Unacylated ghrelin normalizes skeletal muscle oxidative stress and prevents muscle catabolism by enhancing tissue mitophagy in experimental chronic kidney disease.

Unacylated ghrelin (UnAG) may lower skeletal muscle oxidative stress, inflammation, and insulin resistance in lean and obese rodents. UnAG-induced autophagy activation may contribute to these effects, likely involving removal of dysfunctional mitochondria (mitophagy) and redox state maintenance. In chronic kidney disease (CKD) oxidative stress, inflammation and insulin resistance may negatively influence patient outcome by worsening nutritional state through muscle mass loss. Here we show in a 5/6 nephrectomy (Nx) CKD rat model that 4 d s.c. UnAG administration (200 µg twice a day) normalizes CKD-induced loss of gastrocnemius muscle mass and a cluster of high tissue mitochondrial reactive oxygen species generation, high proinflammatory cytokines, and low insulin signaling activation. Consistent with these results, human uremic serum enhanced mitochondrial reactive oxygen species generation and lowered insulin signaling activation in C2C12 myotubes while concomitant UnAG incubation completely prevented these effects. Importantly, UnAG enhanced muscle mitophagy in vivo and silencing RNA-mediated autophagy protein 5 silencing blocked UnAG activities in myotubes. UnAG therefore normalizes CKD-induced skeletal muscle oxidative stress, inflammation, and low insulin signaling as well as muscle loss. UnAG effects are mediated by autophagy activation at the mitochondrial level. UnAG administration and mitophagy activation are novel potential therapeutic strategies for skeletal muscle metabolic abnormalities and their negative clinical impact in CKD.-Gortan Cappellari, G., Semolic, A., Ruozi, G., Vinci, P., Guarnieri, G., Bortolotti, F., Barbetta, D., Zanetti, M., Giacca, M., Barazzoni, R. Unacylated ghrelin normalizes skeletal muscle oxidative stress and prevents muscle catabolism by enhancing tissue mitophagy in experimental chronic kidney disease.

Unacylated Ghrelin: A Novel Regulator of Muscle Intermediate Metabolism With Potential Beneficial Effects in Chronic Kidney Disease.

In patients with chronic kidney disease (CKD), malnutrition with loss of skeletal muscle mass has a negative impact on morbidity and mortality. Emerging evidence indicates that a cluster of oxidative stress, inflammation, and insulin resistance directly contributes to skeletal muscle catabolism by favoring protein breakdown over synthesis. Ghrelin is a gastric hormone discovered and initially studied in its acylated orexigenic form. More recently, a role of unacylated ghrelin (UnAG) has been described to reduce skeletal muscle mitochondrial reactive oxygen species generation, inflammation, and insulin resistance both in experimental models and in clinical studies. UnAG administration could therefore represent a potential comprehensive therapeutic approach for CKD-related metabolic and nutritional complications. Studies of UnAG administration in experimental and clinical CKD are needed to test the hypothesis that UnAG may chronically improve nutritional status and outcome in CKD patients.

Carnitine in maintenance hemodialysis patients.

Carnitine is a conditionally essential metabolite that plays a critical role in cell physiology. Carnitine is necessary for fatty acid transport to sites of beta-oxidation in the mitochondria, where it also helps to prevent organic acid accumulation. Because of these key regulatory functions, carnitine represents a crucial determinant of mitochondrial energy metabolism, whose deficiency may lead to metabolic and clinical disturbances. Loss of carnitine through dialytic membranes occurs in maintenance hemodialysis, resulting in potential carnitine depletion and relative increments of esterified carnitine forms. Carnitine supplementation has been reported to counteract some of these alterations and has been associated with some clinical benefits, such as enhanced response to erythropoietin as well as improvement in exercise tolerance, intradialytic symptom, hyperparathyroidism, insulin resistance, inflammatory and oxidant status, protein balance, lipid profile, cardiac function, and quality of life. Carnitine supplementation has an attractive theoretical rationale; however, there are no definitive supportive studies and conclusive evidence that L-carnitine supplementation in maintenance hemodialysis patients could improve these conditions. A trial of carnitine administration could be attempted for 6 to 12 months only in selected patients on dialysis who do not adequately respond to standard therapies, in the presence of symptomatology, and in conjunction with patient dialysis age and documented L-carnitine deficiency.

