The knowledge of the haplogroups of the analyzed subjects allows to prevent errors in the analysis of the association between mtDNA variations and some pathologies like diabetes. In this paper a cohort of type 2 diabetic Italian patients with known mitochondrial genetic background (haplogroup) were investigated for the presence in the blood of the 3243A>G mutation and other variants of close to tRNA(Leu(UUR)) gene (16S/ND1 region) of mitochondrial DNA (mtDNA). The 3243A>G mutation was present in 0.4% of analyzed patients in agreement with the reported frequencies of such mutation in other European groups. This result suggests a limited role for the 3243A>G mutation in the pathogenesis of diabetes also in the Italian population. In the 16S/ND1 region 15 base changes were found. The knowledge of the haplogroup of the analyzed individuals

BACKGROUND: An increase in mitochondrial DNA (mtDNA) content and mitochondrial biogenesis associated with the activation of PGC-1alpha signalling pathway was previously reported in type I endometrial cancer. The aim of this study has been to evaluate if mtDNA content and the citrate synthase (CS) activity, an enzyme marker of mitochondrial mass, increase in progression from control endometrium to hyperplasia to type I endometrial carcinoma. RESULTS: Given that no statistically significant change in mtDNA content and CS activity in endometrium taken from different phases of the menstrual cycle or in menopause was found, these samples were used as control. Our research shows, for the first time, that mtDNA content and citrate synthase activity increase in hyperplastic endometrium compared to control tissues, even if their levels remain lower compared to cancer tissue. In particular, mtDNA content increases seem to precede increases in CS activity. No statistically significant change in mtDNA content and in CS activity was found in relation to different histopathological conditions such as grade, myometrial invasion and stage. CONCLUSION: MtDNA content and citrate synthase activity increases in pre-malignant lesions could be a potential molecular marker for progression from hyperplasia to carcinoma.

Type I endometrial cancer (EC) is the most common form of EC, displaying less aggressive behavior than type II. The development of type I endometrial cancer is considered a multistep process, with slow progression from normal endometrium to hyperplasia, the premalignant form, and endometrial cancer as a result of an unopposed estrogenic stimulation. The role of mitochondria in type I EC tumor progression and prognosis is currently emerging. This review aims to explore mitochondrial alterations in this cancer and in endometrial hyperplasia focusing on mitochondrial DNA mutations, respiratory complex I deficiency, and the activation of mitochondrial quality control systems. A deeper understanding of altered mitochondrial pathways in type I EC could provide novel opportunities to discover new diagnostic and prognostic markers as well as potential therapeutic targets.

Mitochondrial DNA (mtDNA) mutations have been described in almost all types of cancer. However, their exact role and timing of occurrence during tumor development and progression are still a matter of debate. A Vogelstein-like model of progression is well established for endometrial carcinoma (EC), however, mtDNA has been scarcely investigated in these tumors despite the fact that mitochondrial biogenesis increase has been shown to be a hallmark of type I EC. Here, we screened a panel of 23 type I EC tissues and matched typical hyperplasia for mutations in mtDNA and in four oncosupressors/oncogenes, namely PTEN, KRAS, CTNNB1 and TP53. Overall, mtDNA mutations were identified in 69% of cases, while mutational events in nuclear genes occurred in 56% of the cases, indicating that mtDNA mutations may precede the genetic instability of these genes canonically involved in progression from hyperplasia to tumor. Protein expression analysis revealed an increase in mitochondrial biogenesis and activation of oxidative stress response mechanisms in tumor tissues, but not in hyperplasia, in correlation with the occurrence of pathogenic mtDNA mutations. Our results point out an involvement of mtDNA mutations in EC progression and explain the increase in mitochondrial biogenesis of type I EC. Last, since mtDNA mutations occur after hyperplasia, their potential role in contributing to genetic instability may be envisioned.