Dissecting the mechanisms underlying the accumulation of mitochondrial DNA deletions in human skeletal muscle.

Large-scale mitochondrial DNA (mtDNA) deletions are an important cause of mitochondrial disease, while somatic mtDNA deletions cause focal respiratory chain deficiency associated with ageing and neurodegenerative disorders. As mtDNA deletions only cause cellular pathology at high levels of mtDNA heteroplasmy, an mtDNA deletion must accumulate to levels which can result in biochemical dysfunction-a process known as clonal expansion. A number of hypotheses have been proposed for clonal expansion of mtDNA deletions, including a replicative advantage for deleted mitochondrial genomes inferred by their smaller size--implying that the largest mtDNA deletions would also display a replicative advantage over smaller mtDNA deletions. We proposed that in muscle fibres from patients with mtDNA maintenance disorders, which lead to the accumulation of multiple mtDNA deletions, we would observe the largest mtDNA deletions spreading the furthest longitudinally through individual muscle fibres by means of a greater rate of clonal expansion. We characterized mtDNA deletions in patients with mtDNA maintenance disorders from a range of 'large' and 'small' cytochrome c oxidase (COX)-deficient regions in skeletal muscle fibres. We measured the size of clonally expanded deletions in 62 small and 60 large individual COX-deficient f regions. No significant difference was observed in individual patients or in the total dataset (small fibre regions mean 6.59 kb--large fibre regions mean 6.51 kb). Thus no difference existed in the rate of clonal expansion throughout muscle fibres between mtDNA deletions of different sizes; smaller mitochondrial genomes therefore do not appear to have an inherent replicative advantage in human muscle.

Late-onset respiratory failure due to TK2 mutations causing multiple mtDNA deletions.

Mutations in nuclear genes involved in the maintenance of mitochondrial DNA (mtDNA) are associated with an extensive spectrum of clinical phenotypes, manifesting as either mtDNA depletion syndromes or multiple mtDNA deletion disorders.(1.)

Clonally expanded mitochondrial DNA deletions within the choroid plexus in multiple sclerosis.

Mitochondrial DNA deletions (∆-mtDNA) have been implicated in the pathogenesis of Alzheimer's disease (AD), multiple sclerosis (MS) and Parkinson's disease (PD), as well as ageing. Clonal expansion of ∆-mtDNA is the process by which a mutant mtDNA molecule increases to high levels within a single cell containing both wild-type and mutant mtDNA. Unlike in AD and PD, the diffuse inflammatory process in MS involves the choroid plexus, and mitochondria are exposed to reactive oxygen and nitrogen species over a prolonged period. We determined the extent of respiratory enzyme deficiency and ∆-mtDNA at a single cell level within choroid plexus epithelial cells in MS as well as in AD, PD and controls. The respiratory enzyme-deficient (lacking complex IV and with intact complex II activity) cells were more prevalent within the choroid plexus in AD, MS and PD compared with controls. The main catalytic subunit of complex IV (subunit-I of cytochrome c oxidase) was lacking in significantly more respiratory enzyme-deficient cells in MS compared with AD, PD and controls. The single cell analysis showed a fourfold increase in the percentage of respiratory enzyme-deficient choroid plexus epithelial cells harbouring clonally expanded ∆-mtDNA in MS. Our findings establish clonal expansion of ∆-mtDNA as a feature relatively more prominent within the choroid plexus epithelium in MS than AD, PD or controls. We propose clonal expansion of ∆-mtDNA as a molecular link between inflammation and part of a delayed cellular energy failure in MS.

Relationship between mitochondria and α-synuclein: a study of single substantia nigra neurons.

OBJECTIVE: To explore the relationship between α-synuclein pathology and mitochondrial respiratory chain protein levels within single substantia nigra neurons. DESIGN: We examined α-synuclein and mitochondrial protein expression in substantia nigra neurons of 8 patients with dementia with Lewy bodies, 5 patients with Parkinson disease, and 8 control subjects. Protein expression was determined using immunocytochemistry followed by densometric analysis. PATIENTS: We examined single substantia nigra neurons from 5 patients with idiopathic Parkinson disease (mean age, 81.2 years), 8 patients with dementia with Lewy bodies (mean age, 75 years), and 8 neurologically and pathologically normal control subjects (mean age, 74.5 years). The control cases showed minimal Lewy body pathology and cell loss. Patients with dementia with Lewy bodies and idiopathic Parkinson disease fulfilled the clinical and neuropathologic criteria for these diseases. RESULTS: Our results showed that mitochondrial density is the same in nigral neurons with and without α-synuclein pathology. However, there are significantly higher levels of the respiratory chain subunits in neurons containing α-synuclein pathology. CONCLUSIONS: The finding of increased levels of respiratory chain complex subunits within neurons containing α-synuclein does not support a direct association between mitochondrial respiratory chain dysfunction and the formation of α-synuclein pathology.

