Alcohol myopathy: impairment of protein synthesis and translation initiation.

Alcohol consumption leads to numerous morphological, biochemical and functional changes in skeletal and cardiac muscle. One such change observed in both tissues after either acute alcohol intoxication or chronic alcohol consumption is a characteristic decrease in the rate of protein synthesis. A decrease in translation efficiency appears to be responsible for at least part of the reduction. This review highlights advances in determining the molecular mechanisms by which alcohol impairs protein synthesis and places these observations in context of earlier studies on alcoholic myopathy. Both acute and chronic alcohol administration impairs translational control by modulating various aspects of peptide-chain initiation. Moreover, this alcohol-induced impairment in initiation is associated with a decreased availability of eukaryotic initiation factor (eIF) 4E in striated muscle, as evidenced by an increase in the amount of the inactive eIF4E.4E-BP1 complex and decrease in the active eIF4E.eIF4G complex. In contrast, alcohol does not produce consistent alterations in the control of translation initiation by the eIF2 system. The etiology of these changes remain unresolved. However, defects in the availability or effectiveness of various anabolic hormones, particularly insulin-like growth factor-I, are consistent with the alcohol-induced decrease in protein synthesis and translation initiation.

Amrinone prevents the inhibition of muscle pyruvate dehydrogenase complex activity during sepsis.

A decreased proportion of active pyruvate dehydrogenase complex (PDH) in skeletal muscle has been implicated as an important factor in elevating plasma lactate concentrations in hypermetabolic sepsis. The mediators of the septic process responsible for the inhibition of PDH complex in muscle are unknown. To assess the role of tumor necrosis factor in mediating the effects of sepsis, the effect of daily injections of amrinone (5 mg/kg/day), which inhibits the release of tumor necrosis factor during sepsis, on the proportion of PDH in the active form (PDHa) was investigated in a model of chronic hypermetabolic sepsis. In skeletal muscle from untreated septic rats, PDHa was decreased 50%. Treatment of septic rats with amrinone for 5 days prevented the sepsis-induced decrease in PDHa. Sepsis caused a 2.5-fold elevation in plasma lactate concentrations. The maintenance of the PDH complex activity at control values following injection of amrinone in septic rats was associated with reduced lactate concentrations in plasma. Thus, amrinone prevented the sepsis-induced abnormalities in skeletal muscle PDH activity and plasma lactate concentrations.

Sepsis-induced alterations in pyruvate dehydrogenase complex activity in rat skeletal muscle: effects on plasma lactate.

The pyruvate dehydrogenase (PDH) complex undergoes reversible phosphorylation catalyzed by a PDH kinase (inactivating) and a PDH phosphatase (activating). In skeletal muscle, a decreased proportion of PDH complex in the active, nonphosphorylated form (PDHa) limits glucose oxidation and promotes the conversion of pyruvate to lactate. Increased lactate formation with the accompanying hyperlactatemia is a frequent metabolic complication of sepsis. The time course for inactivation of the PDH complex in skeletal muscle during sepsis was contrasted with changes in PDHa during sterile inflammation 3,7, or 14 days following the implantation of the foreign body nidus. Total PDH complex activity was not altered in any of the conditions examined. Sepsis, but not sterile inflammation, caused a reduction in the muscle PDHa measured 3 or 7 days following induction of sepsis. The inhibition of the muscle PDHa during sepsis was associated with a sustained hyperlactatemia. PDH kinase activity measured in extracts of mitochondria was enhanced twofold during this period. Fourteen days after induction of sepsis, there were no differences in the PDHa or plasma lactate concentrations in septic rats compared with either control or sterile inflammation. Furthermore, the PDH kinase activity was decreased to values observed in control values. The results are consistent with the hypothesis that a reduced PDHa in skeletal muscle during sepsis is responsible, in part, for the hyperlactatemia characteristic of septic hypermetabolism. Furthermore, the results provide evidence that the decrease in PDHa results from a stable stimulation of PDH kinase activity.

Mechanisms regulating skeletal muscle glucose metabolism in sepsis.

