Inhibitory effect of atorvastatin on the cell growth of cardiac myxomas via the PTEN and PHLPP2 phosphatase signaling pathway.

Insulin-like growth factor 1 (IGF-1) is a molecule with strong proliferative effects, and statins have been reported to exhibit antitumor effects based on clinical and experimental studies. However, their effects on cardiac myxoma (CM) cells and the underlying signaling mechanism(s) are largely unknown. Therefore, we investigated whether the protein/lipid phosphatases and tensin homolog deleted on chromosome ten (PTEN) and pleckstrin homology domain leucine-rich repeat phosphatase 1 and 2 (PHLPP1 and 2) are involved in the proliferative effect of IGF-1 on CM cells and the pharmacological impact of atorvastatin. The activity of PTEN and PHLPPs was determined using specific substrate diC16PIP3 and pNPP. We found that IGF-1 enhanced CM cell proliferation and inhibited both PTEN and PHLPP2 activity in a concentration- and time-dependent manner. Atorvastatin acted counter to IGF-1 and reversed the above effects mediated by IGF-1. Both IGF-1 and atorvastatin did not affect the activity of PHLPP1 and the protein expression of the three phosphatases. The results suggest that IGF-1 may exert its proliferative effects by negatively regulating the PTEN/PHLPP2 signaling pathway in CM cells, and atorvastatin may be a potential drug for the treatment of CM by enhancing the activity of PTEN and PHLPP2.

Mitochondrial DNA content varies with pathological characteristics of breast cancer.

Changes in mitochondrial DNA (mtDNA) content in cancers have been reported with controversial results, probably due to small sample size and variable pathological conditions. In this study, mtDNA content in 302 breast tumor/surrounding normal tissue pairs were evaluated and correlated with the clinico-pathological characteristics of tumors. Overall, mtDNA content in tumor tissues is significantly lower than that in the surrounding normal tissues, P < 0.00001. MtDNA content in tumor tissues decreased with increasing tumor size. However, when the tumor is very large (>50 cm(3)), mtDNA content started to increase. Similarly, mtDNA content decreased from grades 0 and I to grade II tumors, but increased from grade II to grade III tumors. Tumors with somatic mtDNA alterations in coding region have significantly higher mtDNA content than tumors without somatic mtDNA alterations (P < 0.001). Tumors with somatic mtDNA alterations in the D-Loop region have significantly lower mtDNA content (P < 0.001). Patients with both low and high mtDNA content in tumor tissue have significantly higher hazard of death than patients with median levels of mtDNA content. mtDNA content in tumor tissues change with tumor size, grade, and ER/PR status; significant deviation from the median level of mtDNA content is associated with poor survival.

Significance of somatic mutations and content alteration of mitochondrial DNA in esophageal cancer.

BACKGROUND: The roles of mitochondria in energy metabolism, the generation of ROS, aging, and the initiation of apoptosis have implicated their importance in tumorigenesis. In this study we aim to establish the mutation spectrum and to understand the role of somatic mtDNA mutations in esophageal cancer. METHODS: The entire mitochondrial genome was screened for somatic mutations in 20 pairs (18 esophageal squamous cell carcinomas, one adenosquamous carcinoma and one adenocarcinoma) of tumor/surrounding normal tissue of esophageal cancers, using temporal temperature gradient gel electrophoresis (TTGE), followed by direct DNA sequencing to identify the mutations. RESULTS: Fourteen somatic mtDNA mutations were identified in 55% (11/20) of tumors analyzed, including 2 novel missense mutations and a frameshift mutation in ND4L, ATP6 subunit, and ND4 genes respectively. Nine mutations (64%) were in the D-loop region. Numerous germline variations were found, at least 10 of them were novel and five were missense mutations, some of them occurred in evolutionarily conserved domains. Using real-time quantitative PCR analysis, the mtDNA content was found to increase in some tumors and decrease in others. Analysis of molecular and other clinicopathological findings does not reveal significant correlation between somatic mtDNA mutations and mtDNA content, or between mtDNA content and metastatic status. CONCLUSION: Our results demonstrate that somatic mtDNA mutations in esophageal cancers are frequent. Some missense and frameshift mutations may play an important role in the tumorigenesis of esophageal carcinoma. More extensive biochemical and molecular studies will be necessary to determine the pathological significance of these somatic mutations.

