Different mechanisms inferred from sequences of human mitochondrial DNA deletions in ocular myopathies.

We have sequenced the deletion borders of the muscle mitochondrial DNA from 24 patients with heteroplasmic deletions. The length of these deletions varies from 2.310 bp to 8.476 bp and spans from position 5.786 to 15.925 of the human mitochondrial genome preserving the heavy chain and light chain origins of replication. 12 cases are common deletions identical to the mutation already described by other workers and characterized by 13 bp repeats at the deletion boundaries, one of these repeats being retained during the deletion process. The other cases (10 out of 12) have shown deletions which have not been previously described. All these deletions are located in the H strand DNA region which is potentially single stranded during mitochondrial DNA replication. In two cases, the retained Adenosine from repeat closed to the heavy strand origin of replication would indicate slippage mispairing. Furthermore in one patient two mt DNA molecules have been cloned and their sequences showed the difference of four nucleotides in the breakpoint of the deletion, possibly dued to slippage mispairing. Taken together our results suggest that deletions occur either by slippage mispairing or by internal recombination at the direct repeat level. They also suggest that different mechanisms account for the deletions since similarly located deletions may display different motives at the boundaries including the absence of any direct repeat.     

Deleted mitochondrial DNA in the skeletal muscle of aged individuals.

Human mitochondrial DNA deletions occur mainly in the major region between the origins of replication of the heavy and light strands both in mitochondrial myopathy and in the ageing process. To determine whether deletions in the minor region also contribute to the ageing process, we analyzed a 3,610-basepair deletion (nucleotide position 1,837-5,447, from the 16S rRNA gene to the ND2 gene) in the skeletal muscle from individuals of various ages. The direct repeated sequence at each boundary of the deletion was identified as 5'-CCCC-3'. This minor-region deletion was detected in one of five individuals of the sixth decade, two of five in the seventh decade, and all of five in the eighth decade, but not in individuals below age 60. These results indicate that age-related accumulation of mtDNA deletions occurs not only in the major region but also in the minor region.     

Mapping of heteroplasmic mitochondrial DNA deletions in Kearns-Sayre syndrome.

Kearns-Sayre syndrome (KSS) is a progressive neuromuscular disease characterised by ophtalmoplegia, cardiac bloc branch, pigmentary retinopathy associated with abnormal mitochondrial function. We have studied the mitochondrial DNA organization of patients presenting KSS and have found large deletions ranging from 3 to 8.5 kilobase pairs. DNA molecules containing deletion are accompanied by the presence of the normal sized mtDNA molecule forming heteroplasmic genomes. The deletions always map in the region which is potentially single stranded during mitochondrial DNA replication. The deletions differ in length and position between individuals but are similar within the different tissues of an individual suggesting that they arise during or before embryogenesis.     

A region of the polyoma virus genome between the replication origin and late protein coding sequences is required in cis for both early gene expression and viral DNA replication.

Deletion mutants within the Py DNA region between the replication origin and the beginning of late protein coding sequences have been constructed and analysed for viability, early gene expression and viral DNA replication. Assay of replicative competence was facilitated by the use of Py transformed mouse cells (COP lines) which express functional large T-protein but contain no free viral DNA. Viable mutants defined three new nonessential regions of the genome. Certain deletions spanning the PvuII site at nt 5130 (67.4 mu) were unable to express early genes and had a cis-acting defect in DNA replication. Other mutants had intermediate phenotypes. Relevance of these results to eucaryotic "enhancer" elements is discussed.     

Deletions of muscle mitochondrial DNA in mitochondrial myopathies: sequence analysis and possible mechanisms.

Forty per cent of patients with mitochondrial myopathies, a diverse group of multisystem diseases predominantly affecting skeletal muscle and the brain, have large deletions of a proportion of muscle mitochondrial DNA (mt DNA). These appeared to be identical in 13 of 28 cases, contained within the region 8286-13595 bp. Analysis of the deletion junction in two cases showed a 13 nucleotide sequence which occurred in the normal genome as a direct repeat flanking the region deleted in the mutant mt DNAs. Mt DNA deletions may arise from recombination or slippage between short sequence repeats during replication.     

