Deletion of Kinin B2 Receptor Alters Muscle Metabolism and Exercise Performance.

Metabolic syndrome is a cluster of metabolic risk factors such as obesity, diabetes and cardiovascular diseases. Mitochondria is the main site of ATP production and its dysfunction leads to decreased oxidative phosphorylation, resulting in lipid accumulation and insulin resistance. Our group has demonstrated that kinins can modulate glucose and lipid metabolism as well as skeletal muscle mass. By using B2 receptor knockout mice (B2R-/-) we investigated whether kinin action affects weight gain and physical performance of the animals. Our results show that B2R-/- mice are resistant to high fat diet-induced obesity, have higher glucose tolerance as well as increased mitochondrial mass. These features are accompanied by higher energy expenditure and a lower feed efficiency associated with an increase in the proportion of type I fibers and intermediary fibers characterized by higher mitochondrial content and increased expression of genes related to oxidative metabolism. Additionally, the increased percentage of oxidative skeletal muscle fibers and mitochondrial apparatus in B2R-/- mice is coupled with a higher aerobic exercise performance. Taken together, our data give support to the involvement of kinins in skeletal muscle fiber type distribution and muscle metabolism, which ultimately protects against fat-induced obesity and improves aerobic exercise performance.

Nearest-neighbor nitrogen and oxygen distances in the iron(II)-DNA complex studied by extended X-ray absorption fine structure.

In mammalian cells, DNA-bound Fe(II) reacts with H2O2 producing the highly reactive hydroxyl radical (OH) in situ. Since ·OH attacks nearby DNA residue generating oxidative DNA damage, many questions have arisen regarding iron-DNA complex formations and their implication in pre-malignant mutations and aging. In this work, a solid sample of Fe(II)-DNA complex containing one Fe(II) per 10 nucleotides was analyzed from extended X-ray absorption fine structure (EXAFS) spectra collected in a synchrotron radiation light source. Best fitting parameters of the EXAFS signal for the first two shells provide evidence of five oxygen atoms at 1.99 ± 0.02 Å and one nitrogen atom at 2.20 ± 0.02 Å in the inner coordination sphere of the Fe(II)-DNA complex. Considering that both purine base moieties bearing nitrogen atoms are prone to chelate iron, these results are consistent with the previously observed lower levels of DNA damage in cytosine nucleotides relative to adenine and guanine sites in cells under more physiological conditions of Fe(II) Fenton reaction.

Mitochondrial DNA damage associated with lipid peroxidation of the mitochondrial membrane induced by Fe2+-citrate

Desequilíbrio/acúmulo de ferro tem sido implicado em injúria oxidativa associada a diversas doenças degenerativas tais como, hemocromatose hereditária, b-talassemia e ataxia de Friedreich. As mitocôndrias são particularmente sensíveis a estresse oxidativo induzido por ferro - um carregamento alto de ferro em mitocôndrias isoladas pode causar uma extensiva peroxidação lipídica e a permeabilização de membrana. Nesse estudo, nós detectamos e caracterizamos danos do DNA mitocondrial em mitocôndrias isoladas de fígado de rato, expostas ao complexo Fe2+-citrato, um dos complexos de baixo peso molecular. A intensa fragmentação do DNA foi induzida após a incubação das mitocôndrias com o complexo de ferro. A detecção de finais 3' de fosfoglicolato nas quebras de fitas de DNA mitocondrial pelo ensaio 32P-postlabeling sugere um envolvimento de radicais hidroxila na fragmentação do DNA induzido por complexo Fe2+-citrato. Os níveis elevados de 8-oxo-7,8-diidro-2'-desoxiguanosina também sugerem que o estresse oxidativo induzido por Fe2+-citrato causa danos no DNA mitocondrial. Em conclusão, nossos resultados mostram que a peroxidação lipídica mediada por ferro esteve associada com severos danos do DNA mitocondrial derivados de ataque direto das espécies reativas de oxigênio.

Mitochondrial DNA damage associated with lipid peroxidation of the mitochondrial membrane induced by Fe2+-citrate.

Iron imbalance/accumulation has been implicated in oxidative injury associated with many degenerative diseases such as hereditary hemochromatosis, beta-thalassemia, and Friedreich's ataxia. Mitochondria are particularly sensitive to iron-induced oxidative stress - high loads of iron cause extensive lipid peroxidation and membrane permeabilization in isolated mitochondria. Here we detected and characterized mitochondrial DNA damage in isolated rat liver mitochondria exposed to a Fe2+-citrate complex, a small molecular weight complex. Intense DNA fragmentation was induced after the incubation of mitochondria with the iron complex. The detection of 3' phosphoglycolate ends at the mtDNA strand breaks by a 32P-postlabeling assay, suggested the involvement of hydroxyl radical in the DNA fragmentation induced by Fe2+-citrate. Increased levels of 8-oxo-7,8-dihydro-2'-deoxyguanosine also suggested that Fe2+-citrate-induced oxidative stress causes mitochondrial DNA damage. In conclusion, our results show that iron-mediated lipid peroxidation was associated with intense mtDNA damage derived from the direct attack of reactive oxygen species.