Carbohydrate dyshomeostasis is a characteristic feature of sepsis. Sepsis elevates glucose uptake and cellular lactate levels in muscle. The mechanisms responsible for these alterations are unknown. We examined the effects of a chronic, intra-abdominal septic abscess upon glucose uptake, the expression of the insulin receptor, glucose transporter proteins (Glut-1 and Glut-4) and mRNA, and the content of glycolytic intermediates in muscle from the hindlimb. Sepsis caused a 67% increase in glucose uptake compared with control. A differential expression of the Glut-1 and Glut-4 transporter proteins in skeletal muscle of septic rats was observed. Sepsis increased the expression of Glut-1 protein 1.7-fold. The increased Glut-1 protein correlated with a similar increase in the relative abundance of Glut-1 mRNA. In contrast, sepsis did not alter the amount of Glut-4 protein and mRNA or insulin receptor protein. The tissue content of glucose-6-phosphate was increased approximately twofold compared with control. The increase in the glucose-6-phosphate content was not associated with increased glycogen deposition in skeletal muscle of septic animals. Analysis of the glycolytic intermediates showed that only the lactate content of muscles from septic rats was significantly elevated in sepsis. The results are consistent with the hypothesis that sepsis enhances glucose uptake secondary to increased Glut-1 expression. Furthermore, once transported, glucose may be preferentially metabolized to lactate.

Regulation of skeletal muscle protein turnover during sepsis: mechanisms and mediators.

Skeletal muscle protein wasting 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. 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 of protein catabolism is also examined. Finally, we discuss the potential role of anticytokine therapies in preventing derangements in protein metabolism during sepsis. A picture is emerging which suggests 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.

Modulation of skeletal muscle lactate metabolism following bacteremia by insulin or insulin-like growth factor-I: effects of pentoxifylline.

Hyperlactatemia is a frequent complication of sepsis. We investigated the effect of pentoxifylline on plasma lactate concentrations and lactate release by epitrochlearis incubated in vitro following intravenous injection of Escherichia coli. Plasma lactate concentrations were elevated on day 2 postinfection and remained elevated for at least another 4 days. Lactate production by incubated epitrochlearis was not increased in septic rats on day 2 postinfection, and lactate production from muscles incubated with insulin (2 nM) or insulin-like growth factor-I, (10 nM) was similar in control and septic rats. On day 6 postinfection, lactate production was augmented 1.8-fold in muscles from septic rats and both insulin and IGF-I caused an exaggerated stimulation of lactate production compared with control. Pentoxifylline decreased plasma TNF concentrations 100-fold following injection of bacteria and prevented the sepsis-induced hyperlactatemia and increase in lactate production by incubated muscles in presence or absence of insulin or IGF-I. Thus, pentoxifylline prevented the sepsis-induced abnormalities in skeletal muscle lactate production and plasma lactate concentrations.

Sepsis inhibits synthesis of myofibrillar and sarcoplasmic proteins: modulation by interleukin-1 receptor antagonist.

The breakdown of myofibrillar and sarcoplasmic (nonmyofibrillar) proteins are regulated independently in sepsis, however, the factors regulating their synthesis are unknown. In this study, we assessed the effects of sepsis and interleukin-1 receptor antagonist on sarcoplasmic and myofibrillar protein synthesis in gastrocnemius. The rate of sarcoplasmic protein synthesis was 3.5 times that of myofibrillar proteins in control and septic rats. The synthesis of both sarcoplasmic and myofibrillar proteins was diminished proportionately during sepsis (p < .05). Infusion of interleukin-1 receptor antagonist (2 mg.kg.-1.h.-1) prevented the sepsis-induced inhibition of total, sarcoplasmic, and myofibrillar protein synthesis. Changes in the abundance of messenger RNA could not account for the inhibition of protein synthesis observed in sepsis. Furthermore, in vitro translation of messenger RNA isolated from control and septic muscle revealed no major differences. These results suggest the following: 1) the inhibition of total mixed proteins during sepsis is a consequence of reduced synthesis of both myofibrillar and sarcoplasmic proteins; 2) IL-1ra maintains control values of protein synthesis by sparing the reduction in synthesis of both myofibrillar and sarcoplasmic proteins during sepsis; and 3) the abundance of messenger RNA is not a rate-limiting determinant of protein synthesis in muscle from septic rats. An alteration in the translational efficiency of existing mRNA appears to be the major mechanism responsible for the inhibition of protein synthesis during sepsis.

