Your search keyword '"Prats C"' showing total 8 results

1. The dynamic life of the glycogen granule.

Author

Prats C, Graham TE, and Shearer J

Subjects

Animals, Energy Metabolism, Glycogen biosynthesis, Glycogen chemistry, Glycogen metabolism, Glycogenolysis, Humans, Liver Glycogen metabolism, Metabolic Networks and Pathways, Phosphorylation, Proteins metabolism, Brain metabolism, Cell Compartmentation, Glycogen physiology, Microbodies metabolism, Muscle, Skeletal metabolism

Abstract

Glycogen, the primary storage form of glucose, is a rapid and accessible form of energy that can be supplied to tissues on demand. Each glycogen granule, or "glycosome," is considered an independent metabolic unit composed of a highly branched polysaccharide and various proteins involved in its metabolism. In this Minireview, we review the literature to follow the dynamic life of a glycogen granule in a multicompartmentalized system, i.e. the cell, and how and where glycogen granules appear and the factors governing its degradation. A better understanding of the importance of cellular compartmentalization as a regulator of glycogen metabolism is needed to unravel its role in brain energetics., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

2. Effects of immobilization and aerobic training on proteins related to intramuscular substrate storage and metabolism in young and older men.

Author

Vigelsø A, Gram M, Wiuff C, Hansen CN, Prats C, Dela F, and Helge JW

Subjects

3-Hydroxyacyl-CoA Dehydrogenase metabolism, Aged, Carrier Proteins metabolism, Glycogen Synthase metabolism, Humans, Male, Muscle, Skeletal growth & development, Perilipin-1, Phosphoproteins metabolism, Qb-SNARE Proteins metabolism, Qc-SNARE Proteins metabolism, Young Adult, Exercise, Glycogen metabolism, Immobilization adverse effects, Lipid Metabolism, Muscle Proteins metabolism, Muscle, Skeletal metabolism

Abstract

Purpose: Aging and inactivity lead to skeletal muscle metabolic inflexibility, but the underlying molecular mechanisms are not entirely elucidated. Therefore, we investigated how muscle lipid and glycogen stores and major regulatory proteins were affected by short-term immobilization followed by aerobic training in young and older men., Methods: 17 young (23 ± 1 years, 24 ± 1 kg m(-2), and 20 ± 2% body fat) and 15 older men (68 ± 1 years; 27 ± 1 kg m(-2), and 29 ± 2% body fat) underwent 2 weeks' one leg immobilization followed by 6 weeks' cycle training. Biopsies were obtained from m. vastus lateralis just before immobilization (at inclusion), after immobilization, and the after 6 weeks' training. The biopsies were analyzed for muscle substrates; muscle perilipin protein (PLIN), glycogen synthase (GS), synaptosomal-associated protein of 23 kDa (SNAP23) protein content, and muscle 3-hydroxyacyl-CoA dehydrogenase (HAD) activity, Results: The older men had higher intramuscular triglyceride (IMTG) (73 %) and Glycogen (16%) levels compared to the young men, and IMTG tended to increase with immobilization. PLIN2 and 3 protein content increased with immobilization in the older men only. The young men had higher GS (74%) protein compared to the older men. Immobilization decreased and training restored HAD activity, GS and SNAP23 protein content in young and older men., Conclusion: Evidence of age-related metabolic inflexibility is presented, seen as body fat and IMTG accumulation. The question arises as to whether IMTG accumulation in the older men is caused by or leading to the increase in PLIN2 and 3 protein content. Training decreased body fat and IMTG levels in both young and older men; hence, training should be prioritized to reduce the detrimental effect of aging on metabolism.

Published

2016

3. An optimized histochemical method to assess skeletal muscle glycogen and lipid stores reveals two metabolically distinct populations of type I muscle fibers.

Author

Prats C, Gomez-Cabello A, Nordby P, Andersen JL, Helge JW, Dela F, Baba O, and Ploug T

Subjects

Adult, Biopsy, Energy Metabolism, Humans, Image Processing, Computer-Assisted, Immunoenzyme Techniques, Quadriceps Muscle surgery, Exercise physiology, Glycogen metabolism, Lipids physiology, Muscle Fibers, Slow-Twitch classification, Muscle Fibers, Slow-Twitch metabolism, Myosin Heavy Chains metabolism, Quadriceps Muscle metabolism

