Deleterious mitochondrial DNA mutations accumulate in aging human tissues.

This paper reviews the current state of knowledge of the contribution of mitochondrial DNA (mtDNA) mutations to the phenotype of aging. Its major focus is on the discovery of deletions of mtDNA which previously were thought to occur only in individuals with neuromuscular disease. One particular deletion (mtDNA4977) accumulates with age primarily in non-dividing cells such as muscle and brain of normal individuals. The level of the deletion rises with age by more than 1000 fold in heart and brain and to a lesser extent in other tissues. In the brain, different regions have substantially different levels of the deletion. High levels of accumulation of the deletion in tissues are correlated with high oxygen consumption. We speculate that oxidative damage to mtDNA may be 'catastrophic'; mutations affecting mitochondrially encoded polypeptides involved in electron transport could increase free radical generation leading to more mtDNA damage.     

Differential accumulations of 4,977 bp deletion in mitochondrial DNA of various tissues in human ageing

Several types of deletions in mitochondrial DNA (mtDNA) have been recetly identified in various tissues of old humans. In order to determine whether there are differences in the incidence and proportion of deleted mtDNAs in different tissues during human ageing, we examined tha 4,977 bp deletion in mtDNA of various tissues from subjects of different ages. Total DNA was extracted from each of the biopsied tissues and was serially diluted by two-fold with distilled water. A 533 bp DNA fragment was amplified by PCR from total mtDNA using a pair of primers L3304-3323 and H3817-3836, and another 524 bp PCR product was amplified from 4,977 bp deleted mtDNA by identical conditions using another pair of primers L8150-8166 and H13631-13650. The maximum dilution fold of each sample that still allowed the ethidium bromide-stained PCR product (533 bp or 524 bp) in the agarose gel to be visible under UV light illumination was taken as the relative abundance of the mtDNA (wild-type or mutant) in the original sample. By this method, we were able to determine the proportion of deleted mtDNA in human tissues. We found that the 4,977 bp deletion started to appear in the second and third decades of life in human muscle and liver tissues. But the deletion was not detectable in the testis until the age of 60 years. Moreover, the proportion of deleted mtDNA varied greatly in different tissues. Among the tissues examined, muscle was found to harbor higher proportin of deleted mtDNA than the other tissues. The average proportion of the 4,977 bp depleted mtDNA of the muscle from subjects over 70 years old was approximately 0.06%, and that of the liver and the testis was 0.0076% and 0.05%, respectively. These findings suggest that the frequency and proportion of the deleted mtDNA in human tissues increase with age and that the mtDNA deletions occur more frequently and abundantly in high energy-demanding tissues during the ageing process of the human.     

Nucleotide sequence identity of mitochondrial DNA from different human tissues

Recombinant DNA techniques have been used to search for mitochondrial (mt) nucleotide (nt) sequence differences between human tissues within an individual. mtDNA isolated from brain, heart, liver, kidney, and skeletal muscle of two different individuals was cleaved with SacI and XbaI, and then cloned in bacteriophage M13. Partial nt sequence determination of 121 independently isolated recombinant M13 clones containing either the cytochrome oxidase subunit III gene or the D-loop region of human mtDNA revealed base substitution differences between individuals, and between each individual and the published human mtDNA sequence. A majority of these base substitutions were transitions. No systematic nt sequence differences were identified between tissues within an individual, however. These results suggest that mtDNA sequence alterations do not accompany organogenesis, and that somatic mutations do not accumulate in the mtDNA of different human tissues to a level of greater than one nt substitution per molecule.     

Senescing human cells and ageing mice accumulate DNA lesions with unrepairable double-strand breaks

Humans and animals undergo ageing, and although their primary cells undergo cellular senescence in culture, the relationship between these two processes is unclear. Here we show that gamma-H2AX foci (gamma-foci), which reveal DNA double-strand breaks (DSBs), accumulate in senescing human cell cultures and in ageing mice. They colocalize with DSB repair factors, but not significantly with telomeres. These cryptogenic gamma-foci remain after repair of radiation-induced gamma-foci, suggesting that they may represent DNA lesions with unrepairable DSBs. Thus, we conclude that accumulation of unrepairable DSBs may have a causal role in mammalian ageing.     