Analysis of repeat-mediated deletions in the mitochondrial genome of Saccharomyces cerevisiae

Mitochondrial DNA deletions and point mutations accumulate in an age-dependent manner in mammals. The mitochondrial genome in aging humans often displays a 4977-bp deletion flanked by short direct repeats. Additionally, direct repeats flank two-thirds of the reported mitochondrial DNA deletions. The mechanism by which these deletions arise is unknown, but direct-repeat-mediated deletions involving polymerase slippage, homologous recombination, and nonhomologous end joining have been proposed. We have developed a genetic reporter to measure the rate at which direct-repeat-mediated deletions arise in the mitochondrial genome of Saccharomyces cerevisiae. Here we analyze the effect of repeat size and heterology between repeats on the rate of deletions. We find that the dependence on homology for repeat-mediated deletions is linear down to 33 bp. Heterology between repeats does not affect the deletion rate substantially. Analysis of recombination products suggests that the deletions are produced by at least two different pathways, one that generates only deletions and one that appears to generate both deletions and reciprocal products of recombination. We discuss how this reporter may be used to identify the proteins in yeast that have an impact on the generation of direct-repeat-mediated deletions.     

Age-associated mitochondrial DNA deletions in mouse skeletal muscle: Comparison of different regions of the mitochondrial genome

The abundance of mitochondrial DNA (mtDNA) deletions has been shown to increase with age in a number of species and may contribute to the aging process. Estimating the total mtDNA deletion load of an individual is essential in evaluating the potential physiological impact. In this study, we compared three 5-kb regions of the mitochondrial genome: one in the major arc, one in the minor arc, and a third containing the light strand origin of replication. Through PCR analysis of mouse skeletal muscle, we have determined that not all regions produce equal numbers of age-associated deletions. There are, on average, twofold more detectable deletions in the major arc region than in the minor arc region. Deletions that result in the loss of the light strand origin of replication are rarely detected. Furthermore, the mechanism of deletion formation seems to be similar in both the major and minor arcs, with direct repeats playing an important, although not essential, role. © 1996 Wiley-Liss, Inc.     

Spectrum of mitochondrial DNA deletions within the common deletion region induced by low levels of UVB irradiation of human keratinocytes in vitro

We show that a single low-dose exposure of human epidermal keratinocytes (NHEK) to an FS20 light source in vitro can induce the formation of mitochondrial DNA deletions in a PCR detection assay. We used primer sets specifically designed to exclude amplification of segments containing the common deletion, but which could detect possibly lower abundance deletions generated within the same region of the mitochondrial genome. We characterized eight novel deletions of which six were generated from cut sites within, or adjacent to, short direct repeats. Two deletions involved cut sites in inverted tetrameric repeats; one of these also involved an insertion.     

Dietary modulation of mitochondrial DNA deletions and copy number after chemotherapy in rats

Mitochondrial DNA (mtDNA) is particularly susceptible to mutation by alkylating agents, and mitochondrial damage may contribute to the efficacy and toxicity of these agents. We found that folate supplementation decreased the frequency of the "common deletion" (4.8kb, bases 8103-12,936) in liver from untreated rats and from animals treated with cyclophosphamide but not 5-fluorouracil (5-FU). The relative abundance of mitochondrial DNA was greater after chemotherapy but there was no effect of diet. Rats fed with a purified diet had fewer mitochondrial deletions than those maintained on a cereal-based diet after chemotherapy. These results indicate that diet can modulate the extent of mitochondrial damage after cancer chemotherapy, and that folic acid supplementation may be protective against mitochondrial DNA deletions.     

