53 research outputs found
Metabolic switching of human skeletal muscle cells in vitro
In this review we will focus on external factors that may modify energy metabolism in human skeletal muscle cells (myotubes) and the ability of the myotubes to switch between lipid and glucose oxidation. We describe the metabolic parameters suppressibility, adaptability and substrate-regulated flexibility, and show the influence of nutrients such as fatty acids and glucose (chronic hyperglycemia), and some pharmacological agents modifying nuclear receptors (PPAR and LXR), on these parameters in human myotubes. Possible cellular mechanisms for changes in these parameters will also be highlighted.The present work was funded by University of Oslo, The European Nutrigenomics
Organisation (NuGO), The Norwegian Diabetes Foundation, AstraZeneca, Freia
Chocolade Fabriks Medical Foundation, and The Anders Jahre’s Foundatio
Remodelling of oxidative energy metabolism by galactose improves glucose handling and metabolic switching in human skeletal muscle cells
Cultured human myotubes have a low mitochondrial oxidative potential. This study aims to remodel energy metabolism in myotubes by replacing glucose with galactose during growth and differentiation to ultimately examine the consequences for fatty acid and glucose metabolism. Exposure to galactose showed an increased [14C]oleic acid oxidation, whereas cellular uptake of oleic acid uptake was unchanged. On the other hand, both cellular uptake and oxidation of [14C]glucose increased in myotubes exposed to galactose. In the presence of the mitochondrial uncoupler carbonylcyanide p-trifluormethoxy-phenylhydrazone (FCCP) the reserve capacity for glucose oxidation was increased in cells grown with galactose. Staining and live imaging of the cells showed that myotubes exposed to galactose had a significant increase in mitochondrial and neutral lipid content. Suppressibility of fatty acid oxidation by acute addition of glucose was increased compared to cells grown in presence of glucose. In summary, we show that cells grown in galactose were more oxidative, had increased oxidative capacity and higher mitochondrial content, and showed an increased glucose handling. Interestingly, cells exposed to galactose showed an increased suppressibility of fatty acid metabolism. Thus, galactose improved glucose metabolism and metabolic switching of myotubes, representing a cell model that may be valuable for metabolic studies related to insulin resistance and disorders involving mitochondrial impairments
Are cultured human myotubes far from home?
Satellite cells can be isolated from skeletal muscle biopsies, activated to proliferating myoblasts and differentiated into multinuclear myotubes in culture. These cell cultures represent a model system for intact human skeletal muscle and can be modulated ex vivo. The advantages of this system are that the most relevant genetic background is available for the investigation of human disease (as opposed to rodent cell cultures), the extracellular environment can be precisely controlled and the cells are not immortalized, thereby offering the possibility of studying innate characteristics of the donor. Limitations in differentiation status (fiber type) of the cells and energy metabolism can be improved by proper treatment, such as electrical pulse stimulation to mimic exercise. This review focuses on the way that human myotubes can be employed as a tool for studying metabolism in skeletal muscles, with special attention to changes in muscle energy metabolism in obesity and type 2 diabetes
Distinct microRNA and protein profiles of extracellular vesicles secreted from myotubes from morbidly obese donors with type 2 diabetes in response to electrical pulse stimulation
Lifestyle disorders like obesity, type 2 diabetes (T2D), and cardiovascular diseases can be prevented and treated by regular physical activity. During exercise, skeletal muscles release signaling factors that communicate with other organs and mediate beneficial effects of exercise. These factors include myokines, metabolites, and extracellular vesicles (EVs). In the present study, we have examined how electrical pulse stimulation (EPS) of myotubes, a model of exercise, affects the cargo of released EVs. Chronic low frequency EPS was applied for 24Â h to human myotubes isolated and differentiated from biopsy samples from six morbidly obese females with T2D, and EVs, both exosomes and microvesicles (MV), were isolated from cell media 24Â h thereafter. Size and concentration of EV subtypes were characterized by nanoparticle tracking analysis, surface markers were examined by flow cytometry and Western blotting, and morphology was confirmed by transmission electron microscopy. Protein content was assessed by high-resolution proteomic analysis (LC-MS/MS), non-coding RNA was quantified by Affymetrix microarray, and selected microRNAs (miRs) validated by real time RT-qPCR. The size and