The effect of rejuvenation of aged erythrocytes on biochemical parameters in the perfused hind limb muscle preparation.

(1) A systematic investigation was carried out into the use of time-expired erythrocytes in an isolated perfused skeletal muscle preparation. Comparisons were made between erythrocytes subjected to a process of 'rejuvenation' (Rennie and Holloszy (1977), Biochem. J. 168, 161-170) and untreated erythrocytes (controls). (2) The use of rejuvenated erythrocytes had no significant effect on concentrations of muscle ATP, phosphocreatine and lactate, nor fractional rates of muscle protein synthesis. However, muscle water concentrations were reduced when compared to controls. (3) There was an influx of K+ from the plasma into rejuvenated erythrocytes. This was accompanied by a substantial loss (17%) of intramuscular K+. There was also loss of K+ from control preparations but this amounted to approx. 1% of muscle content. (4) Erythrocyte fragility was greater in the control perfusate (6%, haemolysis) when compared to the medium with rejuvenated cells (1%, haemolysis). As a consequence of either erythrocyte storage, rejuvenation or haemolysis, plasma concentrations of phosphate, magnesium, calcium and potassium were significantly different from starting values, by as much as 300% in both groups, and varied throughout the study. (5) It is concluded that the use of rejuvenated erythrocytes does not confer any advantage in unexercised perfused skeletal muscle preparations. However, both types of erythrocyte induce changes in perfusate composition relative to starting or in vivo profiles.

Chronic effects of ethanol on muscle metabolism in the rat.

Chronic ethanol feeding in the rat is associated with a skeletal myopathy involving primarily type-II muscle fibres, which is recognised to be mediated via a specific impairment in protein turnover. This paper investigates whether the cause of this myopathy may be related to abnormalities in carbohydrate and lipid metabolism in different muscles. [U-14C]Glucose metabolism was examined in two muscles with different fibre compositions, the extensor digitorum longus (EDL) muscle, which contains predominantly type-II muscle fibres, and the soleus muscle, which is composed primarily of type-I muscle fibres. Feeding on the ethanol-supplemented Lieber-DeCarli liquid diet for 2 or 6 weeks was associated with profound disturbances in glucose metabolism in both EDL and soleus muscles, particularly in relation to rates of glycogen and alanine formation. We discuss the importance of these metabolic changes in relation to the genesis of chronic alcoholic skeletal myopathy.

Synthesis of subcellular protein fractions in the rat heart in vivo in response to chronic ethanol feeding.

An investigation was made into the chronic effects of ethanol on the subcellular protein fractions in the hearts of young rats (80-100 g body weight). Rats were fed a nutritionally adequate liquid diet containing ethanol as 36% of total energy. Controls were fed the same diet in which ethanol was substituted by iso-energetic glucose. At the end of 6 weeks, rats were killed and hearts were fractionated into sarcoplasmic, myofibrillar and stromal protein fractions by differential solubilisation. The total myofibrillar protein content was significantly reduced by chronic ethanol feeding, though the contents of other fractions were relatively unaltered. The fractional and absolute rates of myofibrillar protein synthesis were significantly increased, but the synthesis rates of sarcoplasmic and stromal protein fractions were unaffected by ethanol feeding. This suggests independent regulation of myofibrillar protein content in the ethanol exposed heart. These changes may be responsible for alterations in myocardial function in alcoholic cardiomyopathy.

Protein synthesis in pulmonary, cardiac, and skeletal muscle in acute hypertension induced by aortic constriction in the rat.

OBJECTIVE: The aim was to investigate nucleic acid composition and rates of protein synthesis in cardiopulmonary tissues and skeletal muscle in response to hypertension induced by aortic constriction. METHODS: After five days of abdominal aortic constriction, protein, RNA, and DNA contents were measured in the lung, the left and right atria, the left and right ventricles, and gastrocnemius muscle from young male Wistar rats weighing 120-140 g. Rates of protein synthesis were also measured in these tissues with L[4-3H]phenylalanine. RESULTS: Aortic constriction significantly increased the right atrial weight and in contrast reduced the lung weight, compared to pair fed and sham operated controls. The wet weights of all other tissues were unaffected. The concentrations of right atrial proteins, RNA, and DNA were also significantly reduced though total protein, RNA, and DNA contents were unaltered. The left ventricular RNA concentration increased and there were variable alterations in protein and DNA composition. The protein, RNA, and DNA compositions of the other tissues showed patterned responses, which included reductions in lung and skeletal muscle DNA concentrations, reductions in the skeletal muscle RNA/DNA ratio, and a decrease in the lung protein/DNA ratio. In response to aortic constriction there were increases in the left ventricular fractional rate of protein synthesis in mixed, high salt (myofibrillar), and low salt (sarcoplasmic) fractions. Rates of protein synthesis in all other regions of the heart, lung and skeletal muscle were not significantly changed. CONCLUSIONS: We conclude that in abdominal aortic constriction, the left ventricles display early adaptive responses without any concomitant change in mass. Those regions of the rat cardiopulmonary system which are not directly exposed to the acute pressure overloading, ie, right atrium, lungs, and skeletal muscle, also show disturbances.

