Logic model development for the exercise is medicine-on campus initiative.

One strategy to encourage college students to meet physical activity and public health guidelines is the Exercise is Medicine on Campus Initiative (EIM-OC), whose goal is to promote physical activity as a vital health sign within universities. To develop, implement, and evaluate the EIM-OC Initiative, it is critical to understand the mechanics of the program via a logic model. Objective: The objective is to present a conceptual logic model for EIM-OC Initiative implementation. Methods: Using an activities-approach framework, a logic model was developed using inputs, activities, outputs, and outcomes. Results: This logic model serves as a guide for the conceptual relationships within the EIM-OC Initiative. It was hypothesized that the EIM-OC Initiative would have an overarching outcome of improving physical activity levels in the university setting to promote overall community wellness and health. Conclusion: The authors anticipate this logic model will serve as a framework for other universities implementing EIM-OC.

miR-379 links glucocorticoid treatment with mitochondrial response in Duchenne muscular dystrophy.

Duchenne Muscular Dystrophy (DMD) is a lethal muscle disorder, caused by mutations in the DMD gene and affects approximately 1:5000-6000 male births. In this report, we identified dysregulation of members of the Dlk1-Dio3 miRNA cluster in muscle biopsies of the GRMD dog model. Of these, we selected miR-379 for a detailed investigation because its expression is high in the muscle, and is known to be responsive to glucocorticoid, a class of anti-inflammatory drugs commonly used in DMD patients. Bioinformatics analysis predicts that miR-379 targets EIF4G2, a translational factor, which is involved in the control of mitochondrial metabolic maturation. We confirmed in myoblasts that EIF4G2 is a direct target of miR-379, and identified the DAPIT mitochondrial protein as a translational target of EIF4G2. Knocking down DAPIT in skeletal myotubes resulted in reduced ATP synthesis and myogenic differentiation. We also demonstrated that this pathway is GC-responsive since treating mice with dexamethasone resulted in reduced muscle expression of miR-379 and increased expression of EIF4G2 and DAPIT. Furthermore, miR-379 seric level, which is also elevated in the plasma of DMD patients in comparison with age-matched controls, is reduced by GC treatment. Thus, this newly identified pathway may link GC treatment to a mitochondrial response in DMD.

Sequential expression of genes involved in muscular dystrophies during human development.

To elucidate the normal and pathophysiological roles of genes involved in the aetiology of muscular dystrophies, we studied the expression of dystrophin, four sarcoglycans, beta-dystroglycan and merosin during early human development. These proteins are expressed mainly in skeletal muscles while dystrophin, beta-dystroglycan, delta-sarcoglycan and merosin are in cardiac and smooth muscles. Dystrophin, beta-, delta-sarcoglycan and beta-dystroglycan are first expressed in the myotome at the 4th week of human embryogenesis, followed by gamma-sarcoglycan and merosin at the 6th week of development; alpha-sarcoglycan appears only at the level of the muscular fibre at the end of the embryonic period.

Calpain3 expression during human cardiogenesis.

Transcripts of calpain3, the gene involved in limb girdle muscular dystrophy type 2A, appear in organs other than the skeletal muscle during human development, the first of which being the early embryonic heart. We examined more precisely the spatio-temporal transcription pattern of calpain3 during human cardiogenesis and the appearance of its protein in fetal tissues, and correlated it to titin expression. Different events of the heart's maturation can be recognized: (i) the presence of titin RNA or protein constitute very precocious developmental cardiac markers appearing before the fusion of the two lateral endocardial tubes; (ii) the disappearance of calpain3 RNA from the ventricular compartment later in the embryonic heart. Finally, although calpain3 transcripts are present in the heart, the corresponding protein is not detected elsewhere than in skeletal muscle.

Loss of calpain 3 proteolytic activity leads to muscular dystrophy and to apoptosis-associated IkappaBalpha/nuclear factor kappaB pathway perturbation in mice.

Calpain 3 is known as the skeletal muscle-specific member of the calpains, a family of intracellular nonlysosomal cysteine proteases. It was previously shown that defects in the human calpain 3 gene are responsible for limb girdle muscular dystrophy type 2A (LGMD2A), an inherited disease affecting predominantly the proximal limb muscles. To better understand the function of calpain 3 and the pathophysiological mechanisms of LGMD2A and also to develop an adequate model for therapy research, we generated capn3-deficient mice by gene targeting. capn3-deficient mice are fully fertile and viable. Allele transmission in intercross progeny demonstrated a statistically significant departure from Mendel's law. capn3-deficient mice show a mild progressive muscular dystrophy that affects a specific group of muscles. The age of appearance of myopathic features varies with the genetic background, suggesting the involvement of modifier genes. Affected muscles manifest a similar apoptosis-associated perturbation of the IkappaBalpha/nuclear factor kappaB pathway as seen in LGMD2A patients. In addition, Evans blue staining of muscle fibers reveals that the pathological process due to calpain 3 deficiency is associated with membrane alterations.

Human-mouse differences in the embryonic expression patterns of developmental control genes and disease genes.

Our understanding of early human development has been impeded by the general difficulty in obtaining suitable samples for study. As a result, and because of the extraordinarily high degree of evolutionary conservation of many developmentally important genes and developmental pathways, great reliance has been placed on extrapolation from animal models of development, principally the mouse. However, the strong evolutionary conservation of coding sequence for developmentally important genes does not necessarily mean that their expression patterns are as highly conserved. The very recent availability of human embryonic samples for gene expression studies has now permitted for the first time an assessment of the degree to which we can confidently extrapolate from studies of rodent gene expression patterns. We have found significant human-mouse differences in embryonic expression patterns for a variety of genes. We present detailed data for two illustrative examples. Wnt7a, a very highly conserved gene known to be important in early development, shows significant differences in spatial and temporal expression patterns in the developing brain (midbrain, telencephalon) of man and mice. CAPN3, the locus for LGMD2A limb girdle muscular dystrophy, and its mouse orthologue differ extensively in expression in embryonic heart, lens and smooth muscle. Our study also shows how molecular analyses, while providing explanations for the observed differences, can be important in providing insights into mammalian evolution.

Expression of genes (CAPN3, SGCA, SGCB, and TTN) involved in progressive muscular dystrophies during early human development.

The developmental expression pattern of four human genes, three of which are involved in progressive muscular dystrophies, was investigated. The rationale for these experiments is that these patterns might provide useful information on the pathophysiology underlying these myopathies. Despite the presence of overlapping clinical signs, the spatiotemporal expression profiles of the corresponding genes differed widely. Transcripts of alpha-sarcoglycan (SGCA) were visible as soon as myotomes were formed, and constitute, together with titin transcripts, precocious muscular system landmarks. beta-sarcoglycan (SGCB) was initially transcribed in a ubiquitous manner, and, toward the second part of the embryonic period, became specific to striated muscle, heart, and the central nervous system. Whereas titin (TTN) transcription and translation seem to be coupled, for the sarcoglycans, translation seemed restricted to skeletal muscle. Calpain3 (CAPN3) RNA was found in only skeletal muscles during the fetal period. It was, however, present earlier in the whole heart, where it selectively disappeared. Finally, evidence for differentially spliced calpain3 variants in smooth muscles was also seen. The expression profiles of these genes is suggestive of their having a role during myogenesis, knowledge of which could be pertinent to the understanding of the pathophysiology of the associated diseases.