Obesity and high waist circumference are associated with low circulating pentraxin-3 in acute coronary syndrome.

BACKGROUND: Long pentraxin 3 (PTX3) is a component of the pentraxin superfamily and a potential marker of vascular damage and inflammation, associated with negative outcome in patients with acute coronary syndromes (ACS). Obesity is a risk factor for cardiovascular disease and PTX3 production is reported in abdominal adipose tissue. Low PTX3 is however reported in the obese population, and obesity per se may be associated with less negative ACS outcome. METHODS: We investigated the potential impact of obesity and high waist circumference (reflecting abdominal fat accumulation) on plasma PTX3 concentration in ACS patients (n = 72, 20 obese) compared to age-, sex- and BMI-matched non-ACS individuals. RESULTS: Both obese and non-obese ACS patients had higher PTX3 than matched non-ACS counterparts, but PTX3 was lower in obese than non-obese individuals in both groups (all P < 0.05). PTX3 was also lower in ACS subjects with high than in those with normal waist circumference (WC). Plasma PTX3 was accordingly associated negatively with BMI and WC, independently of age and plasma creatinine. No associations were observed between PTX3 and plasma insulin, glucose or the short pentraxin and validated inflammation marker C-reactive protein, that was higher in ACS than in non-ACS individuals independently of BMI or WC. CONCLUSIONS: Obesity is associated with low circulating PTX3 in ACS. This association is also observed in the presence of abdominal fat accumulation as reflected by elevated waist circumference. Low PTX3 is a novel potential modulator of tissue damage and outcome in obese ACS patients.

Sarcopenic obesity in free-living older adults detected by the ESPEN-EASO consensus diagnostic algorithm: Validation in an Italian cohort and predictive value of insulin resistance and altered plasma ghrelin profile.

Aging and obesity are synergistic sarcopenia risk factors (RF). Their association in sarcopenic obesity (SO) enhances morbidity and mortality, but consensus on SO diagnostic criteria is limited. ESPEN and EASO issued a consensus algorithm for SO screening (obesity and clinical SO suspicion) and diagnosis [low muscle strength by hand-grip (HGS) and low muscle mass by BIA], and we investigated its implementation in older adults (>65-years), as well as SO-associated metabolic RF [insulin resistance (IR: HOMA) and plasma acylated (AG) and unacylated (UnAG) ghrelin, with predictive value also assessed from 5-year-prior observations]. Older adults with obesity from the Italian MoMa study on metabolic syndrome in primary care (n = 76) were studied. 7 of 61 individuals with positive screening had SO (SO+; 9 % of cohort). No individuals with negative screening had SO. SO+ had higher IR, AG and plasma AG/UnAG ratio (p < 0.05 vs negative screening and SO-), and both IR and ghrelin profile predicted 5-year SO risk independent of age, sex and BMI. The current results provide the first ESPEN-EASO algorithm-based investigation of SO in free-living older adults, with 9 % prevalence in those with obesity and 100 % algorithm sensitivity, and they support IR and plasma ghrelin profile as SO risk factors in this setting.

Ghrelin and muscle metabolism in chronic uremia.

Patients with chronic kidney disease (CKD) are prone to nutritional complications with negative prognostic impact. In particular, protein-energy wasting is a major CKD-associated clinical burden, and emerging evidence indicates that clustered metabolic alterations, including inflammation, oxidative stress, and insulin resistance, contribute to loss of skeletal muscle mass. Ghrelin is a gastric hormone discovered in its acylated form and extensively studied for its appetite-stimulating effect. Further studies have shown that ghrelin may positively modulate systemic inflammation and insulin action. In addition, a role of ghrelin in the regulation of redox state has been described in vitro. Ghrelin treatment could therefore represent a potential comprehensive therapeutic approach for CKD-related metabolic and nutritional complications, and evidence supporting this hypothesis has emerged in clinical and experimental CKD. Clinical trials of ghrelin administration are needed to test the hypothesis that ghrelin may chronically improve nutritional status and outcome in CKD patients.

