Browsing by Subject "Muscle, Skeletal"

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    Expanding the clinical spectrum of hereditary fibrosing poikiloderma with tendon contractures, myopathy and pulmonary fibrosis due to FAM111B mutations
    (2015) Mercier, Sandra; Küry, Sébastien; Salort-Campana, Emmanuelle; Magot, Armelle; Agbim, Uchenna; Besnard, Thomas; Bodak, Nathalie; Bou-Hanna, Chantal; Bréhéret, Flora; Brunelle, Perrine; Caillon, Florence; Chabrol, Brigitte; Cormier-Daire, Valérie; David, Albert; Eymard, Bruno; Faivre, Laurence; Figarella-Branger, Dominique; Fleurence, Emmanuelle; Ganapathi, Mythily; Gherardi, Romain; Goldenberg, Alice; Hamel, Antoine; Igual, Jeanine; Irvine, Alan D; Israël-Biet, Dominique; Kannengiesser, Caroline; Laboisse, Christian; Le Caignec, Cédric; Mahé, Jean-Yves; Mallet, Stéphanie; MacGowan, Stuart; McAleer, Maeve A; McLean, Irwin; Méni, Cécile; Munnich, Arnold; Mussini, Jean-Marie; Nagy, Peter L; Odel, Jeffrey; O’Regan, Grainne M; Péréon, Yann; Perrier, Julie; Piard, Juliette; Puzenat, Eve; Sampson, Jacinda B; Smith, Frances; Soufir, Nadem; Tanji, Kurenai; Thauvin, Christel; Ulane, Christina; Watson, Rosemarie M; Khumalo, Nonhlanhla P; Mayosi, Bongani M; Barbarot, Sébastien; Bézieau, Stéphane
    BackgroundHereditary Fibrosing Poikiloderma (HFP) with tendon contractures, myopathy and pulmonary fibrosis (POIKTMP [MIM 615704]) is a very recently described entity of syndromic inherited poikiloderma. Previously by using whole exome sequencing in five families, we identified the causative gene, FAM111B (NM_198947.3), the function of which is still unknown. Our objective in this study was to better define the specific features of POIKTMP through a larger series of patients.MethodsClinical and molecular data of two families and eight independent sporadic cases, including six new cases, were collected.ResultsKey features consist of: (i) early-onset poikiloderma, hypotrichosis and hypohidrosis; (ii) multiple contractures, in particular triceps surae muscle contractures; (iii) diffuse progressive muscular weakness; (iv) pulmonary fibrosis in adulthood and (v) other features including exocrine pancreatic insufficiency, liver impairment and growth retardation. Muscle magnetic resonance imaging was informative and showed muscle atrophy and fatty infiltration. Histological examination of skeletal muscle revealed extensive fibroadipose tissue infiltration. Microscopy of the skin showed a scleroderma-like aspect with fibrosis and alterations of the elastic network. FAM111B gene analysis identified five different missense variants (two recurrent mutations were found respectively in three and four independent families). All the mutations were predicted to localize in the trypsin-like cysteine/serine peptidase domain of the protein. We suggest gain-of-function or dominant-negative mutations resulting in FAM111B enzymatic activity changes.ConclusionsHFP with tendon contractures, myopathy and pulmonary fibrosis, is a multisystemic disorder due to autosomal dominant FAM111B mutations. Future functional studies will help in understanding the specific pathological process of this fibrosing disorder.
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    Role of calcium and AMP kinase in the regulation of mitochondrial biogenesis and GLUT4 levels in muscle
    (2004) Ojuka, Edward O
    Contractile activity induces mitochondrial biogenesis and increases glucose transport capacity in muscle. There has been much research on the mechanisms responsible for these adaptations. The present paper reviews the evidence, which indicates that the decrease in the levels of high-energy phosphates, leading to activation of AMP kinase (AMPK), and the increase in cytosolic Ca(2+), which activates Ca(2+)/calmodulin-dependent protein kinase (CAMK), are signals that initiate these adaptative responses. Although the events downstream of AMPK and CAMK have not been well characterized, these events lead to activation of various transcription factors, including: nuclear respiratory factors (NRF) 1 and 2, which cause increased expression of proteins of the respiratory chain; PPAR-alpha, which up regulates the levels of enzymes of beta oxidation; mitochondrial transcription factor A, which activates expression of the mitochondrial genome; myocyte-enhancing factor 2A, the transcription factor that regulates GLUT4 expression. The well-orchestrated expression of the multitude of proteins involved in these adaptations is mediated by the rapid activation of PPAR gamma co-activator (PGC) 1, a protein that binds to various transcription factors to maximize transcriptional activity. Activating AMPK using 5-aminoimidizole-4-carboxamide-1-beta-D-riboside (AICAR) and increasing cytoplasmic Ca(2+) using caffeine, W7 or ionomycin in L6 myotubes increases the concentration of mitochondrial enzymes and GLUT4 and enhances the binding of NRF-1 and NRF-2 to DNA. AICAR and Ca-releasing agents also increase the levels of PGC-1, mitochondrial transcription factor A and myocyte-enhancing factors 2A and 2D. These results are similar to the responses seen in muscle during the adaptation to endurance exercise and show that L6 myotubes are a suitable model for studying the mechanisms by which exercise causes the adaptive responses in muscle mitochondria and glucose transport.