Altered expression of skeletal muscle proteins during sepsis.

Sepsis induces a net catabolic state in gastrocnemius by increasing protein degradation and decreasing protein synthesis. To determine whether or not sepsis induces a preferential effect on the expression of individual proteins, proteins from gastrocnemius muscle of control and septic rats were separated by two-dimensional isoelectric focusing/sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Laser densitometry of proteins stained with silver provided evidence that the relative abundance of thirty-five proteins was significantly (p < .05) and reproducibly increased during sepsis compared to control. No individual protein underwent significant down-regulation in their relative abundance during sepsis. Twenty-three of the 35 proteins identified in two-dimensional gels of the gastrocnemius were also present in the plasma of septic rats. The remaining 12 proteins, therefore, were taken to represent skeletal muscle proteins. One of the 12 proteins was identified by immunoblot analysis to be carbonic anhydrase III. Another of the proteins was identified as triosephosphate isomerase based upon microsequencing of the N terminus.

Mechanism of IL-1 induced inhibition of protein synthesis in skeletal muscle.

Chronic interleukin (IL)-1 administration is associated with negative nitrogen balance and the loss of lean body mass. To elucidate the molecular mechanism(s) by which IL-1 modulates protein metabolism in muscle, we investigated the effects of chronic (6 day) IL-1alpha infusion on protein synthesis in Individual muscles (gastrocnemius, soleus, heart) compared with saline-infused control rats. IL-1 significantly decreased muscle weight, protein content, and the rate of protein synthesis in gastrocnemius (fast-twitch muscle). IL-1 had no effect on these parameters in the heart, whereas only the rate of protein synthesis was reduced in soleus (slow-twitch muscle). The reduction in gastrocnemius protein synthesis was not the result of a decrease in total RNA content, but was associated with a diminished translational efficiency. The diminished translational efficiency correlated with a 40% reduction in the epsilon-subunit of eukaryotic initiation factor 2B (elF2Bepsilon) in gastrocnemius from IL-1 -treated animals. However, the content of the alpha-subunit of elF2 (elF2alpha) was unaffected. In contrast, the elF2alpha content in heart was increased by IL-1, although elF2Bepsilon levels were unchanged. Reductions in skeletal muscle protein synthesis were not associated with a concomitant reduction in circulating or tissue content of insulin-like growth factor I. In summary, the IL-1-induced decrease in gastrocnemius protein synthesis appears to be regulated at the level of RNA translation via a reduction in elF2Bepsilon. These findings support a regulatory role for IL-1 as a mediator of muscle protein synthesis and the alterations in body composition observed in catabolic states where this cytokine is overexpressed.

Advanced signal-processing method for the detection, localization, and quantification of acute myocardial ischemia.

In this study of a canine heart model of localized reversible ischemia, a computer-based single-processing method is developed to detect and localize the epicardial projections of ischemic myocardial electrocardiograms (ECGs) during the cardiac activation, rather than the repolarization, phase. This is done by transforming ECG signals from an epicardial sensor array into the multichannel spectral domain and identifying three decision variables: (1) the frequency in hertz of the spectral peak (f0), its frequency band width 50% below the peak value (w0), and the maximum eigenvalue difference of the ECG signal's autocorrelation matrix (e0). With use of the histograms of the f0, w0, and e0 parameters of 3256 ECGs from normal and 957 from ischemic areas of myocardium obtained from 12 dogs, it was possible to predict ischemia in a new test group of nine animals from a Neyman-Pearson (NP) test in which the threshold probabilities of detecting ischemia for each decision variable are compared with those of detecting normality. Quantification of each sensor area by the NP tests revealed that, compared with the control, ECG spectra with decreased F0 and w0 and increased e0 relative to their respective thresholds had increased myocardial lactate (p less than 0.01), decreased adenosine triphosphate (ATP) (p less than 0.05), and reduced creatine phosphate (p less than 0.01). Prediction of f0 (p less than 0.0006) as a continuous variable could be obtained from the regression of the myocardial levels of ATP plus creatine phosphate, which demonstrated that this decision variable appears to directly reflect myocardial energetics. It appears that an advanced signal-processing method for ECG array data can be used to detect, localize, and quantify reversible myocardial ischemia.