[Heteroplasmy: a common phenomenon of mitochondrial genome mutations in human tumor tissues].

To explore the status of heteroplasmy and homoplasmy of Mitochondrial DNA somatic mutations in different tumors. DNA from 149 tumors and corresponding normal tissues were extracted and entire mitochondrial genome was amplified using 32 pairs of overlapping primers. The somatic mutations were screened by temporal temperature gradient gel electrophoresis and their heteroplasmic statute were identified by sequencing. The results showed that the incidence rate of heteroplasmy of mitochondrial DNA somatic mutations varies in different tumors. There is a high rate of heteroplasmic mutation in oral cancer (65%) and esophageal cancer (64%), followed by breast cancer (45%). The frequency of four transfer types is Hm (homoplasmy)-->Hm (heteroplasmy) > Hm-->Ht > Ht-->Hm > Ht-->Ht. The main transfer forms of transition and transversion mutations are Hm-->Hm and Hm-->Ht respectively. Heteroplasmy is a common phenomenon in mitochondrial DNA somatic mutations of human tumors.

Detection of mitochondrial DNA mutations using temporal temperature gradient gel electrophoresis.

Mitochondrial disorders are a group of clinically and genetically heterogeneous diseases. Common recurrent mitochondrial DNA (mtDNA) point mutations account for the molecular defects of a small proportion of patients. In order to identify mtDNA mutations, comprehensive mutational analysis of the entire mitochondrial genome is necessary. We developed the temporal temperature gradient gel electrophoresis (TTGE) method to screen for mutations in mtDNA. The entire mitochondrial genome was amplified using 32 pairs of overlapping primers followed by TTGE analysis of the DNA fragments. TTGE method was first validated on 200 DNA fragments containing known mutations or polymorphisms. On TTGE, homoplasmic nucleotide substitutions show a single band shift and heteroplasmic mutations show multiple banding patterns. The known mutations or polymorphisms were correctly identified. TTGE was then used to screen for unknown mutations in the mitochondrial genome. DNA banding patterns, deviated from wild-type, suggestive of either homoplasmic or heteroplasmic mutations, were followed by direct DNA sequencing to identify the mutations. Numerous mutations and polymorphisms were detected. The results demonstrated that TTGE detects and distinguishes heteroplasmic mutations from homoplasmic polymorphisms. It also detects heteroplasmic changes in the background of a homoplasmic polymorphism. Overall, TTGE was proven to be a simple, rapid, sensitive, and effective mutation detection method.

Somatic mitochondrial DNA mutations in neurofibromatosis type 1-associated tumors.

Neurofibromatosis type 1 is an autosomal dominantly inherited disease predisposing to a multitude of tumors, most characteristically benign plexiform neurofibromas and diffuse cutaneous neurofibromas. We investigated the presence and distribution of somatic mitochondrial DNA (mtDNA) mutations in neurofibromas and in nontumor tissue of neurofibromatosis type 1 patients. MtDNA alterations in the entire mitochondrial genome were analyzed by temporal temperature gradient gel electrophoresis followed by DNA sequencing. Somatic mtDNA mutations in tumors were found in 7 of 19 individuals with cutaneous neurofibromas and in 9 of 18 patients with plexiform neurofibromas. A total of 34 somatic mtDNA mutations were found. All mutations were located in the displacement loop region of the mitochondrial genome. Several plexiform neurofibromas from individual patients had multiple homoplasmic mtDNA mutations. In cutaneous neurofibromas, the same mtDNA mutations were always present in tumors from different locations of the same individual. An increase in the proportion of the mutant mtDNA was always found in the neurofibromas when compared with nontumor tissues. The somatic mtDNA mutations were present in the Schwann cells of the analyzed multiple cutaneous neurofibromas of the same individual. The observed dominance of a single mtDNA mutation in multiple cutaneous neurofibromas of individual patients indicates a common tumor cell ancestry and suggests a replicative advantage rather than random segregation for cells carrying these mutated mitochondria.

Enhanced detection of deleterious mutations by TTGE analysis of mother and child's DNA side by side.