Abstract

Skeletal muscle energy metabolism has been a research focus of physiologists for more than a century. Yet, how the use of intramuscular carbohydrate and lipid energy stores are coordinated during different types of exercise remains a subject of debate. Controversy arises from contradicting data from numerous studies, which used different methodological approaches. Here we review the "pros and cons" of previously used histochemical methods and describe an optimized method to ensure the preservation and specificity of detection of both intramyocellular carbohydrate and lipid stores. For optimal preservation of muscle energy stores, air drying cryosections or cycles of freezing-thawing need to be avoided. Furthermore, optimization of the imaging settings in order to specifically image intracellular lipid droplets stained with oil red O or Bodipy-493/503 is shown. When co-staining lipid droplets with associated proteins, Bodipy-493/503 should be the dye of choice, since oil red O creates precipitates on the lipid droplets blocking the light. In order to increase the specificity of glycogen stain, an antibody against glycogen is used. The resulting method reveals the existence of two metabolically distinct myosin heavy chain I expressing fibers: I-1 fibers have a smaller crossectional area, a higher density of lipid droplets, and a tendency to lower glycogen content compared to I-2 fibers. Type I-2 fibers have similar lipid content than IIA. Exhaustive exercise lead to glycogen depletion in type IIA and IIX fibers, a reduction in lipid droplets density in both type I-1 and I-2 fibers, and a decrease in the size of lipid droplets exclusively in type I-1 fibers.

Published

2013

4. Intracellular compartmentalization of skeletal muscle glycogen metabolism and insulin signalling.

Author

Prats C, Gómez-Cabello A, and Hansen AV

Subjects

Cell Compartmentation physiology, Humans, Signal Transduction, Glycogen metabolism, Insulin metabolism, Muscle, Skeletal metabolism

Abstract

The interest in skeletal muscle metabolism and insulin signalling has increased exponentially in recent years as a consequence of their role in the development of type 2 diabetes mellitus. Despite this, the exact mechanisms involved in the regulation of skeletal muscle glycogen metabolism and insulin signalling transduction remain elusive. We believe that one of the reasons is that the role of intracellular compartmentalization as a regulator of metabolic pathways and signalling transduction has been rather ignored. This paper briefly reviews the literature to discuss the role of intracellular compartmentalization in the regulation of skeletal muscle glycogen metabolism and insulin signalling. As a result, a hypothetical regulatory mechanism is proposed by which cells could direct glycogen resynthesis towards different pools of glycogen particles depending on the metabolic needs. Furthermore, we discuss the role of skeletal muscle transverse tubules as potential modulators of tissue insulin responsiveness.

Published

2011

5. Muscle ceramide content in man is higher in type I than type II fibers and not influenced by glycogen content.

Author

Nordby P, Prats C, Kristensen D, Ekroos K, Forsberg G, Andersen JL, Ploug T, Dela F, Storlien L, and Helge JW

Subjects

Adult, Biopsy, Exercise physiology, Humans, Male, Muscle Fibers, Skeletal pathology, Muscle, Skeletal pathology, Physical Endurance physiology, Ceramides metabolism, Glycogen metabolism, Muscle Fibers, Skeletal metabolism, Muscle, Skeletal metabolism

Abstract

Human muscle is studied during glycogen depletion and repletion to understand the influence of exercise and muscle glycogen on total ceramide content. In addition, fiber-type-specific ceramide storage is investigated. Ten healthy males (26.4 +/- 0.9 years, BMI 24.4 +/- 0.7 kg m(-2) and VO2max 57 +/- 2 mL O2 min(-1) kg(-1)) participated in the study. On the first day, one leg was glycogen-depleted (DL) by exhaustive intermittent exercise followed by low carbohydrate diet. Next day, in the overnight fasted condition, muscle biopsies were excised from vastus lateralis before and after exhaustive exercise from both DL and control leg (CL). Muscle glycogen was analyzed biochemically and total muscle ceramide content by 2D quantitative lipidomic approach. Furthermore, fiber-type ceramide content was determined by fluorescence immunohistochemistry. Basal muscle glycogen was decreased (P < 0.05) with 50 +/- 6% in DL versus CL. After exhaustive exercise, muscle glycogen was similar in CL and DL 139 +/- 38 and 110 +/- 31 mmol kg(-1), respectively. Total muscle ceramide 58 +/- 1 pmol mg(-1) was not influenced by glycogen or exercise. Ceramide content was consistently higher (P < 0.001) in type I than in type II muscle fibers. In conclusion, human skeletal muscle, ceramide content is higher in type I than in type II. Despite rather large changes in muscle glycogen induced by prior depletion, exercise to exhaustion and repletion, total muscle ceramide concentration remained unchanged.

