The effect of interleukin-1 alpha and the glucocorticoid receptor blocker RU 38486 on total and myofibrillar protein breakdown in skeletal muscle

The purpose of the present study was to test the hypothesis that muscle proteolysis induced by interleukin-1 alpha (IL-1 alpha) is mediated by glucocorticoids. Male Sprague-Dawley rats, weighing 40-60 g, were treated with recombinant IL-1 alpha (rIL-1 alpha), 300 micrograms/kg in three divided intraperitoneal doses over 16 hr, or corresponding control injections. Groups of rats received the glucocorticoid receptor blocker RU 38486 by gavage (15 mg/kg in three divided doses over 16 hr) or were subjected to sham-gavage. In other experiments we tested the effectiveness of the same dose of RU 38486 to block muscle proteolysis in rats treated with corticosterone (200 mg/kg in two divided doses over 16 hr). Total and myofibrillar protein breakdown rates in incubated extensor digitorum longus muscles were determined by measuring release of tyrosine and 3-methylhistidine, respectively. Administration of rIL-1 alpha increased total and myofibrillar protein breakdown by 49 and 134%, respectively. This effect of the cytokine was not affected by RU 38486. The same dose of RU 38486, however, completely blocked the increase in total and myofibrillar protein breakdown induced by corticosterone. The results suggest that muscle proteolysis induced by the administration of rIL-1 alpha is not mediated by glucocorticoids.     

Is the metabolic response to sepsis in skeletal muscle different in infants and adults? An experimental study in rats.

In this study we compared the effect of sepsis on muscle protein metabolism in infant (3 to 4 weeks) and adult (3 to 4 months) rats. Sepsis was induced by cecal ligation and puncture (CLP). Control animals underwent sham operation. Sixteen hours after CLP or sham operation, metabolic studies were performed in incubated intact extensor digitorum longus muscles from infant rats or in strips of the same muscle from adult rats. Protein synthesis rate was determined as incorporation of 3H-phenylalanine into protein; total and myofibrillar protein breakdown rates were determined as release of tyrosine and 3-methylhistidine, respectively. Mortality rate following CLP was similar in both age groups. Basal protein synthesis rate was 3 times higher, total protein breakdown rate was 50% higher, and myofibrillar protein breakdown rate was 3 times higher in infant than in adult animals. However, the relative changes in protein turnover rates induced by sepsis were similar in infant and adult rats: protein synthesis rate decreased by approximately 30%, total protein breakdown increased by 40% to 50%, and myofibrillar protein breakdown increased severalfold. The data suggest that despite prominent differences in basal protein turnover rates between infant and adult rats, the effect of sepsis on muscle protein metabolism is not age dependent.     

Corticosterone alone does not explain increased muscle proteolysis in septic rats

The mediators and mechanisms of muscle proteolysis in sepsis are not fully known. We investigated the role of corticosterone in increased muscle proteolysis during sepsis in rats. In one series of experiments, plasma corticosterone and total and myofibrillar protein breakdown rates, determined in incubated extensor digitorum longus muscles as release of tyrosine and 3-methylhistidine, respectively, were measured 16 hr after sham operation (control) or cecal ligation and puncture (sepsis). In other experiments, corticosterone (10 mg/100 g body wt) was injected subcutaneously twice over 16 hr; thereafter, plasma hormone levels and muscle protein breakdown rates were determined. Plasma corticosterone was increased from 14 +/- 1 micrograms/dl in control rats to 38 +/- 8 micrograms/dl in septic rats and total and myofibrillar protein breakdown rates were increased by 99 and 326%, respectively, in muscles from septic rats. When administration of corticosterone resulted in plasma levels similar to those observed in septic rats, total or myofibrillar protein breakdown rates were not altered. The results suggest that corticosterone alone is not responsible for increased muscle proteolysis in septic rats. The data, however, do not rule out the possibility that glucocorticoids may be a cofactor to some other substance or substances in the induction of muscle proteolysis during sepsis.     