Mitochondrial DNA (mtDNA) disorders represent a group of heterogeneous diseases that are caused by mutations in mtDNA. We examined 45 pairs of mother and the affected child, by screening the entire mitochondrial genome with temporal temperature gradient gel electrophoresis (TTGE), using 32 pairs of overlapping primers. TTGE is an effective method of mutation detection. It detects and distinguishes heteroplasmic mutations from homoplasmic mutations. By running the mother and child's DNA samples side by side and sequencing only the DNA fragments showing different TTGE patterns, excessive sequencing can be avoided, particularly because most sequence variations represent benign polymorphisms. Mutations identified by sequencing were further confirmed by PCR/ASO (allele-specific oligonucleotide) dot blot analysis or PCR/RFLP (restriction fragment length polymorphism). A total of seven differences in sequence between mother and child pairs were identified: A189G, T5580C, G5821A, C5840T, A8326G, G12207A, and G15995A. All but two mutations were novel. The most significant are the A8326G, G12207A, and G15595A mutations. The A8326G is located at the anticodon region of tRNA(Lys), right next to the first nucleotide of the triplet codon, and it is highly conserved throughout evolution. The G12207A mutation is located at the first base of tRNA(ser) (AGY). The G15995A mutation occurs at a stem region that results in the disruption of the first base pair at the anticodon loop of tRNA(Pro) and is highly conserved throughout evolution from sea urchins to mammals. Running TTGE side by side with DNAs from mother and the affected child is a novel method to detect deleterious mutations.

Somatic mitochondrial DNA mutations in oral cancer of betel quid chewers.

Somatic mitochondrial DNA alteration is a general phenomenon that occurs in cancerous cells. Although numerous mtDNA mutations have been identified in various tumors, the pathogenic significance of these mutations remains unclear. In order to better understand the role of mtDNA mutations in the neoplastic process of oral cancer, the occurrence of mtDNA mutations in oral squamous cell carcinomas was screened by temporal temperature gradient gel electrophoresis (TTGE). The entire mitochondrial genome was amplified with 32 pairs of overlapping primers. The DNA fragments showing different banding patterns between normal and tumor mtDNA were sequenced for the identification of the mutations. Fourteen of 18 (77.8%) tumors had somatic mtDNA mutations with a total of 26 mutations. Among them, 6 were in mRNA coding region. Three were missense mutations (C14F, H186R, T173P) in NADH dehydrogenase subunit 2 (ND2). One frameshift mutation, 9485delC, was in cytochrome c oxidase subunit III. Eight (44%) tumors had insertion or deletion mutations in the np303-309 poly C region of the D-loop. Our results demonstrate that somatic mtDNA mutations occur in oral cancer. The missense and frameshift mutations in the evolutionary conserved regions of the mitochondrial genome may have functional significance in the pathogenesis of oral cancer.

[Evaluation of inheritable character in essential hypertension through reconstruction of neighbor-joining tree].

To explore the inheritable character in essential hypertension and to evaluate the role of mitochondrial DNA (mtDNA) variations of the D-loop region in the pathogenesis of hypertension, the entire genome of the D-loop region from the hypertensive and the normotensive (20 cases, each) was amplified using 3 pairs of overlapping primers and followed by sequencing. We reconstructed the Neighbor-Joining tree and analyzed the mtDNA variations in the D-loop region. The results exhibited that one clustering branch harbored some hypertensive, who had significantly higher frequency and density of mtDNA variations (both P<0.01), especially the polymorphisms of np152T->C, np182C->T, np189A->G, np247G->A, np16187C->T, np16189T->C, np16264C->T, np16270C->T and np16311T->C. This study suggested that there was an aggregative phenomenon in some hypertensive. The genotypes of np152C, np182T, np247A, np16187T, np16189C, np16264T, np16270T and np16311C may be potential genetic markers for susceptibility to hypertension.

Novel heteroplasmic frameshift and missense somatic mitochondrial DNA mutations in oral cancer of betel quid chewers.

Mitochondrial DNA (mtDNA) has been proposed to be involved in carcinogenesis because of its high susceptibility to oxidative DNA damage and limited repair mechanisms. For investigation of the potential role of somatic mtDNA mutations in the tumorigenesis of oral cancer, we screened the occurrence of mtDNA mutations by the temporal temperature gradient gel electrophoresis method. We amplified the entire mitochondrial genome by use of 32 pairs of overlapping primers, and to identify the mutations, we sequenced DNA fragments showing different banding patterns between normal and tumor mtDNA. Fourteen of eighteen (77.8%) oral carcinomas displayed somatic mtDNA mutations, with a total of 26 mutations. Among them, six were in the mRNA coding region. Three were missense mutations (C14F, H186R, T173P) in NADH dehydrogenase subunit 2, and one was a frameshift mutation, 9485delC, in cytochrome c oxidase subunit III. Eight (44%) tumors had insertion or deletion mutations in the nucleotide position 303-309 poly C region of the D-loop. Multiple large deletions were also observed. Our results demonstrate that somatic mtDNA mutations occur in oral cancer. Some missense and frameshift mutations may play an important role in the tumorigenesis of this carcinoma. More extensive biochemical and molecular studies will be necessary for determining the pathologic effect of these somatic mutations.

