UMLS:C0036690 - FACTA Search

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Query: UMLS:C0036690 (sepsis)
59,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

During the last years many investigations have shown that a major catalyst within the mechanism of skeletal muscle wasting occurring under conditions like sepsis, injuries, trauma, cancer cachexia, chronic acidosis, fasting, glucocorticoid treatment, and insulinopenia is the ubiquitin-proteasome system. Evidence for this was obtained by findings that the rate of ATP-dependent protein degradation is increased, that m-RNA concentrations of several proteasome subunits and ubiquitin are increased and the amount of ubiquitin-protein conjugates is elevated under these conditions. Additionally, the enhanced protein breakdown was shown to be suppressed by proteasome inhibitors. In the present report we show that most but not all of the proteolytic activities of partially purified 20S/26S proteasomes from skeletal muscle of rats increase after induction of Diabetes mellitus. This finding suggests that part of the mechanism of acceleration of muscle protein breakdown is due to changes in proteasome activities.
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PMID:Alterations of proteasome activities in skeletal muscle tissue of diabetic rats. 1036 52

Catabolism of lean body mass (particularly muscle) occurs in sepsis and other forms of critical illness despite apparently adequate nutritional support. The determination of the optimal balance of carbohydrate and fat intake in this circumstance should be based on the resulting effect on the maintenance of lean body mass, and the nature and extent of any side effects. The general stress response involves a disruption in normal glucoregulation, in that hepatic glucose production is accelerated and the normal blood glucose lowering action of insulin is diminished. Nonetheless, the capacity to oxidize glucose once inside the cells is not impaired. Lipolysis, or the breakdown of peripheral triglycerides to free fatty acids (FFA) and glycerol, is accelerated in critical illness, to a greater extent than fat oxidation. Provision of exogenous fat maintains fat stores, but has minimal effect on the direct oxidation of plasma FFA. From the results of oxidation studies, it seems that about 5 mg kg x min of glucose can be readily oxidized, and the balance of energy will be supplied by the oxidation of fat, either endogenous or exogenous. However, an additional consideration in determining the optimal caloric substrate is that insulin is a potent anabolic hormone and stimulates muscle protein synthesis. Consequently, provision of exogenous insulin enhances retention of muscle. This procedure dictates that almost all non-protein calories be provided as carbohydrate to avoid hypoglycemia. Preliminary studies suggest this may be the optimal approach in critically ill patients. Glucose and fatty acids are the major energy substrates in the body. The oxidative metabolism of these substrates provides the ATP needed for physiological function, including protein synthesis. Over the past 20 y, development of new techniques in nutritional support have made it possible to provide large amounts of carbohydrate and fat to critically-ill patients, along with protein or amino acids. However, despite providing such patients with what should be more than adequate caloric and protein intake, critically ill patients lose lean body mass (Streat et al, 1987), largely because of persistent muscle catabolism (Sakurai et al, 1995). The general relation between energy substrate metabolism and maintenance of lean body mass has been recognized for many years (Calloway & Spector, 1954), so it is important to examine the alterations in energy substrate metabolism that occur in response to critical illness that may play a role in causing the persistent catabolism of muscle protein.
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PMID:Sepsis as a modulator of adaptation to low and high carbohydrate and low and high fat intakes. 1036 91

The purpose of this article is to review evidence that the ubiquitin-proteasome proteolytic pathway plays an important role in injury- and sepsis-induced muscle catabolism. Such evidence includes upregulated gene expression of several of the components of the ubiquitin-proteasome pathway as well as energy-dependency of the injury- and sepsis-induced muscle protein breakdown. Although the ubiquitin-proteasome pathway is the predominant mechanism of muscle breakdown in various catabolic conditions, other proteolytic mechanisms, in particular calcium-dependent, calpain-mediated protein degradation, probably participate as well.
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PMID:Pathways of muscle protein breakdown in injury and sepsis. 1045 47

Glucocorticoids inhibit protein synthesis and stimulate protein degradation in skeletal muscle and are an important factor in the development of muscle atrophy in various catabolic conditions. Glucocorticoid-stimulated muscle protein breakdown is primarily caused by ubiquitin-proteasome-dependent proteolysis although calcium-dependent protein degradation may also be involved. In certain catabolic conditions, including sepsis, an interaction between glucocorticoids and proinflammatory cytokines is important for the stimulation of muscle protein breakdown.
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PMID:Glucocorticoids and muscle catabolism. 1045 48