Evidence for reduced catabolism by the antiglucocorticoid RU 38486 in acutely uremic rats

Previous studies suggested that increased blood levels of, or increased tissue sensitivity to, glucocorticoids may contribute to catabolism in acute uremia. To examine this possibility we determined urea nitrogen (urea-N) appearance, plasma levels of Nt-methylhistidine and the activity of the alkaline myofibrillar proteinase in acutely uremic rats with and without treatment with RU 38486, a selective antiglucocorticoid. Forty-eight hours after bilateral nephrectomy, the rats had markedly elevated serum levels of urea-N, creatinine, potassium and phosphorus. In uremic rats receiving RU 38486, comparable levels of serum creatinine were found, but the serum levels of urea-N (221 +/- 4 vs. 259 +/- 5 mg/dl) and phosphorus (6.5 +/- 0.3 vs. 8.5 +/- 0.4 mmol/l) were significantly decreased as compared to uremic animals without RU 38486. In comparison to sham-operated rats, urea-N appearance (net urea production) was increased by 56% 48 h after bilateral nephrectomy. This increment was almost completely reversed in uremic animals receiving the antiglucocorticoid. In untreated uremic rats, plasma levels of Nt-methylhistidine were 10.3 +/- 0.9 microgram/dl, whereas the administration of RU 38486 caused a significant decline in the levels of this amino acid (7.6 +/- 0.5 microgram/dl). This reduction in Nt-methylhistidine was associated with a concomitant decrease of myofibrillar proteinase activity in muscle tissue homogenates. Compared to sham-operated animals, this proteinase activity was increased by 30% in uremic rats, but was normal in those given RU 38486. Taken together, these data support the view that in acute uremia accelerated ureagenesis occurs, while enhanced muscle protein breakdown, owing to an increment in myofibrillar proteinase activity, provides the necessary amino acid precursors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein metabolism in different types of skeletal muscle during early and late sepsis in rats

Protein synthesis and degradation rates were measured in incubated soleus (SOL) and extensor digitorum longus (EDL) muscles 4, 8, and 16 hours following cecal ligation and puncture (CLP) in rats. No significant differences in protein synthesis between septic and control rats were found. The proteolytic rate in SOL muscle was increased by 36% eight hours after CLP and by 42% 16 hours after CLP. In EDL muscle, protein breakdown was not significantly increased until 16 hours after CLP, at which time it was 53% above the control value. The plasma amino acid pattern became increasingly deranged during the course of the study, and at 16 hours almost all individual amino acid levels were significantly different in septic rats compared with control rats. There was a significant positive correlation between plasma concentrations of phenylalanine, histidine, and ornithine and the proteolytic rate in EDL and SOL muscles, with the best correlation being found between phenylalanine concentration and proteolytic rate in SOL muscle. These results suggest that muscle wasting during sepsis is caused by increased protein breakdown, not by decreased protein synthesis, and that accelerated muscle proteolysis is an early phenomenon in sepsis.     

Studies on the possible role of thyroid hormone in altered muscle protein turnover during sepsis.

Five days after thyroidectomy (Tx) or sham-Tx in young male Sprague-Dawley rats, sepsis was induced by cecal ligation and puncture (CLP). Control animals underwent laparotomy and manipulation of the cecum without ligation or puncture. Sixteen hours after CLP or laparotomy, protein synthesis and degradation were measured in incubated extensor digitorum longus (EDL) and soleus (SOL) muscles by determining rate of 14C-phenylalanine incorporation into protein and tyrosine release into incubation medium, respectively. Triiodothyronine (T3) was measured in serum and muscle tissue. Protein synthesis was reduced by 39% and 22% in EDL and SOL, respectively, 16 hours after CLP in sham-Tx rats. The response to sepsis of protein synthesis was abolished in Tx rats. Protein breakdown was increased by 113% and 68% in EDL and SOL, respectively, 16 hours after CLP in sham-Tx animals. The increase in muscle proteolysis during sepsis was blunted in hypothyroid animals and was 42% and 49% in EDL and SOL, respectively. T3 in serum was reduced by sepsis, both in Tx and sham-Tx rats. T3 in muscle, however, was maintained or increased during sepsis. Abolished or blunted response of muscle protein turnover after CLP in hypothyroid animals may reflect a role of thyroid hormones in altered muscle protein metabolism during sepsis. Reduced serum levels of T3, but maintained or increased muscle concentrations of the hormone, suggests that increased T3 uptake by muscle may be one mechanism of low T3 syndrome in sepsis, further supporting the concept of a role for thyroid hormone in metabolic alterations in muscle during sepsis.     