Deletion of 60 kilobase pairs of DNA from the terC region of the chromosome of Escherichia coli

Summary The terminus of replication (terC) of the chromosome of Escherichia coli is located between the rac (min 30.0) and manA (min 35.7) loci, presumably close to the trg (min 31.4) locus. We have used a strain containing reverse (min 30.0) and trg-2:: Tn10 (min 31.4) to obtain deletions of the entire 60 kilobase pair region that separates these elements. Strains harboring these deletions possessed fusion fragments that contained DNA homologous to both reverse and trg region DNA. In addition, chromosomal DNA normally present between min 30.0 and min 31.4 was absent in these strains. The strains had no readily apparent mutant phenotype, which demonstrates that this large region of DNA is not essential for normal growth.     

Reactive oxygen and DNA damage in mitochondria.

During the last decade the importance of reactive oxygen species as major contributors to various types of cancer, heart diseases, cataracts, Parkinson's and other degenerative diseases that come with age, and to natural aging has become apparent. Mitochondria are the most important intracellular source of reactive oxygen. Mitochondrial DNA is heavily damaged by reactive oxygen at the bases, as indicated by the high steady-state level of 8-hydroxydeoxyguanosine, the presence of which causes mispairing and point mutations. Mitochondrial DNA is also oxidatively fragmented to a certain extent. Conceivably, such fragmentation relates to deletions found in mitochondrial DNA. Point mutations and deletions have recently been shown to be etiologically linked to several human diseases and natural aging. Future studies should address the causal relationship between mitochondrial dysfunction, production of reactive oxygen species, and aging.     

A topoisomerase II cleavage site is associated with a novel mitochondrial DNA deletion

Mitochondrial myopathies and encephalopathies can be caused by nucleotide substitutions, deletions or duplications of the mitochondrial DNA (mtDNA). In one such disorder, Kearns-Sayre Syndrome (KSS), large-scale hetero-plasmic mtDNA deletions are often found. We describe a 14-year-old boy with clinical features of KSS, plus some additional features. Analysis of the entire mitochondrial genome by the polymerase chain reaction and Southern blotting revealed a 7864-bp mtDNA deletion, heteroplasmic in its tissue distribution. DNA sequencing established that the deletion was between nucleotides 6238 and 14103, and flanked by a 4-bp (TCCT) direct repeat sequence. Deletions between direct repeats have been hypothesised to occur by a slipped-mismatching or illegitimate recombination event, or following the DNA cleavage action of topoisomerase II. Analysis of the gene sequence in the region surrounding the mtDNA deletion breakpoint in this patient revealed the presence of putative vertebrate topoisomerase II sites. We suggest that direct repeat sequences, together with putative topoisomerase II sites, may predispose certain regions of the mitochondrial genome to deletions.     

Multiple origins and rapid evolution of duplicated mitochondrial genes in parthenogenetic geckos (Heteronotia binoei; Squamata, Gekkonidae)

Accumulating evidence for alternative gene orders demonstrates that vertebrate mitochondrial genomes are more evolutionarily dynamic than previously thought. Several lineages of parthenogenetic lizards contain large, tandem duplications that include rRNA, tRNA, and protein-coding genes, as well as the control region. Such duplications are hypothesized as intermediate stages in gene rearrangement, but the early stages of their evolution have not been previously studied. To better understand the evolutionary dynamics of duplicated segments of mitochondrial DNA, we sequenced 10 mitochondrial genomes from recently formed ( approximately 300,000 years ago) hybrid parthenogenetic geckos of the Heteronotia binoei complex and 1 from a sexual form. These genomes included some with an arrangement typical of vertebrates and others with tandem duplications varying in size from 5.7 to 9.4 kb, each with different gene contents and duplication endpoints. These results, together with phylogenetic analyses, indicate independent and frequent origins of the duplications. Small, direct repeats at the duplication endpoints imply slipped-strand error as a mechanism generating the duplications as opposed to a false initiation/termination of DNA replication mechanism that has been invoked to explain duplications in other lizard mitochondrial systems. Despite their recent origin, there is evidence for nonfunctionalization of genes due primarily to deletions, and the observed pattern of gene disruption supports the duplication-deletion model for rearrangement of mtDNA gene order. Conversely, the accumulation of mutations between these recent duplicates provides no evidence for gene conversion, as has been reported in some other systems. These results demonstrate that, despite their long-term stasis in gene content and arrangement in some lineages, vertebrate mitochondrial genomes can be evolutionary dynamic even at short timescales.     

