High glucose-induced oxidative stress accelerates myogenesis by altering SUMO reactions.

Skeletal muscle preservation is a dynamic process that involves constant repair and regeneration. However, the regenerative capacity of muscle cells declines in hyperglycemia. This study aimed to explore the molecular mechanisms underlying this glucotoxicity during myoblast differentiation. C2C12 cells were exposed to different concentrations of glucose, to recapitulate the development of skeletal muscles in vivo in normo- and hyperglycemic conditions. In high glucose conditions, we found significant increases in levels of total cellular reactive oxygen species (ROS) and a reorganization of SUMO enzyme transcripts and SUMOylated proteins. Furthermore, in anticipation of the ROS-induced damage to newly formed myotubes, we observed acceleration of myogenesis. Interestingly, we found a tight relationship between SUMOylation of the Histone methyltransferase SET7/9 and the maintenance of sarcomeric structures of newly formed myotubes. Finally, treatment with the antioxidant anacardic acid preserved the function and activity of myotubes generated in high-glucose conditions by interfering with both ROS and SUMO pathways. Combined, these results suggest that increased oxidative stress and modulation of SUMO reactions are key mediators of glucotoxicity and inhibition of these perturbations using antioxidants might improve muscle regeneration in hyperglycemia.

Expression of SUMO enzymes is fiber type dependent in skeletal muscles and is dysregulated in muscle disuse.

SUMOylation is a dynamic, reversible, enzymatic drug-targetable post-translational modification (PTM) reaction where the Small Ubiquitin-like Modifier (SUMO) moieties are attached to proteins. This reaction regulates various biological functions like cell growth, differentiation, and it is crucial for maintaining organ homeostasis. However, the actions of SUMO in skeletal muscle pathophysiology are still not investigated. In this study, we quantified the abundance of the SUMO enzymes and determined the distribution of SUMOylated proteins along the fibers of nine different muscles. We find that skeletal muscles contain a distinctive group of SUMO enzymes and SUMOylated proteins in relation to their different metabolism, functions, and fiber type composition. In addition, before the activation of protein degradation pathways, this unique set is quickly altered in response to muscle sedentariness. Finally, we demonstrated that PAX6 acts as an upstream regulator of the SUMO conjugation reaction, which can become a potential therapeutic marker to prevent muscle diseases generated by inactivity.

Circadian regulation of phosphodiesterase 6 genes in zebrafish differs between cones and rods: Implications for photopic and scotopic vision.

A correlation is known to exist between visual sensitivity and oscillations in red opsinand rhodopsin gene expression in zebrafish, both regulated by the clock gene. This indicates that an endogenous circadian clock regulates behavioural visual sensitivity, apart from the regulation exerted by the pineal organ. However, the specific mechanisms for cones (photopic vision) and rods (scotopic vision) are poorly understood. In this work, we performed gene expression, cosinor and immunohistochemical analyses to investigate other key genes involved in light perception, encoding the different subunits of phosphodiesterase pde6 and transducin GαT, in constant lighting conditions and compared to normal light-dark conditions. We found that cones display prominent circadian oscillations in mRNA levels for the inhibitory subunit gene pde6ha that could contribute to the regulation of photopic sensitivity by preventing overstimulation in photopic conditions. In rods, the mRNA levels of the inhibitory subunit gene pde6ga oscillate under normal conditions and dampen down in constant light but continue oscillating in constant darkness. There is an increase in total relative expression for pde6gb in constant conditions. These observations, together with previous data, suggest a complex regulation of the scotopic sensitivity involving endogenous and non-endogenous components, possibly present also in other teleost species. The GαT genes do not display mRNA oscillations and therefore may not be essential for the circadian regulation of photosensitivity. In summary, our results support different regulation for the zebrafish photopic and scotopic sensitivities and suggest circadian regulation of pde6ha as a key factor regulating photopic sensitivity, while the regulatory mechanisms in rods appear to be more complex.

Muscle RING-finger protein-1 (MuRF1) functions and cellular localization are regulated by SUMO1 post-translational modification.

The muscle RING-finger protein-1 (MuRF1) is an E3 ubiquitin ligase expressed in skeletal and cardiac muscle tissues and it plays important roles in muscle remodeling. Upregulation of MuRF1 gene transcription participates in skeletal muscle atrophy, on contrary downregulation of protein expression leads to cardiac hypertrophy. MuRF1 gene point mutations have been found to generate protein aggregate myopathies defined as muscle disorder characterized by protein accumulation in muscle fibers. We have discovered that MuRF1 turned out to be also a target for a new post-translational modification arbitrated by conjugation of SUMO1 and it is mediated by the SUMO ligases E2 UBC9 and the E3 PIASγ/4. SUMOylation takes place at lysine 238 localized at the second coiled-coil protein domain that is required for efficient substrate interaction for polyubiquitination. We provided evidence that SUMOylation is essential for MuRF1 nuclear translocation and its mitochondria accumulation is enhanced in hyperglycemic conditions delivering a stabilization of the overall SUMOylated proteins in cultured myocytes. Thus, our findings add this SUMO1 post-translational modification as a new concept to understand muscle disorders related to the defect in MuRF1 activity.

A Proteomic Approach to Identify Alterations in the Small Ubiquitin-like Modifier (SUMO) Network during Controlled Mechanical Ventilation in Rat Diaphragm Muscle.

The small ubiquitin-like modifier (SUMO) is as a regulator of many cellular functions by reversible conjugation to a broad number of substrates. Under endogenous or exogenous perturbations, the SUMO network becomes a fine sensor of stress conditions by alterations in the expression level of SUMO enzymes and consequently changing the status of SUMOylated proteins. The diaphragm is the major inspiratory muscle, which is continuously active under physiological conditions, but its structure and function is severely affected when passively displaced for long extents during mechanical ventilation (MV). An iatrogenic condition called Ventilator-Induced Diaphragm Dysfunction (VIDD) is a major cause of failure to wean patients from ventilator support but the molecular mechanisms underlying this dysfunction are not fully understood. Using a unique experimental Intensive Care Unit (ICU) rat model allowing long-term MV, diaphragm muscles were collected in rats control and exposed to controlled MV (CMV) for durations varying between 1 and 10 days. Endogenous SUMOylated diaphragm proteins were identified by mass spectrometry and validated with in vitro SUMOylation systems. Contractile, calcium regulator and mitochondrial proteins were of specific interest due to their putative involvement in VIDD. Differences were observed in the abundance of SUMOylated proteins between glycolytic and oxidative muscle fibers in control animals and high levels of SUMOylated proteins were present in all fibers during CMV. Finally, previously reported VIDD biomarkers and therapeutic targets were also identified in our datasets which may play an important role in response to muscle weakness seen in ICU patients. Data are available via ProteomeXchange with identifier PXD006085. Username: reviewer26663@ebi.ac.uk, Password: rwcP5W0o.