Effect of indomethacin on proteolysis in septic muscle.

The effect of indomethacin on protein degradation in skeletal muscle from septic rats was investigated. Sepsis was induced by cecal ligation and puncture (CLP). Control rats were sham-operated. Protein degradation rate was estimated by measuring release of tyrosine from incubated soleus (SOL) and extensor digitorum longus (EDL) muscles. Three experiments were performed. In the first experiment, indomethacin was administered subcutaneously (3 mg/kg) at the time of CLP and again after 3 hours. Control rats received corresponding volumes of solvent. Groups of rats were studied after 8 hours (early sepsis) or 16 hours (late sepsis). In the second experiment, the animals were pretreated 45 minutes before induction of sepsis with indomethacin (3 mg/kg) and again 3 hours after CLP and were studied during early sepsis. In the third experiment, indomethacin was added in vitro (3 microM) to incubated normal or septic muscle or to normal muscle incubated in the presence of plasma from septic animals, and release of prostaglandin E2 (PGE2) by incubated muscle was measured in addition to protein degradation. There was no mortality in early sepsis. Survival rate 16 hours after CLP was 8/16 (50%) in rats receiving control injections and 7/15 (47%) in indomethacin-treated rats (NS). Proteolytic rate in incubated EDL and SOL was increased by 20-25% during early sepsis and by 30-50% during late sepsis. The increased proteolytic rate was not affected by administration of indomethacin, neither in the first nor in the second experiment. When indomethacin was added in vitro, release of PGE2 by septic muscles and by normal muscles incubated in the presence of septic plasma was reduced by about 50%, but the increased proteolytic rate in these muscles was not affected. In normal muscle, neither release of PGE2 nor protein degradation was affected by indomethacin in vitro. The present results do not support a role for prostaglandins in the enhancement of muscle proteolysis during sepsis. Since neither survival rate nor protein breakdown was affected by indomethacin, recent suggestions to use this substance in the treatment of septic patients might be questioned.     

Evidence that tumor necrosis factor participates in the regulation of muscle proteolysis during sepsis.

The role of tumor necrosis factor (TNF) in the regulation of muscle protein turnover was studied in rats. Protein synthesis and total and myofibrillar protein breakdown rates were measured in incubated extensor digitorum longus muscles. Intraperitoneal administration of recombinant TNF-alpha (300 micrograms/kg of body weight) increased total and myofibrillar protein breakdown rates by 28% and threefold, respectively, with no effect on protein synthesis. In subsequent experiments, sepsis was induced by cecal ligation and puncture or a sham-operation was performed. Rats received TNF antiserum (1 mL/100 g of body weight) or control serum 2 hours before cecal ligation and puncture or sham-operation. Treatment with TNF antiserum reduced the mortality rate from 25% to 5% following cecal ligation and puncture. The treatment had no effect on protein synthesis but reduced total and myofibrillar protein breakdown rates by 26% and 39%, respectively, in septic animals. Results suggest TNF is involved in the regulation of sepsis-induced muscle proteolysis.     