Mitochondrial DNA deletions cause the biochemical defect observed in Alzheimer's disease.

Alzheimer's disease (AD) is the most common form of dementia, increasing in prevalence with age. Most patients who develop AD have an unknown cause, but characteristic neuropathological features include the deposition of extracellular amyloid beta and of intraneuronal hyperphosphorylated tau protein. Researchers have previously implicated mitochondrial dysfunction in AD. We previously showed an increase in neurons displaying a mitochondrial biochemical defect-cytochrome-c oxidase (COX) deficiency-in the hippocampus in patients with sporadic AD compared with age-matched controls. COX deficiency is well described as a marker of mitochondrial (mt) DNA dysfunction. This present study analyzed the mtDNA in single neurons from both COX normal and COX-deficient cells. Analysis of the mtDNA revealed that COX deficiency is caused by high levels of mtDNA deletions which accumulate with age. Future research is needed to clarify the role mtDNA deletions have in normal aging and investigate the relationship between mtDNA deletions and the pathogenesis of sporadic AD.

Mitochondrial DNA deletions and neurodegeneration in multiple sclerosis.

OBJECTIVE: Cerebral atrophy is a correlate of clinical progression in multiple sclerosis (MS). Mitochondria are now established to play a part in the pathogenesis of MS. Uniquely, mitochondria harbor their own mitochondrial DNA (mtDNA), essential for maintaining a healthy central nervous system. We explored mitochondrial respiratory chain activity and mtDNA deletions in single neurons from secondary progressive MS (SPMS) cases. METHODS: Ninety-eight snap-frozen brain blocks from 13 SPMS cases together with complex IV/complex II histochemistry, immunohistochemistry, laser dissection microscopy, long-range and real-time PCR and sequencing were used to identify and analyze respiratory-deficient neurons devoid of complex IV and with complex II activity. RESULTS: The density of respiratory-deficient neurons in SPMS was strikingly in excess of aged controls. The majority of respiratory-deficient neurons were located in layer VI and immediate subcortical white matter (WM) irrespective of lesions. Multiple deletions of mtDNA were apparent throughout the gray matter (GM) in MS. The respiratory-deficient neurons harbored high levels of clonally expanded mtDNA deletions at a single-cell level. Furthermore, there were neurons lacking mtDNA-encoded catalytic subunits of complex IV. mtDNA deletions sufficiently explained the biochemical defect in the majority of respiratory-deficient neurons. INTERPRETATION: These findings provide evidence that neurons in MS are respiratory-deficient due to mtDNA deletions, which are extensive in GM and may be induced by inflammation. We propose induced multiple deletions of mtDNA as an important contributor to neurodegeneration in MS.

Repeats, longevity and the sources of mtDNA deletions: evidence from 'deletional spectra'.

Perfect direct repeats and, in particular, the prominent 13 bp repeat, are thought to cause mitochondrial DNA (mtDNA) deletions, which have been associated with the aging process. Accordingly, individuals lacking the 13 bp repeat are highly prevalent among centenarians and overall number of perfect repeats in mammalian mitochondrial genomes negatively correlates with species' longevity. However, detailed examination of the distribution of mtDNA deletions challenges a special role of the 13 bp repeat in generating mtDNA deletions. Instead, deletions appear to depend on long and stable, albeit imperfect, duplexes between distant mtDNA segments. Furthermore, significant dissimilarities in breakpoint distributions suggest that multiple mechanisms are involved in creating mtDNA deletions.

Mitochondrial DNA and genetic disease.

From their very beginning to the present day, mitochondria have evolved to become a crucial organelle within the cell. The mitochondrial genome encodes only 37 genes, but its compact structure and minimal redundancy results in mutations on the mitochondrial genome being an important cause of genetic disease. In the present chapter we describe the up-to-date knowledge about mitochondrial DNA structure and function, and describe some of the consequences of defective function including disease and aging.

Older mothers are not at risk of having grandchildren with sporadic mtDNA deletions.

