Food restriction reverses the hyper-muscular phenotype and force generation capacity deficit of the myostatin null mouse.

Food restriction has a great impact on skeletal muscle mass by inducing muscle protein breakdown to provide substrates for energy production through gluconeogenesis. Genetic models of hyper-muscularity interfere with the normal balance between protein synthesis and breakdown which eventually results in extreme muscle growth. Mutations or deletions in the myostatin gene result in extreme muscle mass. Here we evaluated the impact of food restriction for a period of 5 weeks on skeletal muscle size (i. e., fibre cross-sectional area), fibre type composition and contractile properties (i. e., tetanic and specific force) in myostatin null mice. We found that this hyper-muscular model was more susceptible to catabolic processes than wild type mice. The mechanism of skeletal muscle mass loss was examined and our data shows that the myostatin null mice placed on a low calorie diet maintained the activity of molecules involved in protein synthesis and did not up-regulate the expression of genes pivotal in ubiquitin-mediated protein degradation. However, we did find an increase in the expression of genes associated with autophagy. Surprisingly, the reduction on muscle size was followed by improved tetanic and specific force in the null mice compared to wild type mice. These data provide evidence that food restriction may revert the hyper-muscular phenotype of the myostatin null mouse restoring muscle function.

The role of autophagy in the pathogenesis of glycogen storage disease type II (GSDII).

Regulated removal of proteins and organelles by autophagy-lysosome system is critical for muscle homeostasis. Excessive activation of autophagy-dependent degradation contributes to muscle atrophy and cachexia. Conversely, inhibition of autophagy causes accumulation of protein aggregates and abnormal organelles, leading to myofiber degeneration and myopathy. Defects in lysosomal function result in severe muscle disorders such as Pompe (glycogen storage disease type II (GSDII)) disease, characterized by an accumulation of autophagosomes. However, whether autophagy is detrimental or not in muscle function of Pompe patients is unclear. We studied infantile and late-onset GSDII patients and correlated impairment of autophagy with muscle wasting. We also monitored autophagy in patients who received recombinant α-glucosidase. Our data show that infantile and late-onset patients have different levels of autophagic flux, accumulation of p62-positive protein aggregates and expression of atrophy-related genes. Although the infantile patients show impaired autophagic function, the late-onset patients display an interesting correlation among autophagy impairment, atrophy and disease progression. Moreover, reactivation of autophagy in vitro contributes to acid α-glucosidase maturation in both healthy and diseased myotubes. Together, our data suggest that autophagy protects myofibers from disease progression and atrophy in late-onset patients.

Evidence of an involvement of TFAP2A gene in non-syndromic cleft lip with or without cleft palate: an Italian study.

Unraveling of factors involved in multifactorial diseases is a great challenge. Different approaches can be contemplate and applied to a variety of congenital malformations. In the present investigation TFAP2A has been considered a good candidate gene for nonsyndromic cleft lip with or without cleft palate (NSCLP) aetiology, basing on a sum of considerations. TFAP2A has been seen involved in orofacial development in mice; it is located in the NSCLP candidate region 6p24; it codes for a transcription factor which regulates expression of IRF6, a gene implied in NSCLP; finally, it is embroiled in the branchiooculofacial syndrome, that includes clefting as feature. A family based association analysis was performed with a sample study of 405 NSCLP triads. Evidence of association was obtained with both single marker and haplotype analyses, thus providing a support for TFAP2A in NSCLP aetiology.

Normal myogenesis and increased apoptosis in myotonic dystrophy type-1 muscle cells.

Myotonic dystrophy (DM) is caused by a (CTG)(n) expansion in the 3'-untranslated region of DMPK gene. Mutant transcripts are retained in nuclear RNA foci, which sequester RNA binding proteins thereby misregulating the alternative splicing. Controversy still surrounds the pathogenesis of the DM1 muscle distress, characterized by myotonia, weakness and wasting with distal muscle atrophy. Eight primary human cell lines from adult-onset (DM1) and congenital (cDM1) patients, (CTG)(n) range 90-1800, were successfully differentiated into aneural-immature and contracting-innervated-mature myotubes. Morphological, immunohistochemical, RT-PCR and western blotting analyses of several markers of myogenesis indicated that in vitro differentiation-maturation of DM1 myotubes was comparable to age-matched controls. In all pathological muscle cells, (CTG)(n) expansions were confirmed by long PCR and RNA fluorescence in situ hybridization. Moreover, the DM1 myotubes showed the splicing alteration of insulin receptor and muscleblind-like 1 (MBNL1) genes associated with the DM1 phenotype. Considerable myotube loss and atrophy of 15-day-differentiated DM1 myotubes indicated activated catabolic pathways, as confirmed by the presence of apoptotic (caspase-3 activation, cytochrome c release, chromatin fragmentation) and autophagic (P62/LC3) markers. Z-VAD treatment significantly reduced the decrease in myonuclei number and in average width in 15-day-differentiated DM1 myotubes. We thus propose that the muscle wasting typical in DM1 is due to impairment of muscle mass maintenance-regeneration, through premature apoptotic-autophagic activation, rather than altered myogenesis.

The MTHFD1 gene is not involved in cleft lip with or without palate onset among the Italian population.

Nonsyndromic cleft lip with or without cleft palate (CL/P) is the most common orofacial malformation, having a non-Mendelian and multifactorial aetiology. It has been shown that polymorphic variants of genes encoding key proteins of folate and methionine metabolism might be important maternal risk factors for having a child with these craniofacial anomalies. The aim of this study was to evaluate the role of two polymorphisms of the methylenetetrahydrofolate dehydrogenase 1 (MTHFD1) gene, the A1958G and the G401A variants, on the risk of CL/P in the Italian population. A1958G and G401A polymorphism genotyping of MTHFD1 was performed on 216 CL/P triads, (patient and parents), for this study by restriction endonuclease digestion of PCR products. Linkage disequilibrium between markers and disease was tested using both pairwise and haplotype analyses. In our case-parents triad design no significant association between MTHFD1 and the disease is evident. Our data do not support MTHFD1 involvement in CL/P onset among the Italian population.