We investigated the ability of pentoxifylline (PTX) to modulate protein synthesis and degradation in the presence and absence of insulin during incubation of epitrochlearis muscle, 2 or 6 days after injection of Escherichia coli. On days 2 and 6 after infection, protein synthesis was inhibited by 25%, whereas proteolysis was enhanced by 75%. Insulin (2 nM) in vitro stimulated protein synthesis in muscles from infected rats to the same extent as in controls. The ability of insulin to limit protein degradation was severely blunted 48 h after infection. On day 6 after infection, insulin inhibited proteolysis to a greater extent than on day 2. PTX suppressed the increase in plasma concentrations of tumor necrosis factor more than 600-fold after injection of bacteria, and partially prevented the inhibition of protein synthesis and stimulation of protein degradation during sepsis. Moreover, PTX administration maintained the responsiveness of protein degradation to insulin during sepsis. Thus cytokines may influence skeletal muscle protein metabolism during sepsis, both indirectly through inhibition of the effects of insulin on proteolysis, and directly on the protein synthesis and degradation machinery.
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PMID:Pentoxifylline improves insulin action limiting skeletal muscle catabolism after infection. 1049 2

Insulin deficiency (e.g., in acute diabetes or fasting) is associated with enhanced protein breakdown in skeletal muscle leading to muscle wasting. Because recent studies have suggested that this increased proteolysis is due to activation of the ubiquitin-proteasome (Ub-proteasome) pathway, we investigated whether diabetes is associated with an increased rate of Ub conjugation to muscle protein. Muscle extracts from streptozotocin-induced insulin-deficient rats contained greater amounts of Ub-conjugated proteins than extracts from control animals and also 40-50% greater rates of conjugation of (125)I-Ub to endogenous muscle proteins. This enhanced Ub-conjugation occurred mainly through the N-end rule pathway that involves E2(14k) and E3alpha. A specific substrate of this pathway, alpha-lactalbumin, was ubiquitinated faster in the diabetic extracts, and a dominant negative form of E2(14k) inhibited this increase in ubiquitination rates. Both E2(14k) and E3alpha were shown to be rate-limiting for Ub conjugation because adding small amounts of either to extracts stimulated Ub conjugation. Furthermore, mRNA for E2(14k) and E3alpha (but not E1) were elevated 2-fold in muscles from diabetic rats, although no significant increase in E2(14k) and E3alpha content could be detected by immunoblot or activity assays. The simplest interpretation of these results is that small increases in both E2(14k) and E3alpha in muscles of insulin-deficient animals together accelerate Ub conjugation and protein degradation by the N-end rule pathway, the same pathway activated in cancer cachexia, sepsis, and hyperthyroidism.
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PMID:Ubiquitin conjugation by the N-end rule pathway and mRNAs for its components increase in muscles of diabetic rats. 1056 3

Wasting of skeletal muscle protein is a prominent feature of the metabolic response to sepsis. Persistent protein wasting leads to muscle dysfunction and prolongs recovery from the septic insult. Unfortunately, conventional nutritional support alone does not prevent the sepsis-induced weight loss and catabolism of muscle. Hence, mechanisms other than substrate deficiency appear to be involved in the derangements in protein metabolism during sepsis. The catabolism of muscle during sepsis results from a stimulation of proteolysis and an inhibition of protein synthesis. Despite the importance of these pathways in maintaining muscle mass, the regulation of protein synthesis and proteolysis during sepsis remains poorly understood. This review summarizes the mechanisms responsible for alterations in protein synthesis and degradation in muscle during sepsis at the biochemical level. The ability of hormones (insulin, insulin-like growth factor I, glucocorticoids) or cytokines (tumor necrosis factor, interleukin-1) to act as mediators or modulators of protein catabolism is also examined. A picture is emerging suggesting that cytokines may influence skeletal muscle protein metabolism during sepsis both indirectly, through inhibition of the regulatory actions of anabolic hormones on protein turnover, and directly, through modulation of the protein synthesis and degradation enzymatic machinery.
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PMID:Regulation of skeletal muscle protein turnover during sepsis. 1056 51

Sepsis-induced muscle proteolysis mainly reflects ubiquitin-proteasome-dependent protein degradation. The effect of in vivo administration of a proteasome inhibitor on muscle protein breakdown during sepsis is not known. We treated rats with the proteasome inhibitor N-benzyloxycarbonyl-Ile-Glu-(O-t-butyl)-Ala-leucinal (PSI) or corresponding volume of vehicle i.p. 2 h before sham-operation or induction of sepsis by cecal ligation and puncture. The sepsis-induced increase in total and myofibrillar muscle protein breakdown was inhibited in rats treated in vivo with PSI and a maximal effect was seen following 15 mg/kg of the proteasome inhibitor. Results from in vitro experiments in which incubated muscles were treated with 100 microM PSI suggest that the drug has a direct effect on muscle and that the effect is specific for the proteasome. The results are important because they suggest that it may be possible to prevent or improve the cachectic response in skeletal muscle during sepsis by treatment with a proteasome inhibitor.
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PMID:Sepsis-induced muscle proteolysis is prevented by a proteasome inhibitor in vivo. 1073 30