Insulin stimulation of protein synthesis in rat skeletal muscle following resistance exercise is maintained with advancing age.

This study examined whether or not insulin elevates rates of protein synthesis in muscle following four days of resistance exercise in young (4-mo), middle-aged (12-mo), and old (32-mo) rats. Thirty-six male Fischer 344/BN F1 rats (n = 12 in each group) performed an operantly conditioned activity which required full extension of the hindlimbs with weights over the scapula (ACUTE; n = 6 for each age group) or with no additional weight (nonexercised; NONEX; n = 6 for each age group). Acutely exercised animals engaged in four distinct exercise sessions with each session separated by 48 h. Rates of protein synthesis were assessed in soleus, gastrocnemius (GAST), and extensor digitorum longus (EDL) muscles 16 h after the last exercise bout using a bilateral hindlimb perfusion to measure the incorporation of tritiated phenylalanine (F) into muscle protein. One limb of the bilateral hindlimb preparation received a medium that contained rat insulin at a physiological concentration (6.25 ng.ml-1), while the other limb did not. Rates of protein synthesis in soleus with insulin supplementation were significantly higher within all age groups following resistance exercise vs ACUTE without insulin and NONEX with or without insulin (p < .05). Rates of protein synthesis in soleus were not different within age groups for NONEX with or without insulin (p < .05), but rates of protein synthesis for young NONEX were significantly higher (p < .05) than middle-aged or old NONEX (204 +/- 9 vs 149 +/- 6 or 141 +/- 9 nmol F incorporated.g-1.h-1, respectively; means +/- SE). Rates of protein synthesis in GAST with insulin were also significantly higher within all age groups following resistance exercise than ACUTE without insulin or NONEX with or without insulin (p < .05). Unlike soleus, rates of protein synthesis in GAST were significantly higher for old NONEX vs young NONEX (68 +/- 6 vs 45 +/- 5 nmol F incorporated.g-1.h-1, respectively; P < .05), but not middle-aged NONEX (51 +/- 3 nmol F incorporated.g-1.h-1). Translational efficiency (rates of protein synthesis.unit of RNA-1.h-1) for GAST supplemented with insulin was significantly greater in ACUTE with insulin than ACUTE without insulin or NONEX with or without insulin (p < .05). There were no effect of age, insulin, or exercise on rates of protein synthesis in EDL (p > .05). These data suggest that following resistance exercise, insulin increased rates of protein synthesis in both soleus and GAST regardless of age, and it appeared that this insulin-mediated elevation may have occurred at the level of translation.

Modulation of skeletal muscle protein synthesis by amino acids and insulin during sepsis.

Effects of different concentrations of insulin and amino acids on protein synthesis in skeletal muscle of young, fed septic rats were determined in the perfused rat hindlimb. Rates of protein synthesis in gastrocnemius were measured by incorporation of [3H]-phenylalanine into protein. Perfusion of hindlimb muscles from young, fed control rats with medium containing either insulin and a complete mixture of amino acids at plasma concentration (1x) or a mixture of amino acids at 10-fold (10x) plasma concentration resulted in an approximately twofold stimulation of the rate of protein synthesis. The effect of amino acids on protein synthesis was partly accounted for by elevated concentrations of branched-chain amino acids ([BCAA] leucine, isoleucine, and valine). In young, fed septic rats, the rate of protein synthesis in muscle perfused with buffer containing the normal concentration of amino acids was reduced 40% as compared with control levels (P < .05). In contrast to controls, addition of insulin (1,000 microU/mL) did not augment protein synthesis in muscle from young, fed septic rats perfused with the complete mixture of amino acids. Addition of insulin 10,000 microU/mL stimulated protein synthesis approximately 80% in gastrocnemius of septic rats (P < .05). However, the rate of protein synthesis remained less than that observed in young, fed control rats at similar insulin concentrations. Perfusion with medium containing 10x plasma amino acids stimulated protein synthesis approximately fourfold in young, fed septic rats as compared with control animals. In contrast to controls, BCAA at 10x plasma concentration did not augment protein synthesis in young, fed septic rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin-induced activation of pyruvate dehydrogenase complex in skeletal muscle of diabetic rats.