Effect of acute anaesthesia on synthesis of contractile and non-contractile proteins of heart muscle and mixed proteins of types I and II fibre rich skeletal muscles of rat.

STUDY OBJECTIVE: The aim of the study was to determine whether the deleterious effects of anaesthesia on cardiac muscle function were due to disturbance of protein synthesis. Comparative investigations were made on anaerobic and aerobic skeletal muscles, and plasma insulin and growth hormone levels were also measured to see if these were mediating factors. DESIGN: Rats were subjected to acute methoxyfluorane anaesthesia for 10 min. At the end of the study they were killed and plasma growth hormone and insulin were measured. Rates of cardiac and skeletal muscle protein synthesis were also determined with a flooding dose of L[4-3H]phenylalanine. EXPERIMENTAL MATERIAL: Muscle samples were obtained from male Sprague-Dawley rats, weight 191-222 g. MEASUREMENTS AND MAIN RESULTS: Anaesthesia reduced the fractional rate of myocardial mixed protein synthesis and synthesis relative to RNA (p less than 0.05). The anaesthesia induced decrease in the synthesis rates of cardiac contractile proteins (p less than 0.05) was greater than the decrease in the non-contractile protein fractions (p greater than 0.05). Soleus (aerobic, Type I) and plantaris (anaerobic, Type II) muscle rates of protein synthesis were unaltered in response to anaesthesia (p greater than 0.05). Plasma insulin concentrations increased in response to acute anaesthesia (p less than 0.05), but the insulin effect was depressed by the flooding dose of phenylalanine (p less than 0.05). Plasma growth hormone levels were not altered in response to anaesthesia (p greater than 0.05). Thus, the changes in cardiac protein synthesis could not be ascribed to these hormones. CONCLUSIONS: Synthesis of cardiac contractile proteins is selectively sensitive to the effects of acute anaesthesia even in the presence of high plasma insulin concentrations. The fall in cardiac protein synthesis may be a result of the negative inotropic effects of general anaesthesia.

Alcohol and the heart: biochemical alterations.

A considerable amount of attention has focused on the cardiovascular events associated with ethanol consumption. The available evidence suggests that moderate ethanol consumption is associated with reduced risk of coronary heart disease, i.e., vessel events. In contrast, this review is primarily concerned with ethanol and heart muscle damage. Clinical features of the consequences of prolonged and excessive ethanol consumption encompass defects in myocardial contractility and derangement of cellular architecture, including disarray of the contractile elements. Although the incidence of heart muscle abnormalities in alcohol misusers is generally higher than previously considered, the mechanisms are only just being elucidated. This process has been facilitated by laboratory based studies in which animals receive either a single dose of ethanol (acute studies) or a continuous supply of ethanol in their daily diets (chronic studies). Results from these models show that acute ethanol dosage causes a marked decrease in the synthesis of contractile proteins. This occurs in the absence of overt mitochondrial abnormalities: ATP concentrations are generally unaffected. Paradoxically, the synthesis of mitochondrial proteins is reduced. Use of metabolic inhibitors suggests that the deleterious effects of acetaldehyde contribute to these reductions in protein synthesis. In chronic studies, ethanol causes a reduction in the amount of contractile proteins, and two dimensional protein profiling implicates selective loss of individual myocardial proteins. The differential activities of lysosomal proteases may contribute to this patterned response. However, in chronic ethanol feeding, adaptive mechanisms also become important, as the synthesis of the myofibrillary proteins increases. Overall, the mechanisms inherent in these biochemical responses may contribute to the genesis of a distinct disease entity, alcoholic heart muscle disease.

The effect of endotoxin on skeletal muscle protein gene expression in the rat.