Three tracer methods have been used to measure protein synthesis, protein breakdown and protein oxidation at whole-body level. The method using L-[1-(13)C]leucine is considered the method of reference. These methods have contributed greatly to the existing knowledge on whole-body protein turnover and its regulation by feeding, fasting, hormones and disease. How exercise and ingestion of mixed protein-containing meals affect whole-body protein metabolism is still open to debate, as there are discrepancies in results obtained with different tracers. The contribution of whole-body methods to the future gain of knowledge is expected to be limited due to the fact that most physiological disturbances have been investigated extensively, and due to the lack of information on the relative contribution of various tissues and proteins to whole-body changes. Tracer amino acid-incorporation methods are most suited to investigate these latter aspects of protein metabolism. These methods have shown that some tissues (liver and gut) have much higher turnover rates and deposit much more protein than others (muscle). Massive differences also exist between the fractional synthesis rates of individual proteins. The incorporation methods have been properly validated, although minor disagreements remain on the identity of the true precursor pool (the enrichment of which should be used in the calculations). Arterio-venous organ balance studies have shown that little protein is deposited in skeletal muscle following a protein-containing meal, while much more protein is deposited in liver and gut. The amount deposited in the feeding period in each of these tissues is released again during overnight fasting. The addition of tracers to organ balance studies allows the simultaneous estimation of protein synthesis and protein breakdown, and provides information on whether changes in net protein balance are caused primarily by a change in protein synthesis or in protein breakdown. In the case of a small arterio-venous difference in a tissue with a high blood flow, estimates of protein synthesis and breakdown become very uncertain, limiting the value of using the tracer. An additional measurement of the intracellular free amino acid pool enrichment allows a correction for amino acid recycling and quantification of the inward and outward transmembrane transport. However, in order to obtain reliable estimates of the intramuscular amino acid enrichment and, therefore, of muscle protein synthesis and breakdown in this so-called three-pool model, the muscle should be freeze-dried and the resulting fibres should be freed from connective tissue and small blood clots under a dissection microscope. Even when optimal precautions are taken, the calculations in these tracer balance methods use multiple variables and, therefore, are bound to lead to more variability in estimates of protein synthesis than the tracer amino acid incorporation methods. In the future, most studies should focus on the measurement of protein synthesis and breakdown in specific proteins in order to understand the mechanisms behind tissue adaptation in response to various stimuli (feeding, fasting, exercise, trauma, sepsis, disuse and disease). The tracer laboratories, therefore, should improve the methodology to allow the measurement of low tracer amino acid enrichments in small amounts of protein.
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PMID:Tracers to investigate protein and amino acid metabolism in human subjects. 1081 67

We examined the effect of insulin-like growth factor I (IGF-I), administered in vivo, on protein turnover rates and gene expression of the ubiquitin-proteasome proteolytic pathway in skeletal muscle of septic rats. Sepsis was induced by cecal ligation and puncture. Other rats were sham-operated. Miniosmotic pumps were implanted sc, and groups of rats received IGF-I (7 mg/kg x 24 h) or saline. Protein synthesis and breakdown rates were determined in incubated extensor digitorum longus muscles. Messenger RNA levels for ubiquitin and the ubiquitin-conjugating enzyme E2(14k) were determined by Northern blot analysis. Sepsis resulted in an approximately 30% reduction of muscle protein synthesis, and this effect of sepsis was blunted in rats treated with IGF-I. In contrast, IGF-I did not prevent the sepsis-induced increase in total and myofibrillar muscle protein breakdown. Ubiquitin and E2(14k) messenger RNA levels were increased several fold in muscle from septic rats, and this effect of sepsis was abolished in IGF-I treated rats. The results suggest that administration of IGF-I may improve sepsis-induced muscle cachexia by stimulating protein synthesis. However, because muscles were resistant to IGF-I, with regard to regulation of protein breakdown, the use of IGF-I to treat muscle cachexia during sepsis remains unclear. An additional important implication of the present study is that changes in messenger RNA levels for ubiquitin and the ubiquitin-conjugating enzyme E2(14k) do not always reflect changes in muscle protein breakdown rates.
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PMID:Insulin-like growth factor I reduces ubiquitin and ubiquitin-conjugating enzyme gene expression but does not inhibit muscle proteolysis in septic rats. 1091 58

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