concentration of exosomes and MV were unaffected by EPS. Of the 400 miRs identified in the EVs, EPS significantly changed the level of 15 exosome miRs, of which miR-1233-5p showed the highest fold change. The miR pattern of MV was unaffected by EPS. Totally, about 1000 proteins were identified in exosomes and 2000 in MV. EPS changed the content of 73 proteins in exosomes, 97 in MVs, and of these four were changed in both exosomes and MV (GANAB, HSPA9, CNDP2, and ATP5B). By matching the EPS-changed miRs and proteins in exosomes, 31 targets were identified, and among these several promising signaling factors. Of particular interest were CNDP2, an enzyme that generates the appetite regulatory metabolite Lac-Phe, and miR-4433b-3p, which targets CNDP2. Several of the regulated miRs, such as miR-92b-5p, miR-320b, and miR-1233-5p might also mediate interesting signaling functions. In conclusion, we have used a combined transcriptome-proteome approach to describe how EPS affected the cargo of EVs derived from myotubes from morbidly obese patients with T2D, and revealed several new factors, both miRs and proteins, that might act as exercise factors
Climate–ecosystem modelling made easy: The Land Sites Platform
Dynamic Global Vegetation Models (DGVMs) provide a state-of-the-art process-based approach to study the complex interplay between vegetation and its physical environment. For example, they help to predict how terrestrial plants interact with climate, soils, disturbance and competition for resources. We argue that there is untapped potential for the use of DGVMs in ecological and ecophysiological research. One fundamental barrier to realize this potential is that many researchers with relevant expertize (ecology, plant physiology, soil science, etc.) lack access to the technical resources or awareness of the research potential of DGVMs. Here we present the Land Sites Platform (LSP): new software that facilitates single-site simulations with the Functionally Assembled Terrestrial Ecosystem Simulator, an advanced DGVM coupled with the Community Land Model. The LSP includes a Graphical User Interface and an Application Programming Interface, which improve the user experience and lower the technical thresholds for installing these model architectures and setting up model experiments. The software is distributed via version-controlled containers; researchers and students can run simulations directly on their personal computers or servers, with relatively low hardware requirements, and on different operating systems. Version 1.0 of the LSP supports site-level simulations. We provide input data for 20 established geo-ecological observation sites in Norway and workflows to add generic sites from public global datasets. The LSP makes standard model experiments with default data easily achievable (e.g., for educational or introductory purposes) while retaining flexibility for more advanced scientific uses. We further provide tools to visualize the model input and output, including simple examples to relate predictions to local observations. The LSP improves access to land surface and DGVM modelling as a building block of community cyberinfrastructure that may inspire new avenues for mechanistic ecosystem research across disciplines.publishedVersio
Electrical Pulse Stimulation of Cultured Human Skeletal Muscle Cells as an In Vitro Model of Exercise
Background and Aims
Physical exercise leads to substantial adaptive responses in skeletal muscles and plays a central role in a healthy life style. Since exercise induces major systemic responses, underlying cellular mechanisms are difficult to study in vivo. It was therefore desirable to develop an in vitro model that would resemble training in cultured human myotubes.
Methods
Electrical pulse stimulation (EPS) was applied to adherent human myotubes. Cellular contents of ATP, phosphocreatine (PCr) and lactate were determined. Glucose and oleic acid metabolism were studied using radio-labeled substrates, and gene expression was analyzed using real-time RT-PCR. Mitochondrial content and function were measured by live imaging and determination of citrate synthase activity, respectively. Protein expression was assessed by electrophoresis and immunoblotting.
Results
High-frequency, acute EPS increased deoxyglucose uptake and lactate production, while cell contents of both ATP and PCr decreased. Chronic, low-frequency EPS increased oxidative capacity of cultured myotubes by increasing glucose metabolism (uptake and oxidation) and complete fatty acid oxidation. mRNA expression level of pyruvate dehydrogenase complex 4 (PDK4) was significantly increased in EPS-treated cells, while mRNA expressions of interleukin 6 (IL-6), cytochrome C and carnitin palmitoyl transferase b (CPT1b) also tended to increase. Intensity of MitoTracker®Red FM was doubled after 48 h of chronic, low-frequency EPS. Protein expression of a slow fiber type marker (MHCI) was increased in EPS-treated cells.