Mutations in DNA polymerase gamma cause error prone DNA synthesis in human mitochondrial disorders

This paper summarizes recent advances in understanding the links between the cell's ability to maintain integrity of its mitochondrial genome and mitochondrial genetic diseases. Human mitochondrial DNA is replicated by the two-subunit DNA polymerase gamma (polgamma). We investigated the fidelity of DNA replication by polgamma with and without exonucleolytic proofreading and its p55 accessory subunit. Polgamma has high base substitution fidelity due to efficient base selection and exonucleolytic proofreading, but low frameshift fidelity when copying homopolymeric sequences longer than four nucleotides. Progressive external ophthalmoplegia (PEO) is a rare disease characterized by the accumulation of large deletions in mitochondrial DNA. Recently, several mutations in the polymerase and exonuclease domains of the human polgamma have been shown to be associated with PEO. We are analyzing the effect of these mutations on the human polgamma enzyme. In particular, three autosomal dominant mutations alter amino acids located within polymerase motif B of polgamma. These residues are highly conserved among family A DNA polymerases, which include T7 DNA polymerase and E.coli pol I. These PEO mutations have been generated in polgamma to analyze their effects on overall polymerase function as well as the effects on the fidelity of DNA synthesis. One mutation in particular, Y955C, was found in several families throughout Europe, including one Belgian family and five unrelated Italian families. The Y955C mutant polgamma retains a wild-type catalytic rate but suffers a 45-fold decrease in apparent binding affinity for the incoming dNTP. The Y955C derivative is also much less accurate than is wild-type polgamma, with error rates for certain mismatches elevated by 10- to 100-fold. The error prone DNA synthesis observed for the Y955C polgamma is consistent with the accumulation of mtDNA mutations in patients with PEO. The effects of other polgamma mutations associated with PEO are discussed.     

高血压相关的线粒体DNA突变

线粒体DNA(mtDNA)突变是高血压发病的分子机制之一。已经报道的与原发性高血压相关的mtDNA突变包括:tRNAMet A4435G,tRNAMet/tRNAGln A4401G,tRNAIle A4263G,T4291C和A4295G突变。这些高血压相关的mtDNA突变改变了相应的线粒体tRNA的结构,导致线粒体tRNA的代谢障碍。而线粒体tRNAs的代谢缺陷则影响蛋白质合成,造成氧化磷酸化缺陷,降低ATP的合成,增加活性氧的产生。因此,线粒体的功能缺陷可能在高血压的发生发展中起一定的作用。mtDNA突变发病的组织特异性则可能与线粒体tRNAs的代谢以及核修饰基因相关。目前发现的这些高血压相关的mtDNA突变则应该作为今后高血压诊断的遗传风险因子。高血压相关的线粒体功能缺陷的深入研究也将进一步诠释母系遗传高血压的分子致病机制,为高血压的预防、控制和治疗提供依据。文章对高血压相关的mtDNA突变进行了综述。     

Hamster uterine tissues accumulate corticosteroid-binding globulin during decidualization

Although corticosteroid-binding globulin (CBG) is known to be a serum steroid-binding protein, its function outside of the vascular space is not well understood. To prove an extravascular role for CBG, it must first be established that CBG occurs in steroid target tissues. We sought information on the occurrence of CBG in the cytosol, nuclear, and membrane fractions of 6 tissues during decidualization in the hamster. Our objectives were to determine if CBG is distributed in a tissue-specific manner, and to investigate the relationship between serum CBG and tissue CBG. Hamsters were given progesterone pellets s.c. on cycle Day 1 and decidualization was induced on Day 4. A 3H-cortisol-binding assay, which distinguished between CBG and glucocorticoid receptor, was used to determine CGB levels in the serum and in the cytosol, nuclear, and membrane fractions of deciduoma, myometrium, liver, kidney, muscle, and small intestine. Cytosol CBG accounted for greater than 97% of the total CBG detected in all tissues except liver, where nuclei contained 11% of the measurable CBG. For all cell fractions, CBG levels showed consistent tissue-specific differences. Cytosol CBG was highest in deciduoma and myometrium, 2-fold less in liver and kidney, and 5-fold less in muscle and small intestine. Nuclear CBG concentration was greatest in liver and approximately 10-fold less in other tissues, except for small intestine, where nuclear CBG was undetectable. Membrane CBG was highest in liver, 5-fold less in deciduoma, 10-fold less in myometrium, and about 20-fold less in other tissues. Serum CBG increased 7-fold from Day 4 to Day 9 in decidualized hamsters, but not in nondecidualized sham-operated hamsters. In all tissues, serum CBG was correlated with cytosol CBG. The high levels of CBG in uterine tissues were not the result of serum contamination because whole-body perfusion with buffered saline failed to remove the majority of cytosol CBG under conditions where over 70% of 51Cr-labeled red blood cells were removed. The identity of uterine cytosol CBG with serum CBG was established by ion-exchange chromatography (O-(diethylaminoethyl)-cellulose) and by immunoprecipitation with an antibody generated against serum CBG. These data demonstrate that uterine tissues accumulate substantial amounts of CBG during decidualization, thus raising the possibility of a functional role of CBG in uterine tissues during early pregnancy.     

Effect of fixation to the degradation of nuclear and mitochondrial DNA in different tissues.

Samples of different tissues were preserved in seven fixatives for periods of time extending from 1 to 336 days, to determine which fixatives reduce the time-dependent degradation of DNA and preserve the histological structure. To achieve these results, three PCR systems were used: FGA and TC11 (both for nuclear DNA) and HV1 for mitochondrial DNA (mt-DNA). For long-term storage in combination with amplification of nuclear and mt-DNA, consistent results were obtained in Carnoy's solution and glutaraldehyde. Variable results were observed for buffered formalin; an mt-DNA product could be detected even after 3 months of fixation. In regard to comparison of the different tissues, the quantities recovered from skeletal muscles and kidneys were higher than from other tissues.     