Effect of sepsis on calcium uptake and content in skeletal muscle and regulation in vitro by calcium of total and myofibrillar protein breakdown in control and septic muscle: results from a preliminary study

Because high calcium concentration in vitro stimulates muscle proteolysis, calcium has been implicated in the pathogenesis of increased muscle breakdown in different catabolic conditions. Protein breakdown in skeletal muscle is increased during sepsis, but the effect of sepsis on muscle calcium uptake and content is not known. In this study the influence of sepsis, induced in rats by cecal ligation and puncture, on muscle calcium uptake and content was studied. Sixteen hours after cecal ligation and puncture or sham operation, calcium content of the extensor digitorum longus (EDL) and soleus (SOL) muscles was determined with an atomic absorption spectrometer. Calcium uptake was measured in intact SOL muscles incubated in the presence of calcium 45 (45Ca) for between 1 and 120 minutes. Total and myofibrillar protein breakdown was determined in SOL muscles, incubated in the presence of different calcium concentrations (0; 2.5; 5.0 mmol/L), and measured as release into the incubation medium of tyrosine and 3-methylhistidine (3-MH), respectively. Calcium content was increased by 51% (p less than 0.001) during sepsis in SOL and by 10% (p less than 0.05) in EDL muscle. There was no difference in 45Ca uptake between control and septic muscles during the early phase (1 to 5 minutes) of incubation. During more extended incubation (30 to 120 minutes), muscles from septic rats took up significantly more 45Ca than control muscles (p less than 0.05). Tyrosine release by incubated SOL muscles from control and septic rats was increased when calcium was added to the incubation medium, and at a calcium concentration of 2.5 mmol/L, the increase in tyrosine release was greater in septic than in control muscle. Addition of calcium to the incubation medium did not affect 3-MH release in control or septic muscle. The results suggest that calcium uptake and content in skeletal muscle are increased during sepsis and that high calcium concentrations in vitro stimulate nonmyofibrillar protein breakdown. Muscles from septic animals may be more sensitive to the effect of calcium in vitro than muscles from nonseptic rats. Whether increased calcium uptake and content in skeletal muscle is partly responsible for accelerated muscle proteolysis during sepsis remains to be determined.     

糖皮质激素在烧伤脓毒症骨骼肌蛋白代谢中作用的研究

目的　探讨糖皮质激素在烧伤脓毒症骨骼肌蛋白代谢中的作用及其机制。　方法　大鼠随机分为 4组 ,每组 1 5只 :B组大鼠 30 %Ⅲ度烫伤后立即腹腔注射内毒素 6mg/kg,模拟烧伤脓毒症 ;C组于伤前 2h ,D组于伤后 2h分别使用糖皮质激素受体拮抗剂RU38486灌胃 (1 0mg/kg) ,余处理同B组 ;A组为假伤组 ,并使用等量的生理盐水替代内毒素。伤后 1 2h ,测定血浆皮质醇浓度 ,称重和离体有氧孵育伸趾长肌 ,高效液相色谱法测定肌组织蛋白降解率 ,Northern杂交检测伸趾长肌泛素、E2 1 4kDa和C2mRNA的表达变化。　结果　伸趾长肌重量 ,B组较A组明显降低 ,差异有显著意义 (t=9 0 3 ,P <0 0 1 ) ;而C组和D组虽然低于A组 ,但显著高于B组 ,差异有显著意义 (t=2 2 6 ,6 42 ,P <0 0 5或P <0 0 1 )。血浆皮质醇浓度 ,B ,C和D组都明显高于A组 ,差异有显著意义 (t=9 0 3 ,2 2 94,P <0 0 1 )。蛋白降解率 ,B组总蛋白和肌纤维蛋白降解率较A组分别升高 58 8% (2 1 0 / 357)和335 5 % (4 1 6/ 1 2 4 ) ,差异有显著意义 (t=36 99和t=46 1 9,P <0 0 1 ) ;C组总蛋白和肌纤维蛋白降解率较B组分别减少 2 8 3 % (1 61 / 567)和 49 6 % (2 68/ 5 40 ) ,D组较B组分别减少 1 8 9% (1 0 8/ 567)和2 3 2 % (1 2 5/ 5 40 ) ,差异有显著     

Is there a circulating proteolysis-inducing factor during sepsis?