High plasma retinol binding protein 4 (RBP4) is associated with systemic inflammation independently of low RBP4 adipose expression and is normalized by transplantation in nonobese, nondiabetic patients with chronic kidney disease.

OBJECTIVE: Adipose-secreted retinol binding protein 4 (RBP4) circulates in free (active) and transthyretin (TTR)-bound forms and may be associated with obesity-related inflammation. Potential involvement of plasma and adipose RBP4 in systemic inflammation in the absence of obesity and diabetes is unknown. Inflammation reduces survival in chronic kidney disease (CKD) [particularly in maintenance haemodialysis (MHD)], and plasma RBP4 may increase with renal dysfunction. We investigated (i) potential associations between RBP4 and inflammation in CKD and (ii) the role of adipose tissue in this putative interaction. DESIGN: Cross-sectional. PATIENTS: Nonobese, nondiabetic patients with CKD undergoing conservative (CT: n = 10) or MHD treatment (n = 25) and healthy control subjects (C: n = 11). Renal transplant recipients (n = 5) were studied to further assess the impact of restored near-normal renal function. MEASUREMENTS: Plasma RBP4, TTR and C-reactive protein (CRP), adipose RBP4 expression. RESULTS: Plasma RBP4, TTR and CRP were highest in MHD (P < 0·05). Adipose RBP4 mRNA was, however, comparably low in CT and MHD (P < 0·05 vs C), and all parameters were normalized in transplant recipients (P < 0·05 vs MHD). In all subjects (n = 51), creatinine and TTR (P < 0·05) but not adipose RBP4 mRNA were associated with plasma RBP4. Plasma RBP4 but not its adipose expression was in turn associated positively (P < 0·05) with CRP independently of creatinine-TTR. CONCLUSIONS: High plasma RBP4 and inflammation are clustered in CKD in the absence of obesity and diabetes and are normalized by transplantation. Adipose RBP4 expression is not involved in plasma RBP4 elevation, which appears to be mainly because of passive accumulation, or in CKD-associated inflammation.

Fighting protein-energy wasting in chronic kidney disease: a challenge of complexity.

Chronic uremia is often characterized by wasting of muscle and fat mass, which has been defined as protein-energy wasting (PEW), and is responsible for substantial worsening of patient outcome in terms of morbidity and mortality, mostly from cardiovascular events. Despite major advances in patient treatment, nutritional outcome in patients with end-stage renal disease has not improved substantially in recent years. Extensive research in this field has provided plausible explanations for this limitation by indicating that the pathogenesis of PEW in kidney disease is complex and multifactorial. Complexity involves underlying metabolic alterations, including inflammation, oxidative stress, and insulin resistance. In addition, patient heterogeneity is increasing with large numbers of obese individuals as a result of the ongoing obesity epidemics. Several tissues are involved in cross-talk and contribute to metabolic derangements, including adipose tissue, the gut, and the central nervous system, with novel mediators including the gastric hormone ghrelin. Acknowledging its complex pathogenesis may favor the development of novel and more effective therapeutic tools for PEW. These should ideally be effective in treating the underlying common mechanisms of wasting, which appear to include oxidative stress, inflammation, and insulin resistance.

Hemodialysis induces p66(shc) gene expression in nondiabetic humans: correlations with oxidative stress and systemic inflammation.