Sepsis is associated with net breakdown of skeletal muscle protein, mediated partly by reduced rates of muscle protein synthesis. This study investigated the role of altered gene expression for specific muscle proteins in mediating reduced protein synthesis in a rat model of acute severe sepsis. Adult rats were given a single sublethal intraperitoneal dose of endotoxin (bacterial lipopolysaccharide). Protein, RNA and DNA contents of muscle were measured and changes in expression of mRNA in tibialis anterior and extensor digitorum longus muscles were detected by quantification of Northern blots at 6, 24, 48 and 72 hr after endotoxin and in animals starved for 24 hr. Results showed that at 24 hr after endotoxin there was a loss of about 14% of muscle protein content. No reduction in mRNA was found at any time point for beta-myosin heavy chain (MHC), fast-MHC, alpha-actin, skeletal muscle troponin or carbonic anhydrase III (CA III); rather, at 48 hr there was increased expression of beta-MHC (224 +/- 123% control) and CA III (202 +/- 56%). Blocking TNF-alpha by pre-treatment with a monoclonal antibody did not appear to influence this. Total RNA content of muscle was reduced to 67% of the control values 24 hr after LPS, although this was no different to pair-fed animals starved for 24 hr. It is concluded that reduced protein synthesis in skeletal muscle in early acute sepsis is not primarily associated with reduced muscle protein gene expression.

Skeletal muscle protein loss due to D-penicillamine results from reduced protein synthesis.

Reports in the literature indicate that the trifunctional amino acid D-penicillamine (D-P) induces a variety of muscle abnormalities, although the mechanisms are unknown. We hypothesised that defects may also arise due to the effects of D-P on rates of protein synthesis, possibly via changes in muscle metal composition. Male Wistar rats were injected with D-P at doses of 50 and 500 mg/kg body weight, i.p. Rats designated as controls were injected with 0.15 mol/l NaCl. After 24 h, there were reductions in muscle protein contents, protein synthetic capacities (RNA:protein ratio), fractional rates of protein synthesis, synthesis rates per unit RNA and synthesis rates per unit DNA in skeletal muscles of D-P treated rats. There were no statistically significant differences between the responses of the muscles containing a predominance of either Type I (represented by the soleus) or Type II (represented by the plantaris) fibres. In general, intracellular amino acids were not significantly affected by D-P treatment. Changes in muscle metals included significant reductions in copper, iron and manganese, without alterations in zinc or magnesium. In liver D-P reduced copper and iron though zinc, manganese and magnesium were unaffected. These effects of D-P on muscle may have been direct, as plasma indices of liver (activities of alkaline phosphatase and alanine aminotransferase) and kidney (urea, creatinine and electrolytes) damage were not significantly altered by D-P treatment. Plasma levels of corticosterone, insulin and free T3 were also not significantly affected by D-P treatment. Muscle protein carbonyl concentrations, an index of free radical activity, were similarly unaffected. This is the first report of reduced rates of muscle protein synthesis in D-P treatment. Our data suggests that the reduced rates of muscle protein synthesis may contribute to, or reflect, the muscle abnormalities observed in patients undergoing D-P treatment.

Effect of thyroidectomy and adrenalectomy on changes in liver glutathione and malonaldehyde levels after acute ethanol injection.

At low concentrations ethanol is metabolized largely by alcohol dehydrogenase to acetaldehyde, while at higher concentrations a microsomal ethanol oxidising system (MEOS) is involved, namely cytochrome P450 IIE1, which also probably generates free radical species. In hyperthyroidism hepatic glutathione stores are depleted and net superoxide anion production occurs. In contrast, in hypothyroidism hepatic glutathione may be increased and thus renders the liver less sensitive to alcohol generated free radical production. Steroid hormones inhibit lipid peroxidation. Sixty male Wistar rats either underwent thyroidectomy, adrenalectomy, or sham procedures. Twenty control animals were pair fed with thyroidectomized animals, whilst another twenty fed ad libitum. An intraperitoneal injection of alcohol (75 mmol/kg) was given 2.5 h prior to sacrifice to half the animals in each group, the remainder receiving saline. The total hepatic glutathione contents of the pair fed and the ad libitum groups were not different, but were significantly increased by thyroidectomy (p = < 0.001). This effect was significantly reduced by alcohol (p < 0.01). The sham procedures and dietary restrictions had no effect. The ethanol alone reduced total hepatic glutathione, but this only reached statistical significance in the thyroidectomized and sham-adrenalectomized groups. Hepatic malonaldehyde (MDA) levels were significantly reduced in the thyroidectomy group but alcohol had no effect on them. We conclude that hypothyroidism increased hepatic glutathione status, presumably by reducing radical production by enzyme systems, which would otherwise consume this important scavenger. Long term exposure to ethanol with induction of MEOS is probably required for it to generate toxic levels of free radical species.

