex I and Complex II in baboon heart mitochondria in a dose-dependent manner.
...
PMID:Impaired energy metabolism in hearts of septic baboons: diminished activities of Complex I and Complex II of the mitochondrial respiratory chain. 1035 39
Cellular energy metabolism is altered in
sepsis
as a consequence of dysfunction of mitochondrial electron transport and glycolytic pathways. The purpose of the present study was to determine whether
sepsis
is associated with compensatory increases in gene expression of electron transport chain and glycolytic pathway proteins or, alternatively, whether gene expression decreases in
sepsis
, contributing to abnormalities in energy metabolism. Studies were performed using diaphragms from control and endotoxin-treated (8 mg x kg(-1) x day(-1)) rats; at 48 h after endotoxin administration, animals were killed. Microarrays and RNAse protection assays were used to assess the expression of several electron transport chain components (cytochrome-c oxidase subunits Cox 5A, Cox 5B, and Cox 6A, ATP synthase, and ATP synthase subunit 5B) and of the rate-limiting enzyme for glycolysis,
phosphofructokinase
(
PFK
). Western blotting was used to assess protein levels for these electron transport chain subunits and
PFK
. Activity assays were used to assess electron transport chain and
phosphofructokinase
function. We found that
sepsis
evoked 1) a downregulation of genes encoding all examined electron transport chain components (e.g., cytochrome-c oxidase 5A decreased 45 + 7%, P < 0.01) and
PFK
(P < 0.001), 2) reductions in protein levels for these electron transport chain subunits and
PFK
(P < 0.05 for each), and 3) decreases in mitochondrial state 3 respiration rates and
phosphofructokinase
enzyme activity (P < 0.01 for each comparison). We speculate that these
sepsis
-induced reductions in the expression of genes encoding critical electron transport and glycolytic proteins contribute to the development and persistence of
sepsis
-induced abnormalities in cellular energy metabolism.
...
PMID:Downregulation of diaphragm electron transport chain and glycolytic enzyme gene expression in sepsis. 1610 21