OBJECTIVE: Oxidative stress and inflammation characterize hemodialysis (HD) and are associated with malnutrition, cardiovascular disease, and poor clinical outcome. p66(shc) stimulates oxidative stress and atherogenesis. The objective of the present study was to assess p66(shc) expression levels in HD and their associations with inflammatory and oxidative stress markers. DESIGN: p66(shc) messenger ribonucleic acid (mRNA) was compared with systemic oxidative stress and inflammation markers in control subjects and patients on HD before and after a single HD session in a cross-sectional analysis. SETTING: Outpatient hemodialysis unit. PATIENTS: The study included stable HD patients (n = 21, men/women: 18/3) who were on HD 3 times per week for a minimum of 8 weeks; age-matched control subjects (n = 22, men/women:17/5). MAIN OUTCOME MEASURE: mRNA levels of p66(shc), tumor necrosis factor α (TNF-α), and pentraxin 3 (PTX3), p66(shc) protein levels in white blood cells, lipid peroxidation (in the form of plasma thiobarbituric acid-reactive substance [TBARS]) and serum C-reactive protein. RESULTS: In patients on dialysis, of the p66(shc), TNF-α, and PTX3 mRNAs, p66(shc) protein levels were higher (P < .05) than in control subjects, as well as plasma TBARS and C-reactive protein (P < .05). p66(shc) mRNA directly correlated with TBARS (r = 0.69, P = .0005) and with TNF-α mRNA (r = 0.63, P = .003). These associations were confirmed in the whole study population (TBARS: r = 0.541, P = .0003; TNF-α: r = 0.581, P < .0001), whereas in the control group only the positive association between p66(shc) and TNF-α was detected. TNF-α was directly correlated with PTX3 both in HD patients (r = 0.72, P = .0005) and in the whole study group (r = 0.678, P < .0001). The dialysis session affected neither p66(shc) and TNF-α mRNA nor p66(shc) protein expression, whereas it further increased (P = .002) PTX3 mRNA. As compared with predialysis levels, TBARS were reduced (P < .05) after dialysis. In these conditions, p66(shc) remained directly correlated with TNF-α (r = 0.901, P < .0001). CONCLUSIONS: Increased p66(shc) gene expression correlates with TNF-α mRNA and with levels of markers of oxidative stress in HD. We suggest a novel link between HD-associated inflammation and p66(shc) gene expression contributing to systemic oxidative stress.

Combined effects of ghrelin and higher food intake enhance skeletal muscle mitochondrial oxidative capacity and AKT phosphorylation in rats with chronic kidney disease.

Skeletal muscle mitochondrial dysfunction and insulin resistance occur in chronic kidney disease. Ghrelin is a gastric hormone previously shown to enhance muscle mitochondrial enzyme activities and AKT-mediated insulin signaling independent of food intake in healthy rats. Here we determined the impact of ghrelin treatment on anorexia, skeletal muscle mitochondrial oxidative capacity, AKT phosphorylation as a measure of insulin signaling, and lean body mass in a rat model of chronic kidney disease. Ghrelin infusion promoted higher food intake and lean body mass. Further, although muscle mitochondrial enzyme activities were low in the rats with CKD (chronic kidney disease), they normalized with ghrelin treatment, a change that was consistent with the increase in the transcript levels of regulators of mitochondrial biogenesis and lipid metabolism. This was associated with a lower muscle triglyceride content and higher AKT phosphorylation. Pair-feeding showed that mitochondrial effects of ghrelin are independent of changes in food intake, whereas combined ghrelin treatment and higher food intake were needed to enhance AKT phosphorylation. Thus, ghrelin-induced muscle mitochondrial changes and lower tissue triglycerides could favor insulin action and muscle anabolism in the presence of improvement in food intake. Our study shows that combined effects of ghrelin on appetite and muscle mitochondria improve muscle metabolic and nutritional alterations in chronic kidney disease. This could have potential beneficial impact on patient morbidity and survival.

Metabolic syndrome and chronic kidney disease.

Obesity is a global health threat because of its associated metabolic and cardiovascular complications. Metabolic and hemodynamic complications of obesity (insulin resistance and hyperglycemia, hypertension, atherogenic dyslipidemia) are often clustered in the metabolic syndrome, leading to high cardiovascular morbidity and mortality. In recent years, epidemiological studies have clearly indicated that both obesity and the metabolic syndrome are independent risk factors for chronic kidney disease and these associations are at least in part independent of diabetes and hypertension per se. Additional mechanisms associated with obesity and metabolic syndrome leading to reduced renal function may include altered levels of adipose tissue hormones, inflammation, and oxidative stress. The ongoing worldwide obesity epidemic is therefore likely to increase the number of patients with chronic uremia and features of the metabolic syndrome in the next few years. Moreover, the onset and maintenance of renal damage may worsen metabolic syndrome features including insulin resistance and hypertension, leading to potential vicious cycles with negative clinical effect. Further understanding of the interactions between obesity, metabolic syndrome, and chronic kidney disease represents a potential strategy to design more effective treatments aimed at reducing morbidity and mortality in uremic patients.