The evolution of human periodontal tissues with ageing.

In this research, the structural modifications with ageing of clinically healthy periodontal tissues were analyzed by means of polarization microscopy and morphometrical methods for light microscopy. The new findings may be summarized as follows. The periodontal ligament was found to be widened in the cervical and apical regions. The thickening of cementum with ageing was shown to be accompanied by a modification in the shape of Sharpey's fibres, which in the elderlies were wavy instead of straight as in the control. Lamellar bone, forming an osteone, was found to substitute in part for cementum in one tooth. These results are interpreted as indicating that: (1) late active eruption occurs in man, causing the observed modification in the thickness of periodontal ligament and cementum in the apical region and in the direction of Sharpey's fibres within cementum; (2) cementum may undergo renewal during lifetime and in this case bone may be deposited in contact with dentin.     

Authenticating ancient human mitochondrial DNA.

The use of ancient DNA techniques in human studies has been hampered by problems of contamination with modern human DNA. The main problem has been that the object of study belongs to the same species as the observer, and the complete elimination of the contamination risk is seemingly unlikely. Contamination has even been detected in the most specialized laboratories in this field. In these kinds of studies it is therefore very important to detect contamination and to distinguish contaminants from authentic results. Here, we report the use of a strategy to authenticate the identity of ancient mitochondrial DNA (mtDNA), based on the previously established relationship between D-loop sequence substitutions and haplogroup-specific restriction site changes. Forty-four individuals from a 16th-century necropolis were analyzed, from which 28 control region sequences were obtained. These sequences were preclassified into haplogroups, according to the observed motifs. Subsequently, the DNA extracts from which the sequences were obtained, along with independent extracts of subsets of the same individuals, were subjected to restriction fragment length polymorphism (RFLP) analysis to compare and corroborate the results. Using this approach, 24 sequences were authenticated, while two were discarded because of result mismatches. The final distribution of the haplogroups in the sample, and the differences in the sequences, are two additional criteria of authentication.     

Thymidine and deoxyuridine accumulate in tissues of patients with mitochondrial neurogastrointestinal encephalomyopathy (MNGIE)

Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive disease due to ECGF1 gene mutations causing thymidine phosphorylase (TP) deficiency. Analysis of post-mortem samples of five MNGIE patients and two controls, revealed TP activity in all control tissues, but not in MNGIE samples. Converse to TP activity, thymidine and deoxyuridine were absent in control samples, but present in all tissues of MNGIE patients. Concentrations of both nucleosides in the tissues were generally higher than those observed in plasma of MNGIE patients. Our observations indicate that in the absence of TP activity, tissues accumulate nucleosides, which are excreted into plasma.     

Structural evidence for three different types of glutathione transferase in human tissues

Cytosolic glutathione transferase was purified from human placenta and human liver. Three different forms of the enzyme were obtained, the acidic (pi), the near-neutral (mu), and the basic (alpha-epsilon) forms; two had free alpha-amino groups (pi, mu) and one had a blocked alpha-amino group (alpha-epsilon). N-terminal sequence analyses and total compositions gave clearly different results for each form, although transferases pi and mu showed 35% sequence homology in the N-terminal regions, with a 1-residue shift in starting position. Consequently, the proteins are concluded to be products of three discrete but related genes.     

Passion fruit flowers: Kunitz trypsin inhibitors and cystatin differentially accumulate in developing buds and floral tissues

In order to better understand the physiological functions of protease inhibitors (PIs) the PI activity in buds and flower organs of passion fruit (Passiflora edulis Sims) was investigated. Trypsin and papain inhibitory activities were analyzed in soluble protein extracts from buds at different developmental stages and floral tissues in anthesis. These analyses identified high levels of inhibitory activity against both types of enzymes at all bud stages. Intriguingly, the inhibitory activity against both proteases differed remarkably in some floral tissues. While all organs tested were very effective against trypsin, only sepal and petal tissues exhibited strong inhibitory activity against papain. The sexual reproductive tissues (ovary, stigma-style and stamen) showed either significantly lower activity against papain or practically none. Gelatin–SDS–PAGE assay established that various trypsin inhibitors (TIs) homogenously accumulated in developing buds, although some were differentially present in floral organs. The N-terminal sequence analysis of purified inhibitors from stamen demonstrated they had homology to the Kunitz family of serine PIs. Western-blot analysis established presence of a ∼60 kDa cystatin, whose levels progressively increased during bud development. A positive correlation between this protein and strong papain inhibitory activity was observed in buds and floral tissues, except for the stigma-style. Differences in temporal and spatial accumulation of both types of PIs in passion fruit flowers are thus discussed in light of their potential roles in defense and development.