Published

2010

6. Phosphorylation-dependent translocation of glycogen synthase to a novel structure during glycogen resynthesis.

Author

Prats C, Cadefau JA, Cussó R, Qvortrup K, Nielsen JN, Wojtaszewski JF, Hardie DG, Stewart G, Hansen BF, and Ploug T

Subjects

Actins metabolism, Adenosine Monophosphate chemistry, Allosteric Site, Amino Acid Sequence, Animals, Centrifugation, Cytoplasm metabolism, Cytoskeleton metabolism, Female, Glycogen metabolism, Glycogen Phosphorylase metabolism, Image Processing, Computer-Assisted, Immunohistochemistry, Microscopy, Electron, Transmission, Microscopy, Fluorescence, Molecular Sequence Data, Muscle, Skeletal metabolism, Muscle, Skeletal ultrastructure, Muscles enzymology, Muscles metabolism, Peptides chemistry, Phosphorylation, Protein Conformation, Protein Structure, Tertiary, Protein Transport, Rabbits, Sarcoplasmic Reticulum ultrastructure, Subcellular Fractions metabolism, Tibia metabolism, Time Factors, Glycogen chemistry, Glycogen Synthase chemistry, Glycogen Synthase metabolism

Abstract

Glycogen metabolism has been the subject of extensive research, but the mechanisms by which it is regulated are still not fully understood. It is well accepted that the rate-limiting enzymes in glycogenesis and glycogenolysis are glycogen synthase (GS) and glycogen phosphorylase (GPh), respectively. Both enzymes are regulated by reversible phosphorylation and by allosteric effectors. However, evidence in the literature indicates that changes in muscle GS and GPh intracellular distribution may constitute a new regulatory mechanism of glycogen metabolism. Already in the 1960s, it was proposed that glycogen was present in dynamic cellular organelles that were termed glycosomas but no such cellular entities have ever been demonstrated. The aim of this study was to characterize muscle GS and GPh intracellular distribution and to identify possible translocation processes of both enzymes. Using in situ stimulation of rabbit tibialis anterior muscle, we show GS and GPh intracellular redistribution at the beginning of glycogen resynthesis after contraction-induced glycogen depletion. We identify a new "player," a new intracellular compartment involved in skeletal muscle glycogen metabolism. They are spherical structures that were not present in basal muscle, and we present evidence that indicate that they are products of actin cytoskeleton remodeling. Furthermore, for the first time, we show a phosphorylation-dependent intracellular distribution of GS. Here, we present evidence of a new regulatory mechanism of skeletal muscle glycogen metabolism based on glycogen enzyme intracellular compartmentalization.

Published

2005

7. Differences between glycogen biogenesis in fast- and slow-twitch rabbit muscle.

Author

Cussó R, Lerner LR, Cadefau J, Gil M, Prats C, Gasparotto M, and Krisman CR

Subjects

Animals, Glucose-6-Phosphate pharmacology, Glycogen deficiency, In Vitro Techniques, Rabbits, Glycogen biosynthesis, Muscle Fibers, Fast-Twitch metabolism, Muscle Fibers, Slow-Twitch metabolism, Muscle, Skeletal metabolism

Abstract

Skeletal muscle glycogen is an essential energy substrate for muscular activity. The biochemical properties of the enzymes involved in de novo synthesis of glycogen were analysed in two types of rabbit skeletal muscle fiber (fast- and slow-twitch). Glycogen concentration was higher in fast-twitch muscle than in slow-twitch muscle, but the latter contained many more small intermediate-acceptor molecules that could act as glycogen synthase substrates. The enzymes involved in de novo synthesis of glycogen in fast-twitch muscle were strongly stimulated by Glc-6-P, but those in slow-twitch muscle were not.

Published

2003

8. Glycogen depletion and resynthesis during 14 days of chronic low-frequency stimulation of rabbit muscle.

Author

Prats C, Bernal C, Cadefau JA, Frias J, Tibolla M, and Cussó R

Subjects

Animals, Blotting, Western, Electric Stimulation, Electrophoresis, Glycogen biosynthesis, Muscle Fibers, Fast-Twitch metabolism, Protein Precursors biosynthesis, Rabbits, Time Factors, Glycogen metabolism, Glycogen Synthase metabolism, Muscle, Skeletal metabolism, Protein Precursors metabolism

Abstract

Electro-stimulation alters muscle metabolism and the extent of this change depends on application intensity and duration. The effect of 14 days of chronic electro-stimulation on glycogen turnover and on the regulation of glycogen synthase in fast-twitch muscle was studied. The results showed that macro- and proglycogen degrade simultaneously during the first hour of stimulation. After 3 h, the muscle showed net synthesis, with an increase in the proglycogen fraction. The glycogen content peaked after 4 days of stimulation, macroglycogen being the predominant fraction at that time. Glycogen synthase was determined during electro-stimulation. The activity of this enzyme was measured at low UDPG concentration with either high or low Glu-6-P content. Western blots were performed against glycogen synthase over a range of stimulation periods. Activation of this enzyme was maximum before the net synthesis of glycogen, partial during net synthesis, and low during late synthesis. These observations suggest that the more active, dephosphorylated and very low phosphorylated forms of glycogen synthase may participate in the first steps of glycogen resynthesis before net synthesis is observed, while partially phosphorylated forms are most active during glycogen elongation.

Published

2002