Role of E2F1-cyclin E1-cyclin E2 circuit in human coronary smooth muscle cell proliferation and therapeutic potential of its downregulation by siRNAs.

Aberrant coronary vascular smooth muscle cell (CSMC) proliferation is a pivotal event underlying intimal hyperplasia, a phenomenon impairing the long-term efficacy of bypass surgery and angioplasty procedures. Consequently research has become focused on efforts to identify molecules that are able to control CSMC proliferation. We investigated downregulation of CSMC growth by small interfering RNAs (siRNAs) targeted against E2F1, cyclin E1, and cyclin E2 genes, whose contribution to CSMC proliferation is only now being recognized. Chemically synthesized siRNAs were delivered by two different transfection reagents to asynchronous and synchronous growing human CSMCs cultivated either in normo- or hyperglycemic conditions. The depletion of each of the three target genes affected the expression of the other two genes, demonstrating a close regulatory control. The clearest effects associated with the inhibition of the E2F1-cyclin E1/E2 circuit were the reduction in the phosphorylation levels of the retinoblastoma protein pRB and a decrease in the amount of cyclin A2. At the phenotypic level the downmodulation of CSMC proliferation resulted in a decrease of S phase matched by an increase of G1-G0 phase cell amounts. The antiproliferative effect was cell-donor and transfectant independent, reversible, and effective in asynchronous and synchronous growing CSMCs. Importantly, it was also evident in hyperglycemia, a condition that underlies diabetes. No significant aspecific cytotoxicity was observed. Our data demonstrate the interrelation among E2F1-cyclin E1-cyclin E2 and the pivotal role this circuit exerts in CSMC proliferation. Additionally, our work validates the concept of utilizing anti-E2F1-cyclin E1-cyclin E2 siRNAs to develop a potential novel therapy to control intimal hyperplasia.

Inhibitory effects of fenofibrate on apoptosis and cell proliferation in human endothelial cells in high glucose.

Fenofibrate has beneficial effects on the progression and clinical emergence of atherosclerosis in normoglycemic and in diabetic patients. Given the involvement of endothelium in these processes, we speculated that fenofibrate may influence endothelial cell apoptosis and proliferation, regulators of endothelium integrity. Fenofibrate effects on apoptosis and proliferation were studied in human umbilical vein endothelial cells under normal (5.5 mmol/l, NG) and high (22 mmol/l, HG) glucose with or without fenofibrate (50 micromol/l). Apoptosis was evaluated by annexin V, by poly(ADP-ribose) polymerase protein cleavage, and cyclooxygenase-2 (COX-2), Bax/Bcl-2, and p53 protein levels; proliferation was assessed by determining cell cycle phase distribution and the amounts of the cell cycle regulators E2F1, cyclin D1, E1, and A and the levels of the hyper-phosphorylated form of the retinoblastoma protein (ppRb). HG resulted in increased (p<0.05) apoptosis rate associated with COX-2 protein overexpression, without modification of Bax/Bcl2 ratio and p53 levels. Fenofibrate decreased apoptosis and normalized increased COX-2 expression in HG (p<0.05). Both in HG and NG, fenofibrate dramatically reduced cell proliferation (p<0.05) through a G1/G0 block mediated by the reduction in ppRb and the decrease in E2F1, cyclin E1, A, and D1 protein expression, with a mechanism that, for cyclin E1, occurred at the posttranscriptional level. In conclusion, our data show that fenofibrate reduces apoptosis caused by HG but severely interferes with endothelial cell proliferation both in NG and HG. The resulting effect may influence endothelium integrity in vivo and may impact the outcome of acute complications of atherosclerosis in diabetes.

Insulin resistance in chronic uremia.