Oxidants, antioxidants and alcohol: implications for skeletal and cardiac muscle.

The chronic form of alcoholic skeletal myopathy is characterized by selective atrophy of Type II fibers and affects up to two thirds of all alcohol misusers. Plasma selenium and alpha-tocopherol are reduced in myopathic alcoholics compared to alcoholic patients without myopathy. Plasma carnosinase is also reduced in myopathic alcoholics, implicating a mechanism related to reduced intramuscular carnosine, an imidazole dipeptide with putative antioxidant properties. Together with the observation that alcoholic patients have increased indices of lipid peroxidation, there is evidence suggestive of free radical (i.e., unpaired electrons or reactive oxygen species) mediated damage in the pathogenesis of alcohol-induced muscle disease. Protein synthesis is a multi-step process that encompasses amino acid transport, signal transduction, translation and transcription. Any defect in one or more of the innumerable components of each process will have an impact on protein synthesis, as determined by radiolabelling of constituent proteins. Both acute and chronic alcohol exposure are associated with a reduction in skeletal muscle protein synthesis. Paradoxically, alcohol-feeding studies in rats have shown that the imidazole dipeptide concentrations are increased in myopathic muscles though alpha-tocopherol contents are not significantly altered. In acutely dosed rats, where protein synthesis is reduced, protein carbonyl concentrations (an index of oxidative damage to muscle) also decline slightly or are unaltered, contrary to the expected increase. Alcoholic cardiomyopathy can ensue from heavy consumption of alcohol over a long period of time. The clinical features include poor myocardial contractility with reduced left ventricular ejection volume, raised tissue enzymes, dilation of the left ventricle, raised auto- antibodies and defects in mitochondrial function. Whilst oxidant damage occurs in experimental models, however this issues remains to be confirmed in the clinical setting. In the rat, circulating troponin-T release increases in the presence of ethanol, a mechanism ascribed to free radical mediated damage, as it is prevented with the xanthine oxidase inhibitor and beta-blocker, propranolol. However, whilst propranolol prevents the release of troponin-T, it does not prevent the fall in whole cardiac protein synthesis, suggestive of localized ischemic damage due to ethanol.

Differential effects of malnutrition, bile duct ligation and galactosamine injection in young rats on serum levels and gene expression of IGF-binding proteins.

Hepatic gene expression and circulating levels of IGF-binding proteins (IGFBP)-1 to -4 were examined in two rat models of liver disease employing acute hepatitis or chronic structural damage. The study comprised four groups: group 1 (n = 6) was injected intraperitoneally with saline and food was available ad libitum (AL), group 2 (n = 6) underwent bile duct ligation (BDL), group 3 (n = 6) was injected with 400 mg galactosamine (GAL), group 4 (n = 6) was sham-operated and pair-fed to group 2 (PF). All were killed by decapitation at day 7. Serum IGF-I, by RIA, was significantly (P < 0.05) lower in the BDL group (458 +/- 37 micrograms/l) and PF group (451 +/- 51 micrograms/l) compared with the AL group (643 +/- 77 micrograms/l) and GAL group (720 +/- 67 micrograms/l). Immunoblotting showed raised IGFBP-2 levels in all groups compared with AL (BDL, 167 +/- 14% of AL; GAL, 173 +/- 13%; PF, 149 +/- 9%). IGFBP-3 was decreased in the GAL (56 +/- 11%) and PF groups (66 +/- 5%) but increased in the BDL group (154 +/- 29%). IGFBP-4 was decreased in the GAL (76 +/- 11%) and PF groups (47 +/- 5%) but unchanged in the BDL group (90 +/- 10%). By Northern analysis, IGFBP-1 mRNA expression was increased in the GAL (321 +/- 51%) and PF groups (263 +/- 12%) but reduced in the BDL group (68 +/- 8%). IGFBP-2 expression increased in all groups (PF, 836 +/- 19%; BDL, 683 +/- 121%; GAL, 372 +/- 68%) and was highest in the BDL and PF groups. IGFBP-3 expression was reduced in all groups (BDL, 57 +/- 16%; GAL, 52 +/- 12% PF, 51 +/- 13%). IGFBP-4 expression was reduced in the GAL (30 +/- 4%) and PF (28 +/- 5%) groups but unchanged in the BDL group (76 +/- 9%). Marked changes in gene expression of IGFBPs occurred in both models of liver disease, together with serum changes, which were different from each other and from malnutrition alone.

