Project description:The skeletal muscle system plays an important role in the independence of older adults. In this study we examine differences in the skeletal muscle transcriptome between healthy young and older subjects and (pre‐)frail older adults. Additionally, we examine the effect of resistance‐type exercise training on the muscle transcriptome in healthy older subjects and (pre‐)frail older adults. Baseline transcriptome profiles were measured in muscle biopsies collected from 53 young, 73 healthy older subjects, and 61 frail older subjects. Follow‐up samples from these frail older subjects (31 samples) and healthy older subjects (41 samples) were collected after 6 months of progressive resistance‐type exercise training. Frail older subjects trained twice per week and the healthy older subjects trained three times per week. At baseline genes related to mitochondrial function and energy metabolism were differentially expressed between older and young subjects, as well as between healthy and frail older subjects. Three hundred seven genes were differentially expressed after training in both groups. Training affected expression levels of genes related to extracellular matrix, glucose metabolism, and vascularization. Expression of genes that were modulated by exercise training was indicative of muscle strength at baseline. Genes that strongly correlated with strength belonged to the protocadherin gamma gene cluster (r = −0.73). Our data suggest significant remaining plasticity of ageing skeletal muscle to adapt to resistance‐type exercise training. Some age‐related changes in skeletal muscle gene expression appear to be partially reversed by prolonged resistance‐type exercise training. The protocadherin gamma gene cluster may be related to muscle denervation and re‐innervation in ageing muscle.

Project description:No effect of calcifediol supplementation on skeletal muscle transcriptome in vitamin D deficient frail older adults.

Project description:Vitamin D insufficiency may exacerbate non-specific inflammation observed in older adults. Here, we tested the hypothesis that an inflammatory gene signature present in old skin following saline injection (as model for non-specific needle injury) normalizes after oral vitamin D3 supplementation. To define the saline-induced signature, we compared gene expression in skin biopsies taken six hours after saline injection in old adults (≥65 years) to biopsies from unmanipulated skin. We then assessed signature expression in saline-injected skin of old and young adults (<40 years), and in paired samples of old adults before and after oral vitamin D3 supplementation (6400 IU/day for 14 weeks), where median serum 25-hydroxyvitamin D increased from 43 nmol/L (interquartile range 36-53 nmol/L) to 131 nmol/L (interquartile range 115-147 nmol/L). This submission comprises 112 samples from 57 individuals.

Project description:Background: Periods of inactivity experienced by older adults induce nutrient anabolic resistance creating a cascade of skeletal muscle transcriptional and translational aberrations contributing to muscle dysfunction. Objective: To identify how inactivity alters leucine-stimulated translation of molecules and pathways within the skeletal muscle of older adults.

Project description:In a randomized controlled trial, 82 older adults (>65y) with (or at risk of) undernutrition (n=82) were randomly allocated to 12 weeks of supplementation with a novel supplement (586 kcal, 22 g protein of which 50% whey and 50% casein, 206 mg ursolic acid, 7 g free BCAAs, 11 µg vitamin D) or standard care (600 kcal, 24g protein of which 100% casein, 4 µg vitamin D). Body weight increased significantly in the 12 weeks, both in the intervention group (+1.6 ± 0.2 kg, p<.0001) and in the standard care group (+1.8 ± 0.2 kg, p<.0001). Gait speed during 4m and 400m tests improved over time in the intervention group, whereas the standard care showed no improvements (time*treatment effects 400m: p=0.038 and 4m: p=0.048). Gene sets related to mitochondrial functioning were strongly upregulated in the participants receiving the intervention product. We showed that a novel oral nutritional supplement improves gait speed in older adults via improvements in mitochondrial functioning.

Project description:85 radical prostatectomy specimens (where 16 samples are in Placebo group (PL), 15 are in Selenium group (SE), 25 are in Vitamin E group (VE) and 27 are in Vitamin E & Selenium group (VS.Treatment groups: l-selenomethionine, 400 ug + placebo (vitamin E); vitamin E, 400 IU + placebo (l-selenomethionine); l-selenomethionine, 400 ug + vitamin E, 400 IU; placebos) were subjected to laser capture microdissection to isolate prostate cancer cells, normal epithelial prostatic cells, or stroma cells. RNA extraction and amplification were performed. Transcription profiling was conducted using the HG-U133A Affymetrix arrays.

Project description:Human aging is associated with skeletal muscle atrophy and functional impairment (sarcopenia). Multiple lines of evidence suggest that mitochondrial dysfunction is a major contributor to sarcopenia. We evaluated whether healthy aging was associated with a transcriptional profile reflecting mitochondrial impairment and whether resistance exercise could reverse this signature to that approximating a younger physiological age. Skeletal muscle biopsies from healthy older (N = 25) and younger (N = 26) adult men and women were compared using gene expression profiling, and a subset of these were related to measurements of muscle strength. 14 of the older adults had muscle samples taken before and after a six-month resistance exercise-training program. Before exercise training, older adults were 59% weaker than younger, but after six months of training in older adults, strength improved significantly (P<0.001) such that they were only 38% lower than young adults. As a consequence of age, we found 596 genes differentially expressed using a false discovery rate cut-off of 5%. Prior to the exercise training, the transcriptome profile showed a dramatic enrichment of genes associated with mitochondrial function with age. However, following exercise training the transcriptional signature of aging was markedly reversed back to that of younger levels for most genes that were affected by both age and exercise. We conclude that healthy older adults show evidence of mitochondrial impairment and muscle weakness, but that this can be partially reversed at the phenotypic level, and substantially reversed at the transcriptome level, following six months of resistance exercise training. Keywords: resistance exercise, muscle, aging