PURPOSE: Single large-scale mitochondrial DNA deletions account for a quarter of mitochondrial disease cases and occur sporadically with unknown risk factors. Mitochondrial DNA deletions accumulate with age in many tissues. Primordial germ cells, the precursors of oocytes are made by our grandmothers, therefore we wanted to determine whether age of maternal grandmother is a risk factor for sporadic mitochondrial DNA deletions. METHODS: Twenty-nine patients with sporadic single mitochondrial DNA deletions from the Newcastle UK cohort provided dates of birth for mothers and maternal grandmothers plus father and paternal grandmother (healthy controls). RESULTS: Mean age for grandmothers at birth of a mother of an affected patient was 28.5 years (SD +/- 6.9) for single mitochondrial DNA deletions maternal grandmothers and 28.2 years (SD +/- 6.1) for healthy control paternal grandmothers. CONCLUSION: Maternal grandmother age is not a risk factor for sporadic mitochondrial DNA deletions, an important observation in a population where many women are delaying reproduction.

Detection of mitochondrial DNA variation in human cells.

The ability to detect mitochondrial DNA (mtDNA) variation within human cells is important not only to identify mutations causing mtDNA disease, but also as mtDNA mutations are being increasingly described in many ageing tissues and in complex diseases such as diabetes, neurodegeneration and cancer. In this review, we discuss the main molecular genetic techniques that can be applied to study the two main types of mtDNA mutation: point mutations and large-scale mtDNA rearrangements. We then describe in detail protocols routinely used within our laboratory to analyse mtDNA mutations in individual human cells such as single muscle fibres and individual neurons to study the relationship between mtDNA mutation load and respiratory chain dysfunction.

Mitochondrial DNA defects and selective extraocular muscle involvement in CPEO.

PURPOSE. Chronic progressive external ophthalmoplegia (CPEO) is a prominent, and often the only, presentation among patients with mitochondrial diseases. The mechanisms underlying the preferential involvement of extraocular muscles (EOMs) in CPEO were explored in a comprehensive histologic and molecular genetic study, to define the extent of mitochondrial dysfunction in EOMs compared with that in skeletal muscle from the same patient. METHODS. A well-characterized cohort of 13 CPEO patients harboring a variety of primary and secondary mitochondrial (mt)DNA defects was studied. Mitochondrial enzyme function was determined in EOM and quadriceps muscle sections with cytochrome c oxidase (COX)/succinate dehydrogenase (SDH) histochemistry, and the mutation load in single muscle fibers was quantified by real-time PCR and PCR-RFLP assays. RESULTS. CPEO patients with mtDNA deletions had more COX-deficient fibers in EOM (41.6%) than in skeletal muscle (13.7%, P > 0.0001), and single-fiber analysis revealed a lower mutational threshold for COX deficiency in EOM. Patients with mtDNA point mutations had a less severe ocular phenotype, and there was no significant difference in the absolute level of COX deficiency or mutational threshold between these two muscle groups. CONCLUSIONS. The more pronounced mitochondrial biochemical defect and lower mutational threshold in EOM compared with skeletal muscle fibers provide an explanation of the selective muscle involvement in CPEO. The data also suggest that tissue-specific mechanisms are involved in the clonal expansion and expression of secondary mtDNA deletions in CPEO patients with nuclear genetic defects.

The low abundance of clonally expanded mitochondrial DNA point mutations in aged substantia nigra neurons.

Clonally expanded mitochondrial DNA (mtDNA) deletions accumulate with age in human substantia nigra (SN) and high levels cause respiratory chain deficiency. In other human tissues, mtDNA point mutations clonally expand with age. Here, the abundance of mtDNA point mutations within single SN neurons from aged controls was investigated. From 31 single cytochrome c oxidase normal SN neurons, only one clonally expanded mtDNA point mutation was identified, suggesting in these neurons mtDNA point mutations occur rarely, whereas mtDNA deletions are frequently observed. This contrasts observations in mitotic tissues and suggests that different forms of mtDNA maintenance may exist in these two cell types.

Mitochondrial DNA mutations in disease, aging, and neurodegeneration.

Patients with disorders from mutations in the mitochondrial genome have variable phenotypes, but common to many of these disorders are underlying changes in postmitotic cells, particularly neurons and muscle fibers. The mitochondrial dysfunction caused by these mutations has been shown to be associated with signs of apoptosis and to cause cell loss. Mutations of the mitochondrial genome have also been shown to accumulate with age and in common neurodegenerative diseases, such as Parkinson's disease. This review presents recent data to show that the information gained from studying patients with mitochondrial disorders can help our understanding of the role of mitochondrial DNA mutations in brain aging and neurodegeneration.

Dopaminergic midbrain neurons are the prime target for mitochondrial DNA deletions.