Differential expression of suppressors of cytokine signalling genes in response to nutrition and growth hormone in the septic rat.

GH treatment during critical illness and sepsis may increase mortality. A family of negative regulators of cytokine signalling, the suppressors of cytokine signalling (SOCS), have been characterised. SOCS provide a mechanism for cross-talk between the cytokine receptors, including GH. Here, we have investigated the impact of nutrition and GH treatment on GH receptor, SOCS1, SOCS-2, SOCS-3 and cytokine-inducible SH2-containing protein (CIS) hepatic mRNA expression in a rat model of sepsis, caecal ligation and puncture (CLP). Four groups of rats were studied: control (food given ad libitum, n=7), CLP only (n=8), CLP and total parenteral nutrition (TPN) (n=9), and CLP, TPN and GH (n=10). CLP rats underwent surgery and 18 h later received saline or TPN or TPN+GH for 6 h before they were killed. Serum IGF-I levels were lower in all CLP groups (P<0.001). The combination of TPN and GH treatment increased IGF-I levels compared with the saline-treated CLP rats (P<0.01), but IGF-I levels remained lower than control animals (P<0.001). GH receptor and GH-binding protein expression in liver was reduced in animals subjected to CLP and was unaffected by nutrition or GH treatment. Hepatic SOCS-1 was detectable in normal rats, induced in all CLP animals but was unaffected by nutrition and GH. Hepatic SOCS-2 expression was difficult to detect in normal and CLP rats but was greatly induced in CLP rats treated with GH. Hepatic SOCS-3 expression was only just detectable in the control group but was elevated in all CLP groups and unaffected by nutrition and GH. Hepatic CIS expression was difficult to detect in normal rats, was not induced by CLP but was induced by both nutrition and GH. In conclusion, CLP induced low IGF-I levels associated with increased expression of SOCS-1 and SOCS-3, both of which are known to inhibit GH receptor signalling. GH induced SOCS-2 and CIS in the CLP rat despite resistance with respect to IGF-I generation, and parenteral feeding induced CIS in the CLP rat. Thus, there is potential for a complex interaction between GH and cytokine signalling at the level of SOCS expression whereby the inflammatory response may alter GH signalling and GH may influence the inflammatory response.

Comparative effects of acute ethanol dosage on liver and muscle protein metabolism.

Experiments were performed to address some outstanding issues and investigate possible mechanisms relating to the acute comparative effects of ethanol on liver and skeletal muscle protein metabolism. Ethanol (EtOH)-treated rats were injected (i.p.) with a bolus of EtOH (75 mmol/kg body weight) and sacrificed at 20 min, 1-, 2.5-, 6-, and 24-hr time points. Control rats were injected with saline (Con-Sal; 0.15 mmol/L NaCl). All 24-hr ethanol-treated animals were compared with saline-injected rats subjected to controlled feeding (i.e. pair-fed controls for 24 hr EtOH). At 24 hr, there was no measurable alcohol in the plasma, whereas high levels were seen from 20 min to 6 hr (up to 448 mg/dL). Plasma levels of albumin were reduced at initial time points, and activities of aspartate aminotransferase increased, but there was no histological evidence of overt tissue damage either in muscle or liver. Hepatic protein and RNA contents and indices of tissue (C(s) and k(s)) and whole-body (V(s)) protein synthesis were significantly increased in ethanol-dosed rats relative to saline-injected pair-fed controls at 24 hr. In the liver, four of the seven cytoplasmic proteases investigated (alanyl-, arginyl-, and pyroglutamyl-aminopeptidases and proline-endopeptidase) showed significant increases in activity at 24 hr relative to pair-fed controls; four of the six lysosomal proteases showed significant decreases in activity (dipeptidyl-aminopeptidase II and cathepsins B, L, and H). In skeletal muscle, k(s) fell progressively between 1 and 24 hr (-25 to -69%; P < 0.001), but no significant changes in skeletal muscle protease activities were seen at 24 hr. At 24 hr after ethanol dosage in vivo, there were no significant increases in protein carbonyl content in liver or skeletal muscle compared to pair-fed controls (muscle levels actually decreased slightly). However, using either rat or human tissue, both liver and muscle carbonyl increased in vitro in response to superoxide and hydroxyl radicals: muscle was more susceptible to carbonyl formation than liver and both tissues were more sensitive to hydroxyl compared to superoxide radicals. These results show divergent effects of acute ethanol treatment on liver and skeletal muscle protein metabolism, which may not be linked to in vivo free radical-mediated protein damage (as indicated by carbonyl formation), at least in the short term.

