@article{StratosRinasSchroepferetal.2023,
  author    = {Stratos, Ioannis and Rinas, Ingmar and Schr{\"o}pfer, Konrad and Hink, Katharina and Herlyn, Philipp and B{\"a}umler, Mario and Histing, Tina and Bruhn, Sven and M{\"u}ller-Hilke, Brigitte and Menger, Michael D. and Vollmar, Brigitte and Mittlmeier, Thomas},
  title     = {Effects on bone and muscle upon treadmill interval training in hypogonadal male rats},
  series = {Biomedicines},
  volume    = {11},
  journal   = {Biomedicines},
  number    = {5},
  issn      = {2227-9059},
  doi       = {10.3390/biomedicines11051370},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-319266},
  year      = {2023},
  abstract  = {Testosterone deficiency in males is linked to various pathological conditions, including muscle and bone loss. This study evaluated the potential of different training modalities to counteract these losses in hypogonadal male rats. A total of 54 male Wistar rats underwent either castration (ORX, n = 18) or sham castration (n = 18), with 18 castrated rats engaging in uphill, level, or downhill interval treadmill training. Analyses were conducted at 4, 8, and 12 weeks postsurgery. Muscle force of the soleus muscle, muscle tissue samples, and bone characteristics were analyzed. No significant differences were observed in cortical bone characteristics. Castrated rats experienced decreased trabecular bone mineral density compared to sham-operated rats. However, 12 weeks of training increased trabecular bone mineral density, with no significant differences among groups. Muscle force measurements revealed decreased tetanic force in castrated rats at week 12, while uphill and downhill interval training restored force to sham group levels and led to muscle hypertrophy compared to ORX animals. Linear regression analyses showed a positive correlation between bone biomechanical characteristics and muscle force. The findings suggest that running exercise can prevent bone loss in osteoporosis, with similar bone restoration effects observed across different training modalities.},
  language  = {en}
}
@article{SchusterJohannsenIsbaryetal.2018,
  author    = {Schuster, Frank and Johannsen, Stephan and Isbary, Susanne and T{\"u}rkmeneli, Ismail and Roewer, Norbert},
  title     = {In vitro effects of levosimendan on muscle of malignant hyperthermia susceptible and non-susceptible swine},
  series = {BMC Anesthesiology},
  volume    = {18},
  journal   = {BMC Anesthesiology},
  number    = {182},
  doi       = {10.1186/s12871-018-0644-z},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-176991},
  year      = {2018},
  abstract  = {Background: The calcium sensitizer levosimendan is increasingly used to improve hemodynamics in patients with acutely decompensated heart failure. By binding to cardiac troponin C the conformation of the calcium-troponin C complex is stabilized, which leads to acceleration of actin-myosin crossbrigde formation and increased force generating capacity of muscle fibers. Besides indications in cardiac failure, beneficial effects of levosimendan in skeletal muscle disorders are currently evaluated. The aim of this study was to investigate differential effects of levosimendan on skeletal muscle of pigs with and without susceptibility to malignant hyperthermia (MH) in order to identify possible risks of this emerging drug for patients with predisposition to MH. Methods: Muscle bundles of 17 pigs (9 MH susceptible (MHS); 8 MH non-susceptible (MHN)) were excised under general anesthesia and examined in the tissue bath with increasing concentrations of levosimendan (0.065; 0.125; 0.5; 1.0; 10 and 50 μg/ml). Baseline tension and twitch force were monitored continuously. Data are presented as median and interquartile range. Statistical evaluation was performed using D'Agostino \& Pearson test for normal distribution and student's t test and 2-way ANOVA for differences between the groups. P < 0.05 was considered significant. Results: There were no differences between the groups concerning length, weight, initial twitch force and pre-drug resting tension of the investigated muscle strips. After an initial decrease in both groups, twitch amplitude was significantly higher in MHN (- 3.0 [- 5.2-0.2] mN) compared to MHS (- 7.5 [- 10.8- -4.5] mN) (p = 0.0034) muscle at an applied levosimendan concentration of 50 μg/ml. A marked increase in resting tension was detected following levosimendan incubation with 50 μg/ml in MHS muscle bundles (3.3 [0.9-6.1] mN) compared to MHN (- 0.7 [- 1.3-0.0] mN) (p < 0.0001). Conclusions: This in vitro investigation revealed the development of significant contractures in muscle bundles of MHS pigs after incubation with levosimendan. However, the effect appeared only at supra-therapeutic concentrations and further research is needed to determine the impact of levosimendan on MHS individuals in vivo.},
  language  = {en}
}
@phdthesis{Sauer2011,
  author    = {Sauer, Florian},
  title     = {Structural studies on the association of filamentous proteins in the human M-Bands},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-72410},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2011},