Muscles from fed or 72-hour fasted rats were incubated in the presence of plasma from septic rats, recombinant interleukin 1 alpha (rIL-1 alpha), or recombinant tumor necrosis factor alpha (rTNF alpha), and breakdown of total and myofibrillar protein was assessed by determining release of tyrosine and 3-methylhistidine, respectively. Septic plasma stimulated total protein breakdown in muscles from 72-hour fasted rats by 10% to 20%, while myofibrillar protein breakdown was not affected. When septic plasma was added to muscles from fed rats, neither tyrosine nor 3-methylhistidine release was altered. Various concentrations of recombinant interleukin 1 alpha or recombinant tumor necrosis factor alpha did not affect total or myofibrillar protein breakdown. Since septic plasma did not stimulate myofibrillar protein breakdown, the role of a circulating factor for muscle proteolysis during sepsis remains unclear.     

Increased synthesis of secreted hepatic proteins during abdominal sepsis

To study the effect of intraabdominal sepsis on hepatic protein synthesis, male Sprague-Dawley rats underwent celiotomy with either cecal ligation and puncture (CLP) or sham operation. Eight and sixteen hours later total hepatic protein synthesis was measured by flooding dose technique. Specific synthetic rates of structural or secreted hepatic proteins were further studied 16 hr after CLP in an isolated perfused liver model. Total hepatic protein synthesis was significantly elevated at 16 hr (59 +/- 6%/day vs 37 +/- 6%/day, P less than 0.05), but not 8 hr post-CLP. Structural hepatic protein synthesis was unchanged after CLP; however, the synthetic rates of the acute-phase secretory proteins alpha 1-acid glycoprotein, transferrin and complement component C3 were significantly increased 16 hr after CLP. However, the albumin synthetic rate was not increased during sepsis. We conclude that sepsis causes augmentation of hepatic protein synthesis primarily to increase acute-phase proteins for host defense.     

Sepsis increases the plasma membrane content of alpha1 and alpha2 isoforms of Na+-K+ adenosine triphosphatase in rat skeletal muscle

HYPOTHESIS: Increased Na(+)-K(+) adenosine triphosphatase (ATPase) activity in skeletal muscle during sepsis is caused by transient increases in enzyme content within the plasma membrane. DESIGN: Randomized controlled study. SETTING: University laboratory. INTERVENTION: Eighty-eight adult male Wistar rats were randomly assigned to undergo cecal ligation and puncture (CLP) or sham operation. MAIN OUTCOME MEASURES: Gastrocnemius muscles were harvested 6, 12, 24, and 48 hours after operation and Na(+)-K(+) ATPase activities were measured spectrofluorimetrically. Messenger RNA (mRNA) levels for the alpha1 and alpha2 isoforms of Na(+)-K(+) ATPase were determined by Northern blot analysis. Crude membranes, internal membranes, and purified plasma membranes were isolated from gastrocnemius muscles and protein levels of alpha1 and alpha2 isoforms were determined by Western blot analysis. RESULTS: Na(+)-K(+) ATPase activity in the CLP group was significantly higher compared with the sham group 24 hours after operation (P<.05). However, there were no differences between the sham and CLP groups 6, 12, or 48 hours after operation. No significant differences between the CLP and sham groups were noted in mRNA levels for Na(+)-K(+) ATPase alpha1 and alpha2 isoforms. Western blot analysis revealed that the plasma membrane (but not internal membrane or crude membrane) content of alpha2 and alpha1 isoforms from the CLP group was significantly increased compared with the sham group 24 hours after operation (P<.05). CONCLUSIONS: Na(+)-K(+) ATPase activity increases 24 hours after CLP in gastrocnemius muscle and then declines. This increase is caused by increased Na(+)-K(+) ATPase protein levels in the plasma membrane.     