The pyruvate dehydrogenase (PDH) complex undergoes reversible phosphorylation catalyzed by a PDH kinase (inactivating) and a PDH phosphatase (activating). In skeletal muscle, a decreased proportion of active PDH (PDHa) complex limits glucose oxidation in insulin-deficient states. The time-course for reactivation of the PDH complex by insulin in skeletal muscle of diabetic rats is important to understanding the potential mode of the action of insulin in regulating glucose metabolism. A single injection of insulin (1 U/kg) completely reversed the effects of alloxan-diabetes on PDHa activity within 1 hour. The normalization of the effects of diabetes on PDHa activity by insulin was maintained for a minimum of 6 hours. The increase in PDHa activity occurred before an insulin-induced decrease in plasma free fatty acids levels, demonstrating a dissociation between the antilipolytic effects of insulin and its ability to activate the PDH complex. PDH kinase activity was not normalized to control values following a single injection of insulin. Therefore, acute (1 to 6 hours) insulin-mediated activation of the PDH complex does not result from a decrease in PDH kinase activity. However, longer-term insulin therapy (1 U/kg body weight; twice daily) restored both PDHa and PDH kinase activities. The results are consistent with the hypothesis that activation of the PDH complex immediately following insulin administration is not mediated by a decreased PDH kinase activity. However, with daily insulin therapy in diabetes, activation of the PDH complex results from decreased PDH kinase activity.

Selected Contribution: IGF-I antibody prevents increases in protein synthesis in epitrochlearis muscles from refed, diabetic rats.

The purpose of this study was to examine whether immune neutralization of muscle-produced insulin-like growth factor I (IGF-I) would prevent an appropriate anabolic response to refeeding in diabetic rats. Male Sprague-Dawley rats were made diabetic by partial pancreatectomy and were randomly assigned to be either control-fed, fasted, or fasted-refed (n = 7-8 per group). Diabetes decreased rates of protein synthesis and increased rates of protein degradation in incubated epitrochlearis muscles (P < 0.05). In both groups of rats, fasting lowered protein synthesis and increased proteolysis and subsequent refeeding returned both parameters to near basal values (P < 0.05). Neutralization of muscle IGF-I by the addition of IGF-I antibody to the incubation medium reduced protein synthesis an average of 22% for all groups (P < 0.05). However, rates of protein degradation were not affected. In nondiabetic rats, refeeding increased protein synthesis in both control and antibody-treated muscles (P < 0.05). Refeeding also increased protein synthesis in the control muscles from diabetic rats (P < 0.01). In contrast, muscles from diabetic rats that were incubated with anti-IGF-I did not increase protein synthesis in response to refeeding. These data suggest that immune neutralization of muscle IGF-I in hypoinsulinemic rats negated the ability of endogenous IGF-I to promote protein synthesis and thereby prevented an appropriate anabolic response.

Effects of intensity of acute-resistance exercise on rates of protein synthesis in moderately diabetic rats.

These studies determined whether increases in rates of protein synthesis observed in skeletal muscle after moderate or severe acute-resistance exercise were blunted by insulinopenia. Rats (n = 6-9 per group) were made insulin deficient by partial pancreatectomy or remained nondiabetic. Groups either remained sedentary or performed acute-resistance exercise 16 h before rates of protein synthesis were measured in vivo. Exercise required 50 repetitions of standing on the hindlimbs with either 0.6 g backpack wt/g body wt (moderate exercise) or 1.0 g backpack wt/g body wt (severe exercise). Insulin-deficient rats had a mean blood glucose concentration >15 mM and reduced insulin concentrations in the plasma. Rates of protein synthesis in gastrocnemius muscle were not different in all sedentary groups. The moderate-exercised nondiabetic group (192 +/- 12 nmol phenylalanine incorporated. g muscle-1. h-1) and moderate-exercised diabetic group (215 +/- 18) had significantly (P < 0.05, ANOVA) higher rates of protein synthesis than did respective sedentary groups. In contrast, diabetic rats that performed severe-resistance exercise had rates of protein synthesis (176 +/- 12) that were not different (P > 0.05) from diabetic sedentary rats (170 +/- 9), whereas nondiabetic rats that performed severe exercise had higher (212 +/- 24) rates compared with nondiabetic sedentary rats (178 +/- 10) P < 0.05. The present data in combination with previous studies [J. D. Fluckey, T. C. Vary, L. S. Jefferson, and P. A. Farrell. Am. J. Physiol. 270 (Endocrinol. Metab. 33): E313-E319, 1996] show that the amount of insulin required for an in vivo permissive effect of insulin on rates of protein synthesis can be quite low after moderate-intensity resistance exercise. However, severe exercise in combination with low insulin concentrations can ablate an anabolic response.