Metabolic consequences of alcohol ingestion.

Many of the pathophysiological effects of alcohol ingestion relate to the pathways of ethanol metabolism. However, some of the acute and chronic effects of ethanol use are also attributable to the direct effects of ethanol, e.g. on membrane fluidity. Oxidation of ethanol to acetaldehyde is catalysed by alcohol dehydrogenase (ADH). There are at least six classes of ADH, some of which show inter-individual variation, i.e. genetic polymorphism, that influences the rate of ethanol oxidation. A consequence of ethanol oxidation is an increase in the NADH/NAD redox potential within the cytosol and mitochondria with subsequent alteration in several tissue metabolites. The popular hypothesis that most, if not all, of the consequences of chronic alcohol ingestion can be explained by these redox changes is still unproven. This should be considered in the context that most metabolic pathways of the liver are affected by alcohol, as are several endocrine axes in the whole body. In fact most, if not all, tissues and organs are deleteriously affected by chronic ingestion. Acetaldehyde, the product of ethanol oxidation, is chemically highly reactive, toxic and immunogenic. However, the concentrations achieved in vivo usually fall short of those used to produce these toxic effects in experimental situations. Oxidation of acetaldehyde is also coupled to redox changes, although primarily affecting the intra-mitochondrial redox. In addition, further oxidative pathways of ethanol metabolism can lead to the formation of fatty acid ethyl esters, hydroxyethyl free radicals and reactive oxygen species via the ethanol-specific cytochrome P450-2E1 system. There is no conclusive evidence that nutrient supplementation has beneficial effects on overall ethanol-mediated tissue damage.

Alcohol and the myocardium.

Structural and functional abnormalities are prominent in alcoholic cardiomyopathy (ACM). Histological features in affected subjects are almost identical to the characteristics of dilated cardiomyopathy. Quantitative morphometry, however, can distinguish between ACM and dilated cardiomyopathy. Biopsies from patients with ACM show increases in the activities of some myocardial enzymes (alpha-hydroxybutyric dehydrogenase, creatine kinase, lactate dehydrogenase, malic dehydrogenase) which are correlated with the bimodal distribution of alcohol intake and may represent an adaptive response. One-third of patients with ACM have serum antibodies against cardiac acetaldehyde-protein adducts. Animal models of ethanol toxicity have shown that acutely, alcohol and acetaldehyde reduce the synthesis of cardiac contractile proteins in vivo. Two-dimensional SDS-PAGE has also shown that in rats chronically fed alcohol, the relative amounts of over 10% of heart muscle proteins are altered. The heat shock proteins (HSP) Hsp60 and Hsp70 are decreased in alcohol-fed rats, as is desmin. Reduction in HSPs may indicate reduced myocardial protection whilst a fall in desmin may indicate structural defects. In conclusion, ACM is a complex process that is due to altered protein synthesis, the formation of acetaldehyde adducts and a reduction of cardiac HSPs and desmin. Both acetaldehyde and alcohol are myocardial perturbants.

Biochemical and muscle studies in patients with acute onset post-viral fatigue syndrome.

AIMS: To investigate in detail various biochemical and pathophysiological indices of muscle pathology in acute onset post-viral fatigue syndrome (PVFS). METHODS: Twenty three patients with PVFS (of mean duration 4.6 years) were subjected to needle biopsy for histomorphometry and total RNA contents. Plasma analysis included serology and creatine kinase activities. Indices of whole body mass were also measured--namely, whole body potassium content and plasma carnosinase activities. RESULTS: About 80% of the patients had serology indicative of persistent enteroviral infection as determined by VP1 antigen assay. Only about 10% of that same group of patients had serological indications of current enterovirus infection by IgM assay; a separate subset of 10% showed antibody changes suggestive of reactivation of Epstein-Barr virus. Quantitative morphometric analysis of skeletal muscle fibres indicated that the quadriceps muscle was normal or displayed only minor abnormalities in 22 patients. The Quetelet's Index (body mass index) and whole-body potassium values (index of lean body mass) were not affected in PVFS. The mean plasma carnosinase and creatinine kinase activities were also generally normal in these patients. The mean muscle RNA composition--mg RNA/mg DNA: was significantly reduced in acute onset PVFS by about 15%. The protein:DNA ratio was not significantly affected. CONCLUSIONS: Patients with acute onset PVFS, therefore, lose muscle protein synthetic potential, but not muscle bulk. Histopathology is consistent with these observations. These perturbations may contribute to the apparent feature of perceived muscle weakness associated with the persistent viral infection in the muscle themselves.

