38 research outputs found

    Metabolic reprogramming involving glycolysis in the hibernating brown bear skeletal muscle

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    Background: In mammals, the hibernating state is characterized by biochemical adjustments, which include metabolic rate depression and a shift in the primary fuel oxidized from carbohydrates to lipids. A number of studies of hibernating species report an upregulation of the levels and/or activity of lipid oxidizing enzymes in muscles during torpor, with a concomitant downregulation for glycolytic enzymes. However, other studies provide contrasting data about the regulation of fuel utilization in skeletal muscles during hibernation. Bears hibernate with only moderate hypothermia but with a drop in metabolic rate down to ~ 25% of basal metabolism. To gain insights into how fuel metabolism is regulated in hibernating bear skeletal muscles, we examined the vastus lateralis proteome and other changes elicited in brown bears during hibernation. Results: We show that bear muscle metabolic reorganization is in line with a suppression of ATP turnover. Regulation of muscle enzyme expression and activity, as well as of circulating metabolite profiles, highlighted a preference for lipid substrates during hibernation, although the data suggested that muscular lipid oxidation levels decreased due to metabolic rate depression. Our data also supported maintenance of muscle glycolysis that could be fuelled from liver gluconeogenesis and mobilization of muscle glycogen stores. During hibernation, our data also suggest that carbohydrate metabolism in bear muscle, as well as protein sparing, could be controlled, in part, by actions of n-3 polyunsaturated fatty acids like docosahexaenoic acid. Conclusions: Our work shows that molecular mechanisms in hibernating bear skeletal muscle, which appear consistent with a hypometabolic state, likely contribute to energy and protein savings. Maintenance of glycolysis could help to sustain muscle functionality for situations such as an unexpected exit from hibernation that would require a rapid increase in ATP production for muscle contraction. The molecular data we report here for skeletal muscles of bears hibernating at near normal body temperature represent a signature of muscle preservation despite atrophying conditions

    Proteolysis inhibition by hibernating bear serum leads to increased protein content in human muscle cells

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    Muscle atrophy is one of the main characteristics of human ageing and physical inactivity, with resulting adverse health outcomes. To date, there are still no efficient therapeutic strategies for its prevention and/or treatment. However, during hibernation, bears exhibit a unique ability for preserving muscle in conditions where muscle atrophy would be expected in humans. Therefore, our objective was to determine whether there are components of bear serum which can control protein balance in human muscles. In this study, we exposed cultured human differentiated muscle cells to bear serum collected during winter and summer periods, and measured the impact on cell protein content and turnover. In addition, we explored the signalling pathways that control rates of protein synthesis and degradation. We show that the protein turnover of human myotubes is reduced when incubated with winter bear serum, with a dramatic inhibition of proteolysis involving both proteasomal and lysosomal systems, and resulting in an increase in muscle cell protein content. By modulating intracellular signalling pathways and inducing a protein sparing phenotype in human muscle cells, winter bear serum therefore holds potential for developing new tools to fight human muscle atrophy and related metabolic disorders

    Agroecological management of cucurbit-infesting fruit fly: a review

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    Proteomics can help to gain insights into metabolic disorders according to body reserve availability

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    A proteomic approach to identify differentially-expressed plasma protiens between the fed and prolonged fasted states

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    International audienceProlonged fasting is characterized by consecutive phases, a short period of adaptation (phase 1), phase 2 (P2) characterized by fat oxidation, and phase 3 (P3) during which energy requirements are mostly derived from increased protein utilization. At this latter stage, food seeking behavior is induced. Very few circulating biomolecules have been identified that are involved in the response to prolonged fasting. To this end, rat plasma samples were compared by a proteomic approach, using 2-DE. The results revealed a selective variation of the levels of apolipoprotein A-IV, A-I, and E, haptoglobin, transthyretin, plasma retinol binding-protein, and vitamin D binding-protein in P2 and P3. The variations in protein levels were confirmed by ELISA. Changes in mRNA levels encoding these proteins did not systematically correlate well with protein concentrations, and tissue-specific regulation of mRNA expression was observed, underlining the complex metabolic regulation in response to food deprivation. In late fasting, the marked reduction of apolipoprotein A-IV levels could contribute to the alarm signal that triggers refeeding. The variations of the other differentially expressed proteins are more likely related to lipid metabolism and insulin signaling alterations
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