  abstract  = {Cross-striated muscles enable higher animals to perform directed movements and to create mechanical force. The cells of heart and skeletal muscles consist of myofibrils, serial arrays of the smallest contractile subunits, the sarcomeres. Main components of the sarcomeres are the thin and thick filaments, large protein assemblies consisting of mainly actin (thin filaments) and myosin (thick filaments), whose energy-dependent interaction is responsible for the contraction of sarcomeres and so of the whole muscle. The thin filaments are anchored in the sarcomere bordering Z-discs, while the thick filaments are anchored in the M-bands, traverse structures in the sarcomere center. Electron-microscopic studies revealed that the M-bands consist of regular, lattice-like structures that appear to cross-link the thick filaments. A number of proteins could be identified by immune-fluorescence and biochemical binding studies to be present and interact with each other in the M-bands. These data have been integrated into preliminary models of the M-bands. Detailed knowledge of how these proteins interact with each other in the center of the sarcomeres is, however, largely missing. The current study focuses on the structural characterization of the interactions between the titin, myomesin-1, obscurin and obscurin-like 1 (OBSL1), modular filamentous proteins interacting with each other in the M-bands. The high-resolution crystal structure of the titin M10 - OBSL1 Ig1 complex was solved. The structure and additional biophysical data show that titin and OBSL1 as well as titin and obscurin form stable binary complexes through the formation of a small intermolecular ß-sheet. In contrast to previously characterized intermolecular assemblies of sarcomeric proteins, this sheet is formed between parallel non- homologous ß-strands of the interaction partners. The investigation of disease-related variants of the M10 domain by biophysical methods did not allow to draw unambiguous conclusions on a direct connection between impaired OBSL1/obscurin binding and disease development. Two out of four known M10 variants have effects on the correct domain folding and so interfere with the ability to bind obscurin/OBSL1. The two other known variants displayed however only minor effects on fold and binding affinities. It should therefore be further elucidated whether a direct connection between impaired complex formation and disease development exists. -I- Abstract A direct interaction between titin and myomesin-1 could not be confirmed in vitro. Possible explanations for the different results are discussed. While the consequences of the inability of both proteins to interact are unclear, the further characterization of the putative interacting parts of titin and myomesin-1 led to the discovery of two new potential sites of self-assembly on M-band titin and myomesin-1. The crystal structure of titin M4 showed that this domain can form dimeric assemblies through the formation of a disulfide bridge and an intermolecular metal binding site between residues that are unique to this domain. On myomesin-1, in addition to the described C-terminal interaction site, a potential second site of self-assembly was found in its central Fn3-domain segment. The interacting site was mapped to the predicted Fn3 domain My5. The crystal structure of the domain in its dimeric form showed that the interaction is mediated by a mechanism that has previously not been observed in sarcomeric proteins. Two My5 interact with each other by the mutual exchange of an N-terminal ß-strand which complements the Fn3 fold on the binding partner. This type of interaction can be interpreted as misfolding. However, the position of the interacting domain and its mode of interaction allowed the postulation of a model of how myomesin-1 could be integrated in the M-bands. This model is in good agreement with the electron-microscopic appearance of the M-bands.},
  subject      = {Muskelkontraktion},
  language  = {en}
}
@article{HerrmannEngelkeEbertetal.2020,
  author    = {Herrmann, Marietta and Engelke, Klaus and Ebert, Regina and M{\"u}ller-Deubert, Sigrid and Rudert, Maximilian and Ziouti, Fani and Jundt, Franziska and Felsenberg, Dieter and Jakob, Franz},
  title     = {Interactions between muscle and bone — Where physics meets biology},
  series = {Biomolecules},
  volume    = {10},
  journal   = {Biomolecules},
  number    = {3},
  issn      = {2218-273X},
  doi       = {10.3390/biom10030432},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-203399},
  year      = {2020},
  abstract  = {Muscle and bone interact via physical forces and secreted osteokines and myokines. Physical forces are generated through gravity, locomotion, exercise, and external devices. Cells sense mechanical strain via adhesion molecules and translate it into biochemical responses, modulating the basic mechanisms of cellular biology such as lineage commitment, tissue formation, and maturation. This may result in the initiation of bone formation, muscle hypertrophy, and the enhanced production of extracellular matrix constituents, adhesion molecules, and cytoskeletal elements. Bone and muscle mass, resistance to strain, and the stiffness of matrix, cells, and tissues are enhanced, influencing fracture resistance and muscle power. This propagates a dynamic and continuous reciprocity of physicochemical interaction. Secreted growth and differentiation factors are important effectors of mutual interaction. The acute effects of exercise induce the secretion of exosomes with cargo molecules that are capable of mediating the endocrine effects between muscle, bone, and the organism. Long-term changes induce adaptations of the respective tissue secretome that maintain adequate homeostatic conditions. Lessons from unloading, microgravity, and disuse teach us that gratuitous tissue is removed or reorganized while immobility and inflammation trigger muscle and bone marrow fatty infiltration and propagate degenerative diseases such as sarcopenia and osteoporosis. Ongoing research will certainly find new therapeutic targets for prevention and treatment.},
  language  = {en}
}