In rats with sepsis, the acute fall in IGF-I is associated with an increase in circulating growth hormone-binding protein levels.

OBJECTIVE: Growth hormone (GH) given to reverse muscle catabolism in critical illness increased mortality, illustrating the need for better understanding of the pathophysiology of the GH axis. We describe the relationship between changes in plasma insulin-like growth factor-I (IGF-I) and growth hormone-binding protein (GHBP) levels and hepatic growth hormone-binding in rats with sepsis. DESIGN: Randomised, controlled study. SETTING: University research laboratory. SUBJECTS: One hundred and eleven male Wistar rats. INTERVENTION: Three groups of rats underwent caecal ligation and puncture (CLP) and three groups laparotomy only (LAP). Survivors were killed at 24, 72, and 96 h. All animals were starved during the study. Twelve rats were killed at the start of the experiment (baseline) and twelve (allowed food) at 96 h. MEASUREMENTS AND RESULTS: Plasma levels of IGF-I and GHBP and binding of 125I-labelled human GH in liver homogenates were measured. IGF-I fell significantly following both CLP and LAP; at 24 h, IGF-I levels were lower after CLP than LAP (950 +/- 74 vs 1,522 +/- 60 microg/l, P = < 0.001). GHBP increased at 24 h following both CLP and LAP (45.6 +/- 1.87 and 47.7 +/- 3.01 vs 38.7 +/- 1.98 ng/ml at baseline, P = < 0.05). In LAP animals GHBP fell to below baseline by 72 h, and significantly so by 96 h (33.5 +/- 1.43, P = < 0.05), whereas GHBP remained elevated 72 h following CLP, returning to baseline by 96 h. The density of GH-binding sites in liver tended to increase, following both CLP and LAP at both 24 and 96 h, but these changes failed to achieve statistical significance. CONCLUSION: Reduced IGF-I levels in sepsis in the rat are associated with elevations in GHBP and a trend to increased hepatic GH binding. This suggests that in sepsis 'GH resistance' is not associated with reduced GH receptor numbers.

Acute exposure to the nutritional toxin alcohol reduces brain protein synthesis in vivo.

Few studies have measured brain protein synthesis in vivo using reliable methods that consider the precursor pool, and there is a paucity of data on the regional sensitivity of this organ to nutritional or toxic substances. We hypothesized that different areas of the brain will exhibit variations in protein synthesis rates, which might also be expected to show different sensitivities to the nutritional toxin, ethanol. To test this, we dosed male Wistar rats with ethanol (75 mmol/kg body weight) and measured rates of protein synthesis (ie, the fractional rate of protein synthesis, defined as the percentage of the protein pool renewed each day; k(s), %/d) in different brain regions 2.5 hours later with the flooding dose method using L-[4-(3)H] phenylalanine. In the event that some regions were refractory to the deleterious effects of ethanol, we also predosed rats with cyanamide, an aldehyde dehydrogenase inhibitor (ie, cyanamide + ethanol), to increase endogenous acetaldehyde, a potent neurotoxic agent. The results indicated the mean fractional rates of protein synthesis in the cortex was 21.1%/d, which was significantly lower than either brain stem (30.2%/d, P <.025), cerebellum (30.1%/d, P <.01), or midbrain (29.8%, P <.025). Ethanol significantly decreased protein synthesis in the cortex (21%, P < 0.01), cerebellum (19%, P <.025), brain stem (44%, P <.025), but not in the midbrain (not significant [NS]). However, significant reductions in protein synthesis in the midbrain occurred in cyanamide + ethanol-dosed rats (60%, P <.0001). Cyanamide + ethanol treatment also reduced k(s) in the brain stem (66%, P <.001), cortex (59%, P <.001), and cerebellum (55%, P <.001). In conclusion, the applicability of the flooding dose technique to measure protein synthesis in the brain in vivo is demonstrated by its ability to measure regional difference. Impaired protein synthesis rates may contribute to or reflect the pathogenesis of alcohol-induced brain damage.

