Project description:In our study, we investigated for contractile activity-specific changes in the transcriptome in untrained and trained (after an aerobic training programme) human skeletal muscle. The second goal was to examine effect of aerobic training on gene expression in muscle at baseline (after long term training). Seven untrained males performed the one-legged knee extension exercise (for 60 min) with the same relative intensity before and after a 2 month aerobic training programme (1 h/day, 5/week). Biopsy samples were taken at rest (baseline condition, 48 h after exercise), 1 and 4 h after the one-legged exercise from m. vastus lateralis of either leg. Comparison of gene expression in exercised leg with that in non-exercised [control] leg allowed us to identify contractile activity-specific genes in both untrained and trained skeletal muscle, i.e., genes that play a key role in adapting to acute exercise, regardless of the level of fitness. RNA-sequencing (84 samples in total; ~47 million reads/sample) was performed by NextSeq 500 and HiSeq 2500 (Illumina). Two months aerobic training increased the aerobic capacity of the knee-extensor muscles (power at anaerobic threshold in the incremental one-legged and cycling tests), the maximum rate of ADP-stimulated mitochondrial respiration in permeabilized muscle fibres and amounts of oxidative phosphorylation proteins. Contractile activity-specific changes in the transcriptome in untrained and trained human skeletal muscle were revealed for the first time. After 2 month aerobic training, transcriptome responses specific for contractile activity in trained muscle substantially decreased relative to those in untrained muscle. We found out that adaptation of skeletal muscle to regular exercise is associated not only with a transient change in the transcriptome after each stress (acute exercise), but also with a marked change in baseline expression of many genes after repeated stress (e.g., long term training).

Project description:Haloplasma contractile overview

Project description:Here, we use a transcriptomic apprach to identify genes associated with variation in muscle contractile physiology differences among different muscles of the same individual.

Project description:Gene expression and muscle contractile physiology in anoles

Project description:Myxococcus xanthus is a model organism to study the biosynthesis and secretion of polysaccharides. The exopolysaccharide (EPS) is synthesized and exported via the Wzx/Wzy-dependent EPS pathway. The phosphoglycosyl transferase EpsZ initiates EPS biosynthesis by transferring galactose-1-P to undecaprenyl phosphate. EPS biosynthesis is stimulated by the Dif chemosensory system through the single-domain response regulator EpsW, which is activated through phosphorylation by the DifE kinase. Importantly, the mechanism by which EpsW~P activates EPS biosynthesis is unknown. To investigate if EpsW regulates EPS biosynthesis at the transcriptional level, we extracted total RNA from vegetative cells of the wildtype and the ΔepsW mutant. Moreover, we extracted total RNA from vegetative cells of the ΔepsZ and ΔdifE mutants to investigate the effects of EpsZ and DifE on the transcriptome.

Project description:Langerhans cells (LC) coordinate immune homeostasis at the human epidermis, proficent in initiating immunogenic and tolerogenic immune responses. To investigate the transcriptomic mediators of human LC immunogenic vs tolerogenic immune responses, we performed single cell RNA-sequencing of migratory LCs extracted from epidermal sheets stimulated with or without TNF.

Project description:Skeletal muscle mediates the beneficial effects of exercise, thereby improving insulin sensitivity and reducing the risk for type 2 diabetes. Current skeletal-muscle-models in vitro are incapable of fully recapitulating its physiological functions especially regarding exercise. Supplementation of IGF1, a growth factor secreted by myofibers in vivo, might help to overcome these limitations. Primary human CD56-positive myoblasts were differentiated into myotubes in the presence/absence of IGF1 in serum-free medium for 10 days. Daily collected samples were analyzed by proteomics, qRT-PCR and myotube contractibility via electrical-pulse-stimulation (EPS). Mitochondrial respiration and glucose uptake were measured. IGF1-supported differentiation formed thicker multinucleated myotubes showing physiological contraction upon EPS following day 6 while myotubes without IGF1 were almost incapable of contraction. IGF1-treatment upregulated particularly muscle-specific proteins that contribute to myofibril and sarcomere assembly, striated muscle contraction, and ATP production. Elevated PPARGC1A, MYH7 and reduced MYH1/2 suggest a switch towards a more oxidative phenotype in line with elevated mitochondrial respiration. IGF1-treatment also upregulated expression of GLUT4 and increased insulin-dependent glucose uptake. To conclude, utilizing IGF1, we engineered human myotubes that recapitulate the physiological traits of skeletal muscle in vivo vastly superior to established protocols. This novel model enables investigation of exercise on a molecular level, drug screening and interorgan-crosstalk by transfer to organ-on-chip.

Project description:This experiment is part of the FunGenES project (FunGenES - Functional Genomics in Embryonic Stem Cells partially funded by the 6th Framework Programme of the EuropeanUnion, http://www.fungenes.org). The experiment was conducted at University of Cologne, Cologne, Germany. Goal of the experiment is a complete transcriptome profiling of contractile smooth muscle cells (SMCs) differentiated from embryonic stem cells which is crucial for the characterization of smooth muscle gene expression signatures and will contribute to defining biological and physiological processes in these cells. We have generated a transgenic embryonic stem cell line expressing both the puromycin acetyl transferase and enhanced green fluorescent protein cassettes under the control of the Acta2 promoter.This experiment allows the identification of specific biological and physiological processes in the contractile phenotype SMCs and will contribute to the understanding of these processes in early SMCs derived from embryonic stem cells.

Project description:Haloplasma contractile SSD-17B genome sequencing

Project description:Effects of electrical pulse stimulation and hydrogen peroxide as its byproduct on in vitro contractile skeletal muscle tissue.