Capture of somatic mtDNA point mutations with severe effects on oxidative phosphorylation in synaptosome cybrid clones from human brain.

Mitochondrial DNA (mtDNA) is replicated throughout life in postmitotic cells, resulting in higher levels of somatic mutation than in nuclear genes. However, controversy remains as to the importance of low-level mtDNA somatic mutants in cancerous and normal human tissues. To capture somatic mtDNA mutations for functional analysis, we generated synaptosome cybrids from synaptic endings isolated from fresh hippocampus and cortex brain biopsies. We analyzed the whole mtDNA genome from 120 cybrid clones derived from four individual donors by chemical cleavage of mismatch and Sanger sequencing, scanning around two million base pairs. Seventeen different somatic point mutations were identified, including eight coding region mutations, four of which result in frameshifts. Examination of one cybrid clone with a novel m.2949_2953delCTATT mutation in MT-RNR2 (which encodes mitochondrial 16S rRNA) revealed a severe disruption of mtDNA-encoded protein translation. We also performed functional studies on a homoplasmic nonsense mutation in MT-ND1, previously reported in oncocytomas, and show that both ATP generation and the stability of oxidative phosphorylation complex I are disrupted. As the mtDNA remains locked against direct genetic manipulation, we demonstrate that the synaptosome cybrid approach can capture biologically relevant mtDNA mutants in vitro to study effects on mitochondrial respiratory chain function.

Long-term screening for primary mitochondrial DNA variants associated with Leber hereditary optic neuropathy: incidence, penetrance and clinical features.

Leber hereditary optic neuropathy (LHON) is a neurodegenerative disorder characterised by bilateral, painless, subacute, central vision loss caused by pathogenic sequence variants in mitochondrial DNA (mtDNA). Over the course of 20 years, 734 people were systematically screened by our diagnostic laboratory for suspected LHON or for being at risk of LHON, with 98 found to harbour one of the three primary pathogenic mtDNA variants. Detection incidences were: 0.95% for NC_012920.1(MT-ND1):m.3460G>A; 9.4% for (MT-ND4):m.11778G>A; and 2.9% for (MT-ND6):m.14484T>C. The median age for symptomatic males was 27.3 years and for females 29.5 years, with a male to female ratio of 4.4:1 (62 males; 14 females). Most pathogenic variant carriers were propositi with the other individuals belonging to one of 14 pedigrees with noteworthy intra-family variability of clinical severity of the disease.

Association of the MELAS m.3243A>G mutation with myositis and the superiority of urine over muscle, blood and hair for mutation detection.

A patient with a known family history of mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS) due to the MT-TL1 m.3243A>G mutation presented with mild myalgia and very minor upper limb proximal muscle weakness. Muscle histology revealed low levels of cytochrome oxidase-negative fibres and non-specific myositis. Using the last "hot cycle" polymerase chain reaction (PCR)-restriction fragment length polymorphism (RFLP), the MELAS MT-TL1 m.3243A>G mutation was only detected in urine, and not in hair, blood or skeletal muscle. This report highlights the need to screen various tissues to achieve an accurate mitochondrial genetic diagnosis and suggests the likelihood of myositis arising secondary to