Conclusions
Our results imply that in vitro EPS (acute, high-frequent as well as chronic, low-frequent) of human myotubes may be used to study effects of exercise.This work was funded by the University of Oslo, Oslo University College, the Norwegian Diabetes Foundation, the Freia Chocolade Fabriks Medical Foundation and the Anders Jahre’s Foundation. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
Substrate oxidation in primary human skeletal muscle cells is influenced by donor age
Primary human myotubes represent an alternative system to intact skeletal muscle for the study of human diseases related to
changes in muscle energy metabolism. This work aimed to study if fatty acid and glucose metabolism in human myotubes in vitro
were related to muscle of origin, donor gender, age, or body mass index (BMI). Myotubes from a total of 82 donors were
established from three different skeletal muscles, i.e., musculus vastus lateralis, musculus obliquus internus abdominis, and
musculi interspinales, and cellular energy metabolism was evaluated. Multiple linear regression analyses showed that donor age
had a significant effect on glucose and oleic acid oxidation after correcting for gender, BMI, and muscle of origin. Donor BMI
was the only significant contributor to cellular oleic acid uptake, whereas cellular glucose uptake did not rely on any of the
variables examined. Despite the effect of age on substrate oxidation, cellular mRNA expression of pyruvate dehydrogenase
kinase 4 (PDK4) and peroxisome proliferator–activated receptor gamma coactivator 1 alpha (PPARGC1A) did not correlate with
donor age. In conclusion, donor age significantly impacts substrate oxidation in cultured human myotubes, whereas donor BMI
affects cellular oleic acid uptake
Substrate oxidation in primary human skeletal muscle cells is influenced by donor age
Abstract
Primary human myotubes represent an alternative system to intact skeletal muscle for the study of human diseases related to changes in muscle energy metabolism. This work aimed to study if fatty acid and glucose metabolism in human myotubes in vitro were related to muscle of origin, donor gender, age, or body mass index (BMI). Myotubes from a total of 82 donors were established from three different skeletal muscles, i.e., musculus vastus lateralis , musculus obliquus internus abdominis , and musculi interspinales , and cellular energy metabolism was evaluated. Multiple linear regression analyses showed that donor age had a significant effect on glucose and oleic acid oxidation after correcting for gender, BMI, and muscle of origin. Donor BMI was the only significant contributor to cellular oleic acid uptake, whereas cellular glucose uptake did not rely on any of the variables examined. Despite the effect of age on substrate oxidation, cellular mRNA expression of pyruvate dehydrogenase kinase 4 ( PDK4 ) and peroxisome proliferator–activated receptor gamma coactivator 1 alpha ( PPARGC1A ) did not correlate with donor age. In conclusion, donor age significantly impacts substrate oxidation in cultured human myotubes, whereas donor BMI affects cellular oleic acid uptake
Tarmfloraen – på helsa løs
Hensikt
I løpet av de siste årene har det
fremkommet holdepunkter for at
ubalanse eller forstyrrelser i tarmfloraen,
såkalt dysbiose, bidrar til utvikling
av enkelte metabolske sykdommer.
Hensikten med denne artikkelen er å
gi en kortfattet beskrivelse av hvordan
endringer i tarmens mikrobiota kan være
involvert i patofysiologien ved fedme,
type 2-diabetes og aterosklerose.
Materiale og metoder
Oversikten er basert på et skjønnsmessig
utvalg av relevante artikler funnet etter
litteratursøk i PubMed.
Resultater
Pasienter med fedme, type 2-diabetes
og aterosklerose har en annen
bakteriesammensetningen i tarmen
enn friske kontrollpersoner, og det kan
synes som om bakteriemangfoldet er
mindre. BÃ¥de fedme, type 2-diabetes
og aterosklerose er kroniske inflammasjonstilstander
der tarmbakterier
eller deres produkter kan spille en viktig
rolle. Bruk av pre-, pro- og antibiotika
er studert som behandlingsstrategier ved
dysbiose. Resultatene tyder på at både
pre- og probiotika kan ha et terapeutisk
potensial, mens den kliniske dokumentasjonen
er foreløpig begrenset. Det
er antakelig flere ulemper enn fordeler
knyttet til intervensjon med antibiotika i
denne sammenhengen.
Konklusjon
Mekanismene for hvordan tarmens
mikrobiota bidrar i utvikling av fedme,
type 2-diabetes og aterosklerose er
blant annet knyttet til ulike bakterieprodukter
og inflammasjon. Dette åpner
for manipulasjon av tarmfloraen som et
mulig terapeutisk prinsipp i behandling
av metabolske sykdommer
Tarmfloraen – på helsa løs
Hensikt
I løpet av de siste årene har det
fremkommet holdepunkter for at
ubalanse eller forstyrrelser i tarmfloraen,
såkalt dysbiose, bidrar til utvikling
av enkelte metabolske sykdommer.
Hensikten med denne artikkelen er å
gi en kortfattet beskrivelse av hvordan
endringer i tarmens mikrobiota kan være
involvert i patofysiologien ved fedme,
type 2-diabetes og aterosklerose.
Materiale og metoder
Oversikten er basert på et skjønnsmessig
utvalg av relevante artikler funnet etter
litteratursøk i PubMed.
Resultater
Pasienter med fedme, type 2-diabetes
og aterosklerose har en annen
bakteriesammensetningen i tarmen
enn friske kontrollpersoner, og det kan
synes som om bakteriemangfoldet er
mindre. BÃ¥de fedme, type 2-diabetes
og aterosklerose er kroniske inflammasjonstilstander
der tarmbakterier
eller deres produkter kan spille en viktig
rolle. Bruk av pre-, pro- og antibiotika
er studert som behandlingsstrategier ved
dysbiose. Resultatene tyder på at både
pre- og probiotika kan ha et terapeutisk
potensial, mens den kliniske dokumentasjonen
er foreløpig begrenset. Det
er antakelig flere ulemper enn fordeler
knyttet til intervensjon med antibiotika i
denne sammenhengen.
Konklusjon
Mekanismene for hvordan tarmens
mikrobiota bidrar i utvikling av fedme,
type 2-diabetes og aterosklerose er
blant annet knyttet til ulike bakterieprodukter
og inflammasjon. Dette åpner
for manipulasjon av tarmfloraen som et
mulig terapeutisk prinsipp i behandling
av metabolske sykdommer
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