Project description:Expression profiling of vastus lateralis muscle of young, healthy, non-obese men supplemented with creatine monohydrate vs. placebo for 10 days. Results identify transcriptional pathways activated in skeletal muscles as a result of acute creatine monohydrate supplementation. Keywords: Supplementation response. In a randomized, placebo-controlled, crossover, double-blind design, 12 young, healthy, non-obese men were supplemented with either a placebo or creatine monohydrate (loading phase, 20 g/d x 3 d; maintenance phase, 5 g/d x 7 d) for 10 d. Following a 28 day washout period, subjects were put on the alternate supplementation for 10 days. Muscle biopsies of the vastus lateralis were obtained and were assessed for global mRNA expression using cDNA microarrays.

Project description:The obese, insulin resistant state is characterized by impairments in lipid metabolism. Dietary polyphenols might improve these deteriorations. We have previously shown that 3-days supplementation of combined Epigallocatechin-gallate and Resveratrol (E+R) increased energy expenditure, which was accompanied by improved metabolic flexibility after a high-fat mixed-meal (HFMM) in men. The present study aimed to investigate whether these short-term effects translate into longer-term improvement of insulin sensitivity and lipid metabolism. In this randomized, double-blind study, 42 overweight subjects (21 male, 38±2 yrs, BMI 29.7±0.5 kg/m2, HOMA-IR 2.1±0.2) received either E+R (300 and 80 mg/d, respectively) or placebo (PLA) for 12 weeks (3 months). Before (t0) and after (t3) intervention, tissue-specific insulin sensitivity was assessed by a hyperinsulinemic-euglycemic clamp with stable isotope infusion. Fasting and postprandial (HFMM) lipid metabolism was assessed using indirect calorimetry and blood sampling. Adipose tissue and skeletal muscle lipolysis was measured using microdialysis in men and skeletal muscle biopsies were collected to assess mitochondrial function and gene expression alterations via microarray analysis. E+R supplementation increased fasting (P=0.06) and postprandial (P=0.03) fat oxidation but did not alter energy expenditure compared to PLA. This was accompanied by an E+R-induced increase in oxidative capacity in permeabilized muscle fibers (p<0.05). Moreover, E+R supplementation attenuated the increase in plasma triacylglycerol concentration that was observed in the PLA group (AUC, p<0.05), and tended to decrease visceral fat mass (P=0.09). Finally, insulin-stimulated glucose disposal and suppression of endogenous glucose production were not affected by E+R supplementation. 12 weeks E+R supplementation increased whole-body fat oxidation and skeletal muscle oxidative capacity, but this did not translate into increased tissue-specific insulin sensitivity in overweight and obese subjects. To identify pathways that may underlie the E+R-induced improvement of skeletal muscle mitochondrial capacity, we performed microarray analysis on skeletal muscle biopsies (vastus lateralis muscle), collected before and after 12-weeks E+R or PLA treatment. Gene Set Enrichment Analysis (GSEA) indicated that the most upregulated pathways after E+R supplementation were related to the citric acid cycle and respiratory electron transport chain, while pathways related to carbohydrate metabolism were upregulated in the PLA group. In this randomized, double-blind placebo-controlled, parallel intervention trial, subjects received either a combination of E+R supplements (INTV, 282 mg/d and 80 mg/d, respectively) or placebo (PLA, partly hydrolyzed microcrystalline cellulose-filled capsules) for a period of 12 weeks (3 months) to assess effects of E+R supplementation on tissue-specific insulin sensitivity (primary outcomes) and fasting and postprandial substrate metabolism (secondary outcomes). Skeletal muscle (m. vastus lateralis) biopsies were taken under local anesthesia during fasting conditions before (t0) and after the 12-weeks (t3) intervention period. Extraxted RNA was hybridized on HTA 2.0 Affymetrix arrays and microarray analysis was performed on paired sample sets for 27 subjects (p, PLA n = 14; E+R n = 13).

Project description:Inadequate dietary protein intake causes adverse changes in the morphology and function of skeletal muscle. These changes may be reflected in early alterations in muscle mRNA levels. Microarray analysis was used to assess whether inadequate protein intake differentially affects skeletal muscle transcript levels and expression profiles in older adults. Experiment Overall Design: 11 older males and females (aged 55-80 y) consumed controlled diets that contained 1.2 g protein•kg-1•d-1 (adequate protein) for one wk and then 0.5 g protein•kg-1•d-1 (inadequate protein; IP group; n=11) for a second wk. RNA was isolated from fasting-state vastus lateralis biopsies obtained at the end of each period and the transcript levels were determined using the Affymetrix U133A array