Insulin resistance often characterizes chronic uremia, and is associated with enhanced morbidity and mortality, because it may contribute to protein-energy wasting (in turn, an independent predictor of reduced survival), atherosclerosis, and cardiovascular death. Causes of insulin resistance in chronic uremia are complex and multifactorial. Obesity is emerging as an independent risk factor for chronic kidney disease, and an expected rise in number of obese uremic patients because of the ongoing worldwide obesity epidemic is likely to increase the prevalence of insulin resistance in chronic uremia in the near future. Similar to the general population, reported associations between obesity and insulin resistance in chronic uremia support a role of adipose tissue and altered adipokine profiles in insulin resistance in obese chronic kidney disease patients. Hormonal imbalances, chronic acidosis, and systemic inflammation and oxidative stress are uremia-associated relevant causes of insulin resistance in nonobese individuals. A further understanding of the causes of insulin resistance in chronic uremia represents a potential important tool in the design of more effective therapeutic strategies to reduce uremia-associated morbidity and mortality.

Central adiposity markers, plasma lipid profile and cardiometabolic risk prediction in overweight-obese individuals.

BACKGROUND: Waist circumference (WC) is the currently recommended marker of central fat for cardiometabolic risk screening. Alternative surrogate markers have been recently proposed to better reflect the metabolic impact of central fat accumulation per se, based on WC normalization by height (Weight-to-Height Ratio - WtoH; Body Roundness Index - BRI) or body mass index (BMI) without (A Body Shape Index - ABSI) or with inclusion of plasma triglyceride and HDL-cholesterol concentrations (Visceral Adiposity Index - VAI). METHODS: We investigated associations between WtoH, BRI, ABSI or VAI and insulin resistance (HOMA-index) or metabolic syndrome (MetS) in a general population cohort from the North-East Italy Mo.Ma. study (n = 1965, age = 49 ± 13 years, BMI = 26.7 ± 5.2 kg/m2). Baseline values were also evaluated as predictors of future insulin resistance and MetS in overweight-obese individuals undergoing 5-year follow-up (Ow-Ob) (n = 263; age = 54 ± 9, BMI = 30,7 ± 4,1). RESULTS: Compared to WC or BMI, basal WtoH and BRI were similarly associated with baseline HOMA and MetS prevalence after multiple adjustments (P < 0.001) and all markers similarly predicted 5-year HOMA and MetS (P < 0.001). Under basal conditions, superimposable results were observed for VAI whereas ABSI was less accurate or unable to identify baseline HOMA and MetS (p < 0.05 vs WtoH-BRI-VAI-WC-BMI). VAI had highest 5-year risk predictive value in Ow-Ob [ROC Area Under the Curve (AUC) VAI > WtoH-BRI-WC-BMI; p < 0.05] while no predictive value was in contrast observed for ABSI (ROC AUC ABSI < WtoH-BRI-WC-BMI; p < 0.05). Using alternate formulae with plasma lipid inclusion in ABSI and removal from VAI calculations completely reversed their 5-year predictive value and AUC. CONCLUSIONS: The current findings do not support replacement of WC with height-normalized anthropometric central fat surrogate markers to predict cardiometabolic risk in the general and overweight-obese population. BMI-normalization impairs risk assessment unless plasma lipid concentrations are available and included in calculations.

Physical inactivity decreases whole body glutamine turnover independently from changes in proteolysis.

Glutamine synthesis and utilization are strictly linked to energy metabolism and physical activity. To investigate the interaction between bed rest and moderate energy restriction on whole body glutamine kinetics in healthy volunteers, we performed a four-period study in which each subject randomly underwent a bed rest or ambulatory 14 day period both in eucaloric or hypocaloric (-20% of energy requirement) conditions. Glutamine kinetics were measured by l-[5-(15)N]glutamine and l-[1-(13)C]leucine primed continuous infusions in the postabsorptive state and during a 3 h infusion of a glutamine-free amino acid mixture (0.13 g amino acids (kg lean body mass (LBM))(-1) h(-1)). Bed rest decreased glutamine de novo synthesis in the postabsorptive state both in eucaloric (from 4.17 +/- 0.14 to 3.56 +/- 0.13 micromol (kg LBM)(-1) min(-1); P < 0.001) and in hypocaloric (from 3.79 +/- 0.19 to 3.49 +/- 0.14 micromol (kg LBM)(-1) min(-1); P < 0.001) conditions, independently of changes in whole body proteolysis. Bed rest did not affect glutamine clearance. We failed to detect either significant effects of energy intake or energy x activity interactions on glutamine kinetics. Bed rest significantly decreased postabsorptive plasma glutamine concentrations (P < 0.05). Amino acid infusion increased glutamine de novo synthesis rate and plasma glutamine concentrations in all conditions, without significant effects of bed rest or energy levels. We conclude that inactivity is associated with decreased whole body glutamine availability due to down-regulated de novo synthesis.