Interaction between corticosterone and tumor necrosis factor stimulated protein breakdown in rat skeletal muscle, similar to sepsis

Protein synthesis and breakdown rates were determined in incubated extensor digitorum longus muscles of rats treated with tumor necrosis factor (TNF; 20 micrograms/100 gm body weight), corticosterone (20 mg/100 gm body weight), or a combination of the two substances. Protein synthesis was measured as incorporation of carbon 14-labeled phenylalanine into protein. Total and myofibrillar protein breakdown rates were assessed as release of tyrosine and 3-methylhistidine, respectively. Administration of TNF alone did not affect muscle protein turnover rates. Corticosterone inhibited muscle protein synthesis and stimulated total and myofibrillar protein breakdown. When TNF was administered together with corticosterone, total and myofibrillar protein breakdown rates were increased further compared with rats treated with corticosterone alone. Because plasma corticosterone levels in rats treated with both TNF and the glucocorticoid were higher than in animals treated with corticosterone alone, it is possible that muscle proteolysis noted after TNF, injected together with costicosterone, was caused by the high glucocorticoid levels. To test that hypothesis, corticosterone alone or in combination with TNF was injected in rats that had undergone adrenalectomy. In these experiments, TNF did not increase plasma corticosterone levels or muscle protein breakdown rates. The results suggest that muscle catabolism induced by administration of TNF is mediated by glucocorticoids.     

Further evidence that accelerated muscle protein breakdown during sepsis is not mediated by prostaglandin E2.

Prostaglandin E2 (PGE2) reportedly increases protein break-down in skeletal muscle. The role of PGE2 for accelerated muscle proteolysis during sepsis, however, is controversial. In this study, the effect of the prostaglandin synthesis inhibitor indomethacin on PGE2 release and protein breakdown in skeletal muscle from nonseptic and septic rats was evaluated. Sepsis was induced in male Sprague-Dawley rats (40-60 g) by cecal ligation and puncture (CLP). After 16 hours the extensor digitorum longus (EDL) and soleus (SOL) muscles were dissected with intact tendons and incubated in an oxygenated medium, and the release of tyrosine (protein breakdown) and PGE2 into the incubation medium was determined. Paired muscles were incubated in the absence or presence of indomethacin (3 mumol/L or 6 mumol/L). In some experiments the effect of indomethacin was investigated in the presence of different concentrations of insulin (1, 10, or 100 mU/mL) since previous reports suggested an interaction between insulin and prostaglandins on protein turnover in skeletal muscle. In other experiments muscles were incubated in a flaccid or stretched state, which is known to influence the metabolic response to different substances. Protein breakdown rate was 0.210 +/- 0.013 and 0.492 +/- 0.025 mumol Tyr/g X 2 hours in EDL from nonseptic and septic rats, respectively (p less than 0.01). The corresponding values for SOL were 0.480 +/- 0.037 and 0.712 +/- 0.039 mumol Tyr/g X 2 hours (p less than 0.01). Addition of indomethacin to the incubation medium reduced PGE2 release from 29.1 +/- 3.1 to 6.8 +/- 0.7 ng/g X 2 hours in nonseptic SOL and from 50.6 +/- 10.4 to 5.6 +/- 0.7 ng/g X 2 hours in septic SOL. Protein breakdown rate in SOL and EDL from sham-operated or septic rats was unaffected by indomethacin, both when muscles were incubated in a flaccid or stretched state, and when they were incubated in the presence or absence of insulin. The present results do not suggest a role of PGE2 for accelerated muscle proteolysis in the present experimental septic model.     

