Aging-dependent mitochondrial bioenergetic impairment in the skeletal muscle of NNT-deficient mice.

Overall health relies on features of skeletal muscle that generally decline with age, partly due to mechanisms associated with mitochondrial redox imbalance and bioenergetic dysfunction. Previously, aged mice genetically devoid of the mitochondrial NAD(P)+ transhydrogenase (NNT, encoded by the nicotinamide nucleotide transhydrogenase gene), an enzyme involved in mitochondrial NADPH supply, were shown to exhibit deficits in locomotor behavior. Here, by using young, middle-aged, and older NNT-deficient (Nnt-/-) mice and age-matched controls (Nnt+/+), we aimed to investigate how muscle bioenergetic function and motor performance are affected by NNT expression and aging. Mice were subjected to the wire-hang test to assess locomotor performance, while mitochondrial bioenergetics was evaluated in fiber bundles from the soleus, vastus lateralis and plantaris muscles. An age-related decrease in the average wire-hang score was observed in middle-aged and older Nnt-/- mice compared to age-matched controls. Although respiratory rates in the soleus, vastus lateralis and plantaris muscles did not significantly differ between the genotypes in young mice, the rates of oxygen consumption did decrease in the soleus and vastus lateralis muscles of middle-aged and older Nnt-/- mice. Notably, the soleus, which exhibited the highest NNT expression level, was the muscle most affected by aging, and NNT loss. Additionally, histology of the soleus fibers revealed increased numbers of centralized nuclei in older Nnt-/- mice, indicating abnormal morphology. In summary, our findings suggest that NNT expression deficiency causes locomotor impairments and muscle dysfunction during aging in mice.

High susceptibility of activated lymphocytes to oxidative stress-induced cell death

The present study provides evidence that activated spleen lymphocytes from Walker 256 tumor bearing rats are more susceptible than controls to tert-butyl hydroperoxide (t-BOOH)-induced necrotic cell death in vitro. The iron chelator and antioxidant deferoxamine, the intracellular Ca2+ chelator BAPTA, the L-type Ca2+ channel antagonist nifedipine or the mitochondrial permeability transition inhibitor cyclosporin A, but not the calcineurin inhibitor FK-506, render control and activated lymphocytes equally resistant to the toxic effects of t-BOOH. Incubation of activated lymphocytes in the presence of t-BOOH resulted in a cyclosporin A-sensitive decrease in mitochondrial membrane potential. These results indicate that the higher cytosolic Ca2+ level in activated lymphocytes increases their susceptibility to oxidative stress-induced cell death in a mechanism involving the participation of mitochondrial permeability transition.

O presente estudo demonstra que linfócitos ativados de baço de ratos portadores do tumor de Walker 256 são mais susceptíveis à morte celular necrótica induzida por tert-butil hidroperóxido (t-BOOH) in vitro quando comparados aos controles. O quelante de ferro e antioxidante deferoxamina, o quelante intracelular de Ca2+ BAPTA, o antagonista de canal de Ca2+ nifedipina ou o inibidor da transição de permeabilidade mitocondrial ciclosporina-A, mas não o inibidor de calcineurina FK-506, inibiram de maneira similar a morte celular induzida por t-BOOH em linfócitos ativados e controles. Os linfócitos ativados apresentaram redução do potencial de membrana mitocondrial induzida por t-BOOH num mecanismo sensível a ciclosporina-A. Nossos resultados indicam que o aumento da concentração de Ca2+ citosólico em linfócitos ativados aumenta a susceptibilidade dos mesmos à morte celular induzida por estresse oxidativo, num mecanismo envolvendo a participação do poro de transição de permeabilidade mitocondrial.

Mitochondrial oxidative damage promoted by a synergism betweem Ca2+ and prooxidants: inner membrane permeabilization and mtDNA breakage

Oxidative damage of mitochondria induced by a synergism between Ca2+ and prooxidants is mediated by the attack of mitochondria-generated reactive oxygen species to membrane proteins, lipids and DNA. This results in mitochondrial DNA fragmentation, lipid peroxidation and oxidation of vicinal protein thiols producing high molecular weight membrane protein aggregates. The membrane protein alterations lead to a condition called mitochondrial membrane permeability transition, characterized by formation of nonspecific membrane protein pores sensitive to cyclosporin A, EGTA, dithiothreitol, Mg2+ and ADP. We propose that these alterations are related to the mechanisms by which cells are killed by a series of toxins, xenobiotics or pathological conditions such as prolonged hypoxia or ischemia/reperfusion.