Calorie restriction modulates inactivity-induced changes in the inflammatory markers C-reactive protein and pentraxin-3.

CONTEXT: Energy balance and physical activity potentially influence systemic inflammation. OBJECTIVE: Our objective was to test the hypothesis that moderate energy restriction may prevent activation of inactivity-induced inflammatory response. DESIGN: Participants were studied four times at the end of 14-d periods of experimental bed rest or controlled ambulation, after receiving eucaloric or hypocaloric diets. SETTING: The study was conducted at the clinical research center of the German Space Agency. SUBJECTS: Nine healthy young volunteers participated. INTERVENTIONS: Energy intake was calibrated to physical activity and decreased by about 20% in hypocaloric conditions. MAIN OUTCOME MEASURES: Changes in body fat by dual-energy x-ray absorptiometry as well as plasma inflammatory markers and cytokine mRNA levels in blood cells were measured. RESULTS: Fat mass did not change significantly in eucaloric conditions and decreased in hypocaloric periods (-1.0 +/- 0.3 and -1.0 +/- 0.3 kg in ambulatory and bed rest, respectively). Bed rest in eucaloric conditions increased plasma C-reactive protein (CRP) (+143 +/- 53%) and both the ratios between plasma IL-6 and IL-10 (4+/-1 times) and white blood cell IL-6 and IL-10 mRNAs (5 +/- 1 times). Energy restriction prevented bed-rest-mediated increases in CRP and the IL-6 to IL-10 ratio. Bed rest increased (P = 0.03) long pentraxin-3 (PTX3) plasma concentration, without significant activity-by-diet interaction. In all conditions (n = 36), CRP and PTX3 were inversely correlated (r = -0.61; P < 0.001). Changes in fat mass, leptin, and IL-6 directly correlated with CRP and inversely correlated with PTX3. IL-10 inversely correlated with CRP and directly correlated with PTX3 (r = 0.52; P < 0.01). CONCLUSIONS: Calorie restriction prevents the inflammatory response induced by 14 d of bed rest. We suggest an inverse regulation of CRP and PTX3 in response to changes in energy balance.

Treating hyperglycemia improves skeletal muscle protein metabolism in cancer patients after major surgery.

OBJECTIVE: Cancer and surgical stress interact to aggravate insulin resistance, protein catabolism, and glutamine depletion in skeletal muscle. We compared the effects of insulin-mediated euglycemia and moderate hyperglycemia on kinetics of protein and selected amino acids in skeletal muscle of female cancer patients after major surgery. DESIGN: In each patient, a 24-hr period of insulin-mediated tight euglycemia (mean blood glucose, 5.8 +/- 0.4 mmol/L) preceded or followed a 24-hr control period of moderate hyperglycemia (mean blood glucose, 9.6 +/- 0.6 mmol/L) on the first and second day after surgery, in randomized order, according to a crossover experimental design. SETTING: Intensive care unit, cancer hospital. PATIENTS: Cancer patients after abdominal radical surgery combined with intraoperative radiation therapy. INTERVENTIONS: Intensive (57 +/- 11 units/24 hrs) and conventional (25 +/- 5 units/24 hrs) insulin treatment during total parenteral nutrition. MEASUREMENTS AND MAIN RESULTS: Muscle metabolism was assessed at the end of each 24-hr period of euglycemia and of hyperglycemia by leg arteriovenous catheterization with stable isotopic tracers. We found that euglycemia as compared with hyperglycemia was associated with higher (p < .05) fractional glucose uptake (16% +/- 4% vs. 9% +/- 3%); higher (p < .05) muscle protein synthesis and neutral net protein balance (-3 +/- 3 vs. -11 +/- 3 nmol phenylalanine x 100 mL(-1) x min(-1), respectively); lower (-52% +/- 12%, p < .01) muscle nonprotein leucine disposal (an index of leucine oxidation) and higher (p < .05) plasma leucine concentrations; and higher (3.6 +/- 1.7 times, p < .01) net de novo muscle glutamine synthesis and plasma glutamine concentrations (p < .05). Euglycemia was associated with higher (23% +/- 7%, p < .05) plasma concentrations of arginine but did not affect either arginine release from muscle or plasma concentration and muscle flux of asymmetrical dimethylarginine. Rate of muscle proteolysis correlated (p < .05) with muscle release of asymmetrical dimethylarginine. CONCLUSIONS: Treating hyperglycemia improves skeletal muscle protein and amino acid metabolism in cancer patients after major surgery.