Severe diabetes prohibits elevations in muscle protein synthesis after acute resistance exercise in rats.

This study determined whether rates of protein synthesis increase after acute resistance exercise in skeletal muscle from severely diabetic rats. Previous studies consistently show that postexercise rates of protein synthesis are elevated in nondiabetic and moderately diabetic rats. Severely diabetic rats performed acute resistance exercise (n = 8) or remained sedentary (n = 8). A group of nondiabetic age-matched rats served as controls (n = 9). Rates of protein synthesis were measured 16 h after exercise. Plasma glucose concentrations were >500 mg/dl in the diabetic rats. Rates of protein synthesis (nmol phenylalanine incorporated. g muscle(-1). h(-1), means +/- SE) were not different between exercised (117 +/- 7) and sedentary (106 +/- 9) diabetic rats but were significantly (P < 0.05) lower than in sedentary nondiabetic rats (162 +/- 9) and in exercised nondiabetic rats (197 +/- 7). Circulating insulin concentrations were 442 +/- 65 pM in nondiabetic rats and 53 +/- 11 and 72 +/- 19 pM in sedentary and exercised diabetic rats, respectively. Plasma insulin-like growth factor I concentrations were reduced by 33% in diabetic rats compared with nondiabetic rats, and there was no difference between exercised and sedentary diabetic rats. Muscle insulin-like growth factor I was not affected by resistance exercise in diabetic rats. The results show that there is a critical concentration of insulin below which rates of protein synthesis begin to decline in vivo. In contrast to previous studies using less diabetic rats, severely diabetic rats cannot increase rates of protein synthesis after acute resistance exercise.

Eukaryotic initiation factors and protein synthesis after resistance exercise in rats.

Translational control of protein synthesis depends on numerous eukaryotic initiation factors (eIFs) and we have previously shown (Am. J. Physiol. Endocrinol. Metab. 276: E721-E727, 1999) that increases in one factor, eIF2B, are associated with increases in rates of protein synthesis after resistance exercise in rats. In the present study we investigated whether the eIF4E family of initiation factors is also involved with an anabolic response to exercise. Male Sprague-Dawley rats either remained sedentary (n = 6) or performed acute resistance exercise (n = 6), and rates of protein synthesis were assessed in vivo 16 h after the last session of resistance exercise. eIF4E complexed to eIF4G (eIF4E x eIF4G), eIF4E binding protein 1 (4E-BP1) complexed to eIF4E, and phosphorylation state of eIF4E and 4E-BP1 (gamma-form) were assessed in gastrocnemius. Rates of protein synthesis were higher in exercised rats compared with sedentary rats [205 +/- 8 (SE) vs. 164 +/- 5.5 nmol phenylalanine incorporated x g muscle(-1) x h(-1), respectively; P < 0.05]. Arterial plasma insulin concentrations were not different between the two groups. A trend (P = 0.09) for an increase in eIF4E x eIF4G with exercise was noted; however, no statistically significant differences were observed in any of the components of the eIF4E family in response to resistance exercise. These new data, along with our previous report on eIF2B, suggest that the regulation of peptide chain initiation after exercise is more dependent on eIF2B than on the eIF4E system.

Hypertrophy of skeletal muscle in diabetic rats in response to chronic resistance exercise.