Somatic mtDNA Mutation Spectra in the Aging Human Putamen

The accumulation of heteroplasmic mitochondrial DNA (mtDNA) deletions and single nucleotide variants (SNVs) is a well-accepted facet of the biology of aging, yet comprehensive mutation spectra have not been described. To address this, we have used next generation sequencing of mtDNA-enriched libraries (Mito-Seq) to investigate mtDNA mutation spectra of putamen from young and aged donors. Frequencies of the “common” deletion and other “major arc” deletions were significantly increased in the aged cohort with the fold increase in the frequency of the common deletion exceeding that of major arc deletions. SNVs also increased with age with the highest rate of accumulation in the non-coding control region which contains elements necessary for translation and replication. Examination of predicted amino acid changes revealed a skew towards pathogenic SNVs in the coding region driven by mutation bias. Levels of the pathogenic m.3243A>G tRNA mutation were also found to increase with age. Novel multimeric tandem duplications that resemble murine control region multimers and yeast ρ⁻ mtDNAs, were identified in both young and aged specimens. Clonal ∼50 bp deletions in the control region were found at high frequencies in aged specimens. Our results reveal the complex manner in which the mitochondrial genome alters with age and provides a foundation for studies of other tissues and disease states.     

Genomic gigantism: DNA loss is slow in mountain grasshoppers

Several studies have shown DNA loss to be inversely correlated with genome size in animals. These studies include a comparison between Drosophila and the cricket, Laupala, but there has been no assessment of DNA loss in insects with very large genomes. Podisma pedestris, the brown mountain grasshopper, has a genome over 100 times as large as that of Drosophila and 10 times as large as that of Laupala. We used 58 paralogous nuclear pseudogenes of mitochondrial origin to study the characteristics of insertion, deletion, and point substitution in P. pedestris and Italopodisma. In animals, these pseudogenes are "dead on arrival"; they are abundant in many different eukaryotes, and their mitochondrial origin simplifies the identification of point substitutions accumulated in nuclear pseudogene lineages. There appears to be a mononucleotide repeat within the 643-bp pseudogene sequence studied that acts as a strong hot spot for insertions or deletions (indels). Because the data for other insect species did not contain such an unusual region, hot spots were excluded from species comparisons. The rate of DNA loss relative to point substitution appears to be considerably and significantly lower in the grasshoppers studied than in Drosophila or Laupala. This suggests that the inverse correlation between genome size and the rate of DNA loss can be extended to comparisons between insects with large or gigantic genomes (i.e., Laupala and Podisma). The low rate of DNA loss implies that in grasshoppers, the accumulation of point mutations is a more potent force for obscuring ancient pseudogenes than their loss through indel accumulation, whereas the reverse is true for Drosophila. The main factor contributing to the difference in the rates of DNA loss estimated for grasshoppers, crickets, and Drosophila appears to be deletion size. Large deletions are relatively rare in Podisma and Italopodisma.     

Molecular Characterization of the Mitochondrial DNA of a New Stopper Mutant Er-3 of Neurospora Crassa

An ethidium bromide-induced stopper mutant of Neurospora crassa is characterized at the molecular level. The mutant has two populations of mitochondrial DNA: a defective predominant mutant molecule and a basal level of the wild-type molecule. The aberrant DNA resulted after a 25-kbp deletion from the wild-type mitochondrial chromosome, which included major genes such as cytb, co1 and oli2. The deletion endpoints are located in the second intron of the ND5 gene, and in a sequence 250 nucleotides upstream of the co2 gene. The recombination has taken place between two nine nucleotide repeats CCCCGCCCC, one of which is close to a PstI palindrome at its 5' end. Thus the mutant ER-3 differs from all the other stopper mutants described previously in the extent and location of the deletions in the mtDNA.