Comparative study of the active and passive properties in mdx/utrn +/- and mdx with different ages

Duchenne Muscular Dystrophy (DMD) is an important and severe muscle wasting disease caused by a dystrophin mutation. In the absence of dystrophin, sarcolemma becomes vulnerable to damage due a damage caused by continuous cycles of degeneration regeneration. Consequently, the muscle force reduces and the myofibers are replaced by fibrotic tissue. Between the skeletal muscles, the diaphragm is main affected muscle in DMD. Similarly, to a human DMD, despite the mdx model exhibit a milder phenotype, he presents the diaphragm muscle severely affected, as it was observed in our previous study, here described. However, it is also considered a poor model because it cannot reproduce the severe dystrophic phenotype seen in patients. An utrophin heterozygous utrophin mice (mdx/utrn+/- ), has been hypothesized as an intermediate model and they are gaining popularity in many laboratories. However unfortunately there is currently, no physiological enough evidence to justify the choice of this model for experimental therapies. Therefore, in this study, we aimed to elucidate the real contribution of the mdx/utrn+/- for the experimental therapies. To test this hypothesis, we evaluated the diaphragm muscle morphology and muscle function of the mdx and mdx/utrn+/- with 2 and 6 months. To elucidate the diaphragm morphology, we used light microscopy techniques and immunostaining analysis. Muscle function was evaluated through the active and passive properties. The clamps allowed to safe evaluate the diaphragm function. The update of the new protocol was efficient and able to evaluate the active and passive properties. At 2 months, the Hematoxylin and eosin, Masson Thrichome, Alisarine red, revealed that the mdx/utrn+ showed more inflammatory infiltrate, connective tissue and more areas with calcification than mdx model. At 6 months, there was no significant differences between mdx and mdx/utrn+. In the immunohistochemical analysis for eMyHC (embryonic myosin heavy chain), there was no difference between mdx and mdx/utrn+/- at 2 and 6 months. However, the results obtained in both ages, showed muscle regeneration Marking for dystrophin and utrophin protein, inflammatory cells and fiber type were also detected by immunohistochemistry. Marking for dystrophin was absent in mdx and mdx/utrn+/- with 2 and 6 months. Marking for utrophin protein was more evident in mdx than in mdx/utrn+/- mice, evidencing the utrophin haploinsufficiency in mdx/utr+/-. Macrophages were increased in mdx/utrn+/- than in mdx mice with 2 and 6 months, showing an inflammation. Neutrophils were increased in mdx/utrn+/- at 2 month-old, evidencing the acute phase of inflammation. However, at 6 months similar amounts of neutrophil were detected in mdx and mdx/utrn+/-. Fibers marked by MyHC-I, IIa and IIx were detected in a higher percentage in BL10 than in mdx and mdx/utrn+/- at 2 months, showing that this change could collaborate with force decrease in these animals. At 6 months, similar percentage of MyHC-I was detected in BL10, mdx and mdx/utrn+/-. MyHC-IIa animals were not found at 6 months. Higher percentage of MyHC-IIx was found in BL10 than in mdx and mdx/utrn+/- with 6 months. Low percentage of MyHC- I/IIa was detected in mdx and mdx/utrn+/- at 2 and 6 months and it was absent in BL10 in the same age. Fibers marked by MyHC-IIa/IIx isoforms were increased in mdx and mdx/utrn+/- with 2 and 6 months. These changes could help to maintain the muscle force. MyHC-IIx-IIb was detected in higher percentage in mdx, reduced the BL10 and it was absent in mdx/utrn+/- with 2 months. MyHC-IIx-IIb was not identified in the animals with 6 months. Contractile properties in mdx/utrn+/- at 2 months were more affected than in mdx mice. Pt (maximal twitch force), sPt (specific twitch force), Po (maximal tetanic force) and sPo (specific tetanic force) showed more severely affected in mdx/utrn+/- than in mdx mice. At 6 months there were no significant difference in Pt, sPt, Po and sPo between mdx/utrn+/- and mdx mice. Passive properties of mdx/utrn+/- with 2 months presented more affected than the in mdx mice. However, at 6 months, this property did not differ between mdx/utrn+/- and mdx mice. In summary, we concluded that the mdx/utrn+/- at 2 month represent a superior model than the mdx with matched-age, since they presented morphology and contractile and passive properties more compromised than mdx mice. At 6 months, the mdx/utrn+/-contractile and the passive properties and morphology did not differ from the mdx mice age-matched. We suggest that the use of mdx/utrn+/- with 2 months-old would represent would represent a better model to test the potential of the therapies than mdx mice (AU)