RESUMO
Brugada syndrome (BrS) is a rare genetic arrhythmic disorder with a complex model of transmission. At least 20 different genes have been identified as BrS-causal or susceptibility genes. Of these, SCN5A is the most frequently mutated. Coregulation of different mutations or genetic variants, including mitochondrial DNA (mtDNA), may contribute to the clinical phenotype of the disease. In the present study, we analysed the mitochondrial genome of a symptomatic BrS type 1 patient to investigate a possible mitochondrial involvement recently found in the arrhytmogenic diseases. No pathogenic mutation was identified; however, a high number of singlenucleotide polymorphisms were found (n=21) and some of them were already been reported in molecular autopsy case for sudden death. The results reported here further support our hypothesis on the potential role of mtDNA polymorphisms in mitochondrial dysfunction, which may represent a risk factor for arrhythmogenic disease.
RESUMO
Surgical resection at any location in the body leads to stress response with cellular and subcellular change, leading to tissue damage. The intestine is extremely sensitive to surgical stress with consequent postoperative complications. It has been suggested that the increase of reactive oxygen species as subcellular changes plays an important role in this process. This article focuses on the effect of surgical stress on nuclear and mitochondrial DNA from healthy sections of colon and rectum of patients with colorectal cancer. Mitochondrial DNA copy number, mitochondrial common deletion and nuclear and mitochondrial 8-oxo-2′-deoxyguanosine content were measured. Both the colon and rectal tissue were significantly damaged either at the nuclear or mitochondrial level. In particular, mitochondrial DNA was more damaged in rectum than in colon. The present investigation found an association between surgical stress and nuclear and mitochondrial DNA damage, suggesting that surgery may generate an increase in free radicals, which trigger a cascade of molecular changes, including alterations in DNA.