RESUMO
Aging-related alteration of mitochondrial morphology, impairment in metabolic capacity, bioenergetics, and biogenesis are closely associated with loss of muscle mass and function. Mitochondrial Reactive Oxygen Species (ROS) stimulate muscular redox signaling mechanisms. Bioenergetic integrity of mitochondria and redox signaling dynamics deteriorates in aged skeletal muscle. Mitochondrial bioenergetic impairment leads to excessive ROS levels and induces the generation of defective mitochondria. Higher ROS levels may induce senescence or apoptosis. It is not a resolved issue that mitochondrial dysfunction is either the sole reason or a consequence of muscle loss (or both). However, Increasing evidence emphasizes that dysregulated mitochondrial redox signaling has a central role in age-related muscle loss. Nuclear factor erythroid 2-related factor 2 (Nrf2) regulates redox signaling pathways with the expression of antioxidant genes. As the aberrant redox signaling mechanisms in aging skeletal muscle become clearer, new natural and synthetic Nrf2-modulating substances and integrated daily physical activity alternatives are coming into view for preventing muscle loss in the elderly. A comprehensive understanding of the relationship between redox signaling pathways and age-related sarcopenia can help us to prevent sarcopenia and its frailty effects with an optimized exercise program as an innovative non-pharmacological therapeutic approach. A further aspect is necessary to consider both individualized physical training options and alternative Nrf2 signaling modulators. Ameliorating the redox signaling with physical activity and pharmacological interventions may help to prevent sarcopenia and its frailty effects.
RESUMO
BACKGROUND: Intercellular adhesion molecule-1 (ICAM-1) is a surface glycoprotein important for tumor invasion and angiogenesis. The present research is conducted to investigate whether specific gene polymorphism of ICAM-1 K469E (rs5498) and plasma redox status could be associated with laryngeal cancer (LC) development. Since there is no clear evidence which investigates the relationship between ICAM-1 polymorphism and ROS-mediated plasma protein oxidation in LC, our study is the first significant contribution for investigating the relationship. METHODS: The study covered patients with primary LC and their age-matched healthy control subjects. Evaluation of ICAM-1 K469E (rs5498) gene polymorphism was performed by polymerase chain reaction-restriction fragment length polymorphism. Plasma redox status was assessed with spectrophotometric methods. RESULTS: In the current paper, we found that LC patients with GG genotype had a decreasing trend for the plasma oxidative damage biomarker levels when compared with all allele genotypes (AA and AG). CONCLUSION: We concluded that G allele of the ICAM-1 K469E gene plays a significant role in the optimal regulation of plasma redox homeostasis in patients with LC.