Mitochondrial dysfunction is a consistent finding in neurodegenerative disorders like Alzheimer's (AD) or Parkinson's disease (PD) but also in normal human brain aging. In addition to respiratory chain defects, damage to mitochondrial DNA (mtDNA) has been repeatedly reported in brains from AD and PD patients. Most studies though failed to detect biologically significant point mutation or deletion levels in brain homogenate. By employing quantitative single cell techniques, we were recently able to show significantly high levels of mtDNA deletions in dopaminergic substantia nigra (SN) neurons from PD patients and age-matched controls. In the present study we used the same approach to quantify the levels of mtDNA deletions in single cells from three different brain regions (putamen, frontal cortex, SN) of patients with AD (n = 9) as compared to age-matched controls (n = 8). There were no significant differences between patients and controls in either region but in both groups the deletion load was markedly higher in dopaminergic SN neurons than in putamen or frontal cortex (p < 0.01; ANOVA). This data shows that there is a specific susceptibility of dopaminergic SN neurons to accumulate substantial amounts of mtDNA deletions, regardless of the underlying clinical phenotype.

Age related mitochondrial degenerative disorders in humans.

Disorders caused by mitochondrial respiratory chain deficiency due to mutations in mitochondrial DNA have varied phenotypes but many involve neurological features often associated with cell loss within specific brain regions. These disorders, along with the increasing evidence of decline in mitochondrial function with ageing, have raised speculation that primary changes in mitochondria could have an important role in age-related neurodegenerative diseases such as Parkinson's disease (PD) and Alzheimer's disease (AD). Evidence supporting a role for mitochondria in common neurodegenerative diseases comes from studies with the toxin MPP+ and familial PD, which has been shown to involve proteins such as DJ-1 and Pink1 (both of which are predicted to have a role in mitochondrial function and oxidative stress). Mutations within the mitochondrial genome have been shown to accumulate with age and in common neurodegenerative diseases. Mitochondrial DNA haplogroups have also been shown to be associated with certain neurodegenerative conditions. This review covers the primary mitochondrial diseases but also discuss the potential role of mitochondria and mitochondrial DNA mutations in mitochondrial and neurodegenerative diseases, in particular in PD and in AD.

What causes mitochondrial DNA deletions in human cells?

Mitochondrial DNA (mtDNA) deletions are a primary cause of mitochondrial disease and are likely to have a central role in the aging of postmitotic tissues. Understanding the mechanism of the formation and subsequent clonal expansion of these mtDNA deletions is an essential first step in trying to prevent their occurrence. We review the previous literature and recent results from our own laboratories, and conclude that mtDNA deletions are most likely to occur during repair of damaged mtDNA rather than during replication. This conclusion has important implications for prevention of mtDNA disease and, potentially, for our understanding of the aging process.

Nature of mitochondrial DNA deletions in substantia nigra neurons.

Mitochondrial DNA (mtDNA) deletions have been investigated in a number of neurodegenerative diseases. This study aimed to investigate the characteristics of mtDNA deletions found in single substantia nigra neurons from three patient groups: controls, Parkinson disease patients, and a patient with Parkinsonism due to multiple mtDNA deletions. We have identified 89 deletions from these neurons and examined the breakpoint characteristics of them. There was no difference in the types of mtDNA deletions detected in these neurons. These results suggest that the mechanism leading to the formation of these deletions in these three distinct groups could be the same.

The ageing mitochondrial genome.

The population of elderly individuals has increased significantly over the past century and is predicted to rise even more rapidly in the future. Ageing is a major risk factor for many diseases such as neurodegenerative disease, diabetes and cancer. This highlights the importance of understanding the mechanisms involved in the ageing process. One plausible mechanism for ageing is accumulation of mutations in the mitochondrial genome. In this review, we discuss some of the most convincing data surrounding age-related mtDNA mutations and the evidence that these mutations contribute to the ageing process.

Mitochondrial DNA mutations and aging.

Mitochondria have been hypothesized to play a role in both aging and neurodegenerative diseases, such as Parkinson's disease (PD) and Alzheimer's disease. Many studies have shown the accumulation of mitochondrial DNA (mtDNA) mutations in post-mitotic tissues and more recent data have shown this also to be a feature of aging mitotic tissues. Much of this data has been correlative, until recently with the development of polymerase gamma deficient mice which accumulate high levels of mtDNA mutations and show a premature aging phenotype, that a more causative role has been proposed. This article focuses on recent developments in aging research into the role that mtDNA mutations play in the aging process.