Effects of indomethacin and leupeptin on muscle cathepsin B activity and protein degradation during sepsis

The roles of prostaglandins and lysosomal proteases in accelerated skeletal muscle proteolysis during sepsis are not yet fully understood. In this study rats received intraperitoneal injections of the prostaglandin synthesis inhibitor indomethacin (IND, 5.0 mg/kg), the lysosomal cathepsin B inhibitor leupeptin (LEU, 2.5 mg/kg), or normal saline 2 hr before cecal ligation and puncture (a model of intraabdominal sepsis) or sham-operation. The injections were repeated every 6 hr for a total of four doses. Sixteen hours after operation, intact extensor digitorum longus (EDL) muscles were harvested and cathepsin B activity was measured in one muscle. The contralateral muscle was incubated in oxygenated Krebs-Henseleit bicarbonate buffer containing glucose (10 mM) and cycloheximide (0.5 mM), and protein degradation rate was determined as the release of tyrosine into the incubation medium. Both muscle cathepsin B activity and protein degradation rate were higher in septic than in sham-operated rats. Treatment with IND or LEU significantly reduced the elevated cathepsin B activity in septic muscles, but failed to significantly alter muscle proteolysis. In nonseptic muscle, both cathepsin B activity and protein degradation rate were unaffected by the different types of treatment. The results suggest that although prostaglandins may influence muscle lysosomal protease activity, neither prostaglandins nor the lysosomal protease cathepsin B appear to be major regulators of accelerated muscle protein breakdown during sepsis.     

Complement regulatory protein CD59 involves c-SRC related tyrosine phosphorylation of the creatine transporter in skeletal muscle during sepsis

BACKGROUND: Myocellular creatine (Cr) uptake is predominantly governed by the creatine transporter (CreaT) and plays a pivotal role in skeletal muscle energy metabolism. The CreaT belongs to a neurotransmitter transporter family that is functionally regulated by protein tyrosine kinase induced tyrosine phosphorylation. Recently, complement regulatory protein CD59 has been found not only to protect host tissue from C5b-9 complex attack that occurs in sepsis but also to initiate the activation of Src family kinase and tyrosine phosphorylation of its downstream proteins. The purpose of this study was to determine the association between myocellular free Cr, c-Src related tyrosine phosphorylation of the CreaT, and CD59 during sepsis. METHODS: Male Sprague-Dawley rats (250 to 300 g) were randomized to undergo cecal ligation and puncture (CLP) or sham operation. Fast-twitch gastrocnemius muscles were harvested 24 hours after operation. Myocellular free Cr levels were measured by high-performance liquid chromatography. Combination of protein immunoprecipitation with Western blotting was used to assess tyrosine phosphorylation status of the CreaT and the association between CD59, c-Src, and CreaT. RESULTS: Myocellular free Cr levels were 70% greater after CLP. Tyrosine phosphorylation of the CreaT was significantly increased after CLP as compared to sham operation. Tyrosine phosphorylated c-Src (Tyr-416) in the CreaT-c-Src immune complex was 24% higher after CLP. Sepsis also increased protein expression of tyrosine phosphorylated c-Src (Tyr-416) or CreaT in the CD59-c-Src or CD59-CreaT complex by 20% or 30%, respectively. CONCLUSIONS: During sepsis, an increase in myocellular free Cr levels is associated with enhanced tyrosine phosphorylation of the CreaT, which is likely induced by active c-Src. CD59 is physically associated with both c-Src and CreaT, which suggests that CD59 may participate in the regulation of myocellular Cr metabolism via the CreaT during sepsis.     