Alcohol increases c-myc mRNA and protein in skeletal and cardiac muscle.

The pathogenic mechanisms responsible for alcohol-induced muscle disease are unknown, although it is possible that increased proto-oncogene expression may be the causative process. Therefore, we investigated the responses of skeletal muscle c-myc protein and mRNA to a standard acute ethanol dosage regimen (75 mmol/kg/body weight [BW]) for 2.5 to 24 hours. Comparative studies were made on the heart. Acute ethanol administration in vivo led to an increase in c-myc proto-oncogene mRNA in rat skeletal and cardiac muscle. The changes in c-myc mRNA were mirrored by increases in the c-myc protein as demonstrated by immunohistochemistry. The changes in the c-myc protein were localized to the myonuclei, with no corresponding changes seen in the interstitial cell nuclei. This is the first report of altered proto-oncogene expression in muscle in response to ethanol. Increased c-myc mRNA and protein may reflect adaptive changes, a stress response, or another uncharacterized cellular adaptation.

Effect of acute and chronic alcohol treatment and their superimposition on lysosomal, cytoplasmic, and proteosomal protease activities in rat skeletal muscle in vivo.

Alcohol can be considered as a nutritional toxin when ingested in excess amounts and leads to skeletal muscle myopathy. We hypothesized that altered protease activities contribute to this phenomenon, and that differential effects on protease activities may occur when: (1) rats at different stages in their development are administered alcohol in vivo; (2) acute ethanol treatment is superimposed on chronic alcohol-feeding in vivo; and (3) muscles are exposed to alcohol and acetaldehyde in vivo and in vitro. In acute studies, rats weighing approximately 0.1 kg (designated immature) or approximately 0.25 kg (designated mature) body weight (BW) were dosed acutely with alcohol (75 mmol/kg BW; intraperitoneal [IP], 2.5 hours prior to killing) or identically treated with 0.15 mol/L NaCl as controls. In chronic studies, rats (approximately 0.1 kg BW) were fed between 1 to 6 weeks, with 35% of dietary energy as ethanol, controls were identically treated with isocaloric glucose. Other studies included administration of cyanamide (aldehyde dehydrogenase inhibitor) in vivo or addition of alcohol and acetaldehyde to muscle preparations in vitro. At the end of the treatments, cytoplasmic (alanyl-, arginyl-, leucyl-, prolyl-, tripeptidyl-aminopeptidase and dipeptidyl aminopeptidase IV), lysosomal (cathepsins B, D, H, and L, dipeptidyl aminopeptidase I and II), proteasomal (chymotrypsin-, trypsin-like, and peptidylglutamyl peptide hydrolase activities) and Ca(2+)-activated (micro- and milli-calpain and calpastatin) activities were assayed. (1) Acute alcohol dosage in mature rats reduced the activities of alanyl-, arginyl- and leucyl aminopeptidase (cytoplasmic), dipeptidyl aminopeptidase II (lysosomal), and the chymotrypsin- and trypsin-like activities (proteosomal). No significant effects were observed in similarly treated immature rats. (2) Alcohol feeding in immature rats did not alter the activities of any of the enzymes assayed at 6 weeks. (3) In immature rats, activities of cathepsins B and D were not overtly affected at either 3, 7, 14, 28, or 42 days. (4) Superimposing acute (2.5 hours) on chronic (4 weeks feeding of immature rats) ethanol treatment (ie, chronic + acute) reduced the activities of cytoplasmic proline aminopeptidase and the chymotrypsin- and trypsin-like activities of the proteasome. (5) Cathepsin D activities were reduced in muscle homogenates upon addition of alcohol and acetaldehyde in vitro. (6) Cyanamide pretreatment in combination with alcohol dosage in immature rats did not significantly alter any protease activities. The data suggests that mature rats are more sensitive to the effects of acute alcohol on muscle proteases. Protease activities may be affected by acetaldehyde or alcohol levels as indicated by in vitro experiments. The reduction in muscle protease activities in chronic + acute alcohol superimposition may reflect the effect of acute alcohol dosage alone. Overall, there was no evidence for increased protease activity in any of the experimental situations.