Mitochondrial genotype associated with longevity and its inhibitory effect on mutagenesis.

Mitochondria are not only the major site of ATP production in cells but also an important source of reactive oxygen species (ROS) under certain pathological conditions. Because mitochondrial DNA (mtDNA) in the mitochondrial matrix is exposed to ROS that leak from the respiratory chain, this extranuclear genome is prone to mutations. Therefore, the mitochondrial genome is a rich source of single nucleotide polymorphisms (SNPs) and the functional significance of SNPs in the mitochondrial genome is comparable to that of SNPs in the entire nuclear genome. To demonstrate the contribution of mitochondrial SNPs to the susceptibility to adult-onset diseases, we analyzed the mtDNA from Japanese centenarians and identified a longevity-associated mitochondrial genotype, Mt5178A. Because this genotype was demonstrated to suppress the occurrence of mtDNA mutations in the oocytes, it also would seem to decelerate the accumulation of mtDNA mutations in the somatic cells with increasing age. This genotype is likely to confer resistance to adult-onset diseases by suppressing obesity and atherosclerosis.

Appropriately spaced nuclear localizing signals are necessary for efficient nuclear import of nonnuclear proteins.

To deliver nonnuclear proteins into the nucleus, we have examined the locations and number of nuclear localizing signals by use of simian virus 40 large T-antigen (SV40Ta) and yeast enhanced green fluorescent protein (yEGFP) in Saccharomyces cerevisiae as a model system. When only one SV40Ta was added to either the N- or C-terminus of yEGFP, the fluorescence of yEGFP was detected in both the nucleus and the cytoplasm. When two SV40Ta signals were added, one to the N-terminus and one to the C-terminus of yEGFP (SV40Ta-yEGFP-SV40Ta), the fluorescence of yEGFP was localized in only the nucleus. When the presequence of cytochrome oxidase subunit IV (pCOXIV) was inserted between the SV40Ta and the N-terminus of yEGFP (SV40Ta-pCOXIV-yEGFP-SV40Ta) in this construct, the fluorescence was located in both the nucleus and the cytoplasm, suggesting that the increased distance between the two SV40Ta signals decreased the efficiency of transport into the nucleus. When an additional SV40Ta signal was inserted between pCOXIV and yEGFP (SV40Ta-pCOXIV-SV40Ta-yEGFP), the fluorescence was localized only in the nucleus, indicating that two SV40Ta signals spaced by pCOXIV of 28 amino acid residues forming an alpha-helix are potent in transporting yEGFP into the nucleus. These results indicate that two SV40Ta signals spaced appropriately are essential for the efficient transport of the nonnuclear protein into the nucleus.

Peroxide production and apoptosis in cultured cells carrying mtDNA mutation causing encephalomyopathy.

When cybrids with a point mutation, which locates in the tRNALeu(UUR) gene of mtDNA and causes a mitochondrial encephalomyopathy (MELAS syndrome), were exposed to a high concentration of oxygen (95%), the peroxide production markedly increased by 6 h of oxygen exposure, whereas the peroxide production was similar among the cybrids under a normal concentration of oxygen. The peroxide production by oxygen exposure was enhanced particularly in cybrids with high proportions of the mutant mtDNA and low respiratory capacities. The appearance of apoptotic cells by oxygen exposure was high in cybrids with the impaired respiratory function due to the mutation. An antioxidant NAC successfully suppressed both the peroxide production and apoptosis. These results imply that the peroxide production plays an important role in inducing apoptosis in cells carrying the mtDNA mutation causing encephalomyopathy.

An IDDM patient who complained of chest oppression with ischemic changes on ECG in insulin-induced hypoglycemia.

A 34-year-old female IDDM patient complained of chest oppression in hypoglycemic episodes and electrocardiograms revealed reversible ischemic changes occurring concomitantly with hypoglycemia. The ECG changes improved and the chest oppression disappeared following increasing blood glucose level by glucose intake. Master's double load test and treadmill load test were positive for ischemic changes. Radioisotopic myocardial scintigraphy by thallium and BMIPP did not show any filling defects and coronary angiography revealed no remarked stenosis in the coronary arteries. She had no mitochondrial tRNA(Leu) (A-->G) gene mutation at nucleotide position 3243, but both the patient and her mother had a G-to-A transition within the replication origin of the light strand at nucleotide position 5744 of the mitochondrial gene. As the patient's maternal family had no history of ischemic heart disease, it is not clear whether mitochondrial gene mutation at nucleotide position 5744 reflects the occurrence of cardiac ischemia. Some disorders of microcirculation in capillary vessels in cardiac muscles may occur in such patients.

Accumulation of deletions and point mutations in mitochondrial genome in degenerative diseases.

Accumulation of various mutations in the mitochondrial genome is proposed as an important contributor to aging and degenerative diseases. Extensive fragmentation of mtDNA was detected in association with increased 8-hydroxydeoxyguanosine content in the heart mitochondrial DNA (mtDNA) from a patient with premature aging and mitochondrial cardiomyopathy, who carried a mutation within the mitochondrial tRNA(Asp) gene. This result suggests that damage to mtDNA by hydroxyl radical and accumulation of deleted mtDNA can be accelerated by a specific mitochondrial genotype. Similarly, extensive fragmentation of mtDNA was also detected in cultured cells exposed to a high oxygen concentration atmosphere, implying that mtDNA is vulnerable to reactive oxygen species. To clarify the role of point mutations accumulated in mtDNA, we examined the sequence heterogeneity of mtDNA in the skeletal muscle of a MELAS patient who carried a mutation within the mitochondrial tRNA(leu)(UUR) gene. The analysis revealed that the frequency of mutant clones in the MELAS muscle was significantly higher than those in an age-matched control muscle and a control placenta. Some of these nucleotide substitutions were missense and nonsense mutations, which potentially have deleterious effects on the mitochondrial function. The frequency of nucleotide substitutions in the striatum of three patients with Parkinson's disease was also significantly higher than that in control tissues. We also observed increased protein modification by 4-hydroxy-2-nonenal, a lipid peroxidation by-product, in Parkinson's disease. These results suggests that a vicious cycle contributes to the progression of degenerative process. In this cycle, first a primary mitochondrial mutation(s) induces a mitochondrial respiratory defect, which increases the leakage of reactive oxygen species (ROS) from the respiratory chain. Then the ROS would trigger accumulation of secondary mtDNA mutations in postmitotic cells, leading to further aggravation of mitochondrial respiratory defects and increased production of ROS and lipid peroxides from mitochondria, and thus resulting in degeneration of cellular components.

A common hot spot for somatic and germline mutations in rat mitochondrial DNA: analysis by fluorescence-based SSCP.

To estimate the degree of sequence heterogeneity of mtDNA, we have developed an efficient system for mutant detection using fluorescence-based single strand conformational polymorphism (F-SSCP). The F-SSCP analysis 200 clones from Wistar rat and sequencing of 2 clones from each 40 inbred Wistar rats at the age of 7 weeks detected no sequence differences, suggesting that the mtDNA sequence heterogeneity is low in young rat hearts. One of the 387 clones isolated from a Donryu rat showed a different mobility in the F-SSCP from other clones. Sequencing of the mutant clone revealed double contiguous TT-->CC transitions at nucleotide positions 15443 and 15444, compared with the normal Donryu clone. The nucleotide at 15444 was different between the Wistar and Donryu rats, indicating that this is the site of germline mutation. These results suggest that the somatic and germline mutations can occur at a common hot spot.