Whey protein ingestion enhances postprandial anabolism during short-term bed rest in young men.

We tested the relative ability of rapidly digested whey and slowly digested casein to stimulate net whole-body protein synthesis during prolonged physical inactivity. We studied 8 young male volunteers after they consumed isonitrogenous casein or whey mixed meals on d 12 or d 14 of experimental bed rest. Rates of phenylalanine hydroxylation were measured by primed-constant oral administration of L[2-(2)H(2)]tyrosine and L[ring-(2)H(5)]phenylalanine for 3 h in the postabsorptive state and 6 h after an isonitrogenous bolus meal containing sucrose (0.27 g/kg) and casein or whey (0.40 g/kg). Net protein synthesis in the fed state was calculated during the first 6 h postmeal as the difference between phenylalanine hydroxylation and phenylalanine content in the ingested casein or whey. In the fed state, the integrated changes in phenylalanine hydroxylation were lower (P < 0.05) after whey (-2 +/- 8 micromol x kg(-1) x 6 h(-1)) than after casein ingestion (34 +/- 7 micromol x kg(-1) x 6 h(-1)). During bed rest, net postprandial protein synthesis was greater (P < 0.05) after whey (96 +/- 8 micromol phenylalanine x kg(-1) x 6 h(-1)) than after casein ingestion (82 +/- 7 micromol phenylalanine x kg(-1) x 6 h(-1)). The rapidly digested whey protein was more efficient than the slowly digested casein in increasing postprandial net protein synthesis during short-term bed rest.

Insulin action on glucose and protein metabolism during L-carnitine supplementation in maintenance haemodialysis patients.

BACKGROUND: Impaired protein anabolism and insulin resistance are characteristic features of maintenance haemodialysis patients. We have used a randomised, matched-paired, double-blind, placebo-controlled experimental design to determine the capability of intravenous L-carnitine supplementation to modify insulin resistance and protein catabolism in non-diabetic patients with end-stage renal disease (ESRD) undergoing chronic haemodialysis treatment. METHODS: L-carnitine (20 mg x kg(-1)) (n = 9) or placebo (n = 10) were given intravenously at the end of seven consecutive dialysis sessions. Whole-body protein and glucose metabolism were assessed on interdialytic days by the L[1-(13)C]leucine and the [2,2-(2)H(2)]glucose kinetic models in the postabsorptive state and during euglicemic hyperinsulinemic clamp studies at baseline and at the end of the treatment period. RESULTS: L-carnitine supplementation was associated with lower (P < 0.05) rates of leucine oxidation (-11 +/- 12%) and appearance from proteolysis (-6 +/- 2%) during the clamp studies than after placebo supplementation. The rates of glucose appearance in the postabsorptive state did not change significantly in the patients receiving L-carnitine treatment. Insulin-mediated glucose disappearance was improved by L-carnitine only in those patients (n = 5) (+18 +/- 3%, P < 0.05 vs placebo group, n = 5) with greater baseline insulin resistance, selected according to the median value of insulin sensitivity before treatment. CONCLUSIONS: L-carnitine supplementation was associated with protein-sparing effects in maintenance haemodialysis patients during hyperinsulinemia.