Comprehensive scanning of the entire mitochondrial genome for mutations.

BACKGROUND: Definitive molecular diagnosis of mitochondrial disorders has been greatly hindered by the tremendous clinical and genetic heterogeneity, the heteroplasmic condition of pathogenic mutations, and the presence of numerous homoplasmic mitochondrial DNA (mtDNA) variations with unknown significance. We used temporal temperature gradient gel electrophoresis (TTGE) to detect heteroplasmic mutations from homoplasmic variations in the whole mitochondrial genome. METHODS: We screened 179 unrelated patients by TTGE with use of 32 overlapping primer pairs. Mutations were identified by direct sequencing of the PCR products and confirmed by PCR with allele-specific oligonucleotide or restriction fragment length polymorphism analysis. RESULTS: We detected 71 heteroplasmic and 647 homoplasmic banding patterns. Sequencing of the heteroplasmic fragments identified 68 distinct novel mutations and 132 reported sequence variations and mutations; most of them occurred only once. The deleterious nature of some of the novel mutations was established by analyzing the asymptomatic family members and the biochemical and molecular characteristics of the mutation. When the number of mutations was normalized to the size of the region, the occurrence of mutations was 2.4 times more frequent in the tRNA genes than in the mRNA (protein coding) regions. CONCLUSIONS: Screening by TTGE detects low proportions of mutant mtDNA and distinguishes heteroplasmic from homoplasmic variations. Results from comprehensive molecular analysis should be followed up with clinical correlation to establish a guideline for complete mutational analysis of the entire mitochondrial genome and to facilitate the diagnosis of mitochondrial disorders.

Analysis of the mitochondrial DNA genome in the peripheral blood leukocytes of HIV-infected patients with or without lipoatrophy.

OBJECTIVE: To investigate the molecular mechanisms of nucleoside analogue reverse transcriptase inhibitor (NRTI)-associated mitochondrial dysfunction. METHODS: Peripheral blood samples were collected from 10 healthy individuals, 10 HIV-infected, NRTI-treated patients with lipoatrophy, and four HIV-infected patients naive to all antiretrovirals. DNA was isolated from the leukocytes and the mitochondrial genome analyzed for DNA depletion, deletions and point mutations. RESULTS: We were not able to detect mitochodrial DNA (mtDNA) depletion, deletions, or DNA rearrangements in any of the specimens, including one from a patient with fulminant lactic acidosis. A complete analysis of the entire mitochondrial genome by temporal temperature gradient gel electrophoresis revealed several nucleotide substitutions in blood mtDNA of several HIV infected patients. CONCLUSION: We found no evidence for NRTI-associated mtDNA depletion or gross mtDNA mutations in leukocytes of HIV-infected patients, regardless of their treatment history. Thus, either NRTI-induced mutations in mtDNA are tissue-specific or alternatively, pre-existent mtDNA variations in HIV disease predispose to the development of clinically apparent mitochondrial dysfunction during NRTI therapy. The significance of mtDNA variations in the development of mitochondrial-related clinical conditions in HIV patients with or without NRTI therapy is to be further investigated.

Comprehensive scanning of somatic mitochondrial DNA mutations in breast cancer.

To investigate the role of mitochondrial DNA (mtDNA) in tumorigenesis, a temporal temperature gradient gel electrophoresis method was used to analyze the somatic mtDNA mutations in breast cancer. The entire mitochondrial genomes in 19 tumor samples and paired normal tissues from the same patients were amplified using 32 pairs of overlapping primers. DNA fragments showing different banding patterns between normal and tumor mtDNA were sequenced to identify the mutations. Fourteen of the 19 tumors (74%) displayed at least one somatic mtDNA mutation. Twenty-seven somatic mutations were found, and 22 of them occurred in the D loop region. This study represents the most comprehensive mtDNA mutational analysis in breast cancer.