This study had the following objectives: 1) to determine whether diabetic rats could increase muscle mass due to a physiological manipulation (chronic resistance exercise), 2) to determine whether exercise training status modifies the effect of the last bout of exercise on elevations in rates of protein synthesis, and 3) to determine whether chronic resistance exercise alters basal glycemia. Groups consisted of diabetic or nondiabetic rats that performed progressive resistance exercise for 8 wk, performed acute resistance exercise, or remained sedentary. Arterial plasma insulin in diabetic groups was reduced by about one-half (P < 0.05) compared with nondiabetic groups. Soleus and gastrocnemius-plantaris complex muscle wet weights were lower because of diabetes, but in response to chronic exercise these muscles hypertrophied in diabetic (0.028 +/- 0.003 vs. 0.032 +/- 0.0015 g/cm for sedentary vs. exercised soleus and 0.42 +/- 0.068 vs. 0.53 +/- 0.041 g/cm for sedentary vs. exercised gastrocnemius-plantaris, both P < 0.05) but not in nondiabetic (0.041 +/- 0.0026 vs. 0.042 +/- 0.003 g/cm for sedentary vs. exercised soleus and 0.72 +/- 0.015 vs. 0.69 +/- 0.013 g/cm for sedentary vs. exercised gastrocnemius-plantaris) rats when muscle weight was expressed relative to tibial length or body weight (data not shown). Another group of diabetic rats that lifted heavier weights showed muscle hypertrophy. Rates of protein synthesis were higher in red gastrocnemius in chronically exercised than in sedentary rats: 155 +/- 11 and 170 +/- 7 nmol phenylalanine incorporated x g muscle(-1) x h(-1) in exercised diabetic and nondiabetic rats vs. 110 +/- 14 and 143 +/- 7 nmol phenylalanine incorporated x g muscle(-1) x h(-1) in sedentary diabetic and nondiabetic rats. These elevations, however, were lower than in acutely exercised (but untrained) rats: 176 +/- 15 and 193 +/- 8 nmol phenylalanine incorporated x g muscle(-1) x h(-1) in diabetic and nondiabetic rats. Finally, chronic exercise training in diabetic rats was associated with reductions in basal glycemia, and such reductions did not occur in sedentary diabetic groups. These data demonstrate that, despite lower circulating insulin concentrations, diabetic rats can increase muscle mass in response to a physiological stimulus.

Effect of dichloroacetate on plasma and hepatic amino acids in sterile inflammation and sepsis.

The effect of sterile inflammation and chronic sepsis on the plasma and hepatic free amino acid concentrations was determined. Relative to control animals, only minor alterations in the plasma amino acid concentrations were observed in sterile inflammation and sepsis. In liver, concentrations of alanine, serine, threonine, asparagine, proline, and glycine were significantly increased to the same extent in sterile inflammation and sepsis, while hepatic glutamine concentrations were significantly decreased. Compared with sterile inflammation, the branched-chain amino acid concentrations were depressed in the liver of septic animals. Following administration of dichloroacetate, hepatic alanine concentrations were significantly reduced more than threefold in each of the conditions examined; in contrast, significant increases in hepatic concentrations of threonine, glycine, glutamine, glutamate, histidine, and proline were observed. Also following administration of dichloroacetate, the branched-chain amino acid concentrations were all significantly elevated in each of the conditions examined, and plasma alanine concentrations were significantly decreased, while those of glutamine and glycine were significantly increased. These results demonstrate that there is a disassociation between the plasma and hepatic concentration of free amino acids in sterile inflammation and sepsis. Furthermore, the results demonstrate that some of the alterations in hepatic amino acid metabolism may be reversed pharmacologically by dichloroacetate.

Intravascular plastic catheters. How they potentiate tumor necrosis factor release and exacerbate complications associated with sepsis.

We tested the hypothesis that long-term intravascular cannulation exacerbates the harmful effects of an infectious challenge. Four groups of rats were initially studied: rats without intravascular catheters or infection (group 1), rats without catheters with a polymicrobial infection (group 2), rats with catheters but no infection (group 3), and rats with catheters and infection (group 4). Infected animals had an increased mortality and generated a significantly increased tumor necrosis factor response compared with noninfected animals. Animals with catheters and infection generated far less cardiac output than animals from the other three groups. No histologic changes differentiated the four groups. Therefore, the presence of a sterile intravascular catheter significantly increases cardiac dysfunction and mortality rates in rats with chronic bacteremia. These results suggest that intravascular plastic catheters potentiate the destructive cascade of events produced by the host in response to bacteremia.