Skeletal muscle proteolysis in rats with acute streptozocin-induced diabetes

Skeletal muscle proteolysis was studied in rats 1 day after induction of diabetes with 65 mg/kg streptozocin. An evisceration procedure, including functional hepatectomy-nephrectomy, was performed, and the rate of proteolysis in the remaining tissues, primarily skeletal muscles, was evaluated over 2 h. With cycloheximide to block protein synthesis, total protein breakdown was measured from the rate of rise in plasma tyrosine concentration. The rate of degradation of contractile (myofibrillar) protein was estimated from the rate of rise in plasma concentration of 3-methylhistidine released from the breakdown of actomyosin. Compared with nondiabetic control preparations, the total protein degradation rate was increased 30% by diabetes (P less than .001), and myofibrillar catabolism was accelerated by 60% (P less than .005). In diabetes, the increase in proteolysis was accompanied by reductions in circulating insulin to 25-50% of normal level, whereas food intake did not differ from control. Treatment of diabetic rats with exogenous insulin, including acute infusions postoperatively, completely reversed the proteolytic effects of diabetes. The findings demonstrate that the hypoinsulinemia of acute diabetes increases the catabolism of skeletal muscle protein and that the inhibitory effect of normal levels of insulin includes a specific action to restrain myofibrillar proteolysis.     

Plasma alpha-glutathione S-transferase: a sensitive indicator of hepatocellular damage during polymicrobial sepsis

HYPOTHESIS: Since studies have found the liver enzyme alpha-glutathione S-transferase (alphaGST) to be a marker of hepatic injury after hemorrhagic shock, alphaGST also may serve as a sensitive indicator of hepatocellular damage during the early stage of polymicrobial sepsis. DESIGN, INTERVENTIONS, AND MAIN OUTCOME MEASURES: Male adult rats were subjected to the cecal ligation and puncture (CLP) model of polymicrobial sepsis or sham operation, followed by fluid resuscitation with isotonic sodium chloride solution. Systemic blood samples were taken at 2, 5, 10, or 20 hours after CLP or sham operation. Plasma levels of alphaGST and lactate were determined using an enzyme immunoassay and enzymatic assay, respectively. Additional animals were examined for morphologic alterations in liver ultrastructure of septic animals using electron microscopy. RESULTS: A similar level of alphaGST (mean +/- SEM, 30.5 +/- 3.5 microg/L) was found in the sham group at all measured time points. Although plasma levels of alphaGST did not change at 2 hours after CLP, they were elevated by 249% at 5 hours after the onset of sepsis and continued to increase throughout the septic course. Plasma lactate levels were significantly increased only at 20 hours after CLP (P<.001). Previous studies have shown that liver transaminase levels did not increase at 5 hours, but at 10 and 20 hours after CLP. In addition, electron microscopy revealed structural changes in hepatocyte morphology at 5 and 20 hours after CLP that were indicative of hepatocellular injury. CONCLUSION: Since plasma alphaGST levels increased earlier than plasma lactate and liver transaminase levels, alphaGST may be a more sensitive indicator of early liver injury and should be used in monitoring hepatocellular damage during the progression of sepsis.     

Effect of catabolic hormone infusion on protein turnover and amino acid uptake in skeletal muscle

Increased plasma levels of the catabolic hormones glucagon, epinephrine, and cortisol have been implicated in mediating various metabolic alterations in trauma and sepsis. Their role in altered protein turnover and amino acid transport in skeletal muscle during sepsis, however, is not known. In the current study, rats were infused with a mixture of the catabolic hormones for 16 hours. Control animals were infused with vehicle solution. Protein synthesis and degradation rates were measured in incubated, intact soleus muscles as incorporation of 14C-phenylalanine into protein and release of tyrosine into incubation medium, respectively. Muscle amino acid uptake was determined by measuring the intracellular to extracellular ratio of [3H]-alpha-aminoisobutyric acid after incubation for 2 hours. Infusion of catabolic hormones for 16 hours resulted in elevated plasma glucose and lactate levels, reduced plasma concentrations of most amino acids, and accelerated muscle protein breakdown, similar to previous findings in septic rats. Protein synthesis rates and amino acid uptake in incubated muscles were not significantly different in control and hormone-infused rats. The current study suggests that increased muscle proteolysis in sepsis and severe injury may be mediated in part by catabolic hormones. In contrast, reduced muscle protein synthesis and amino acid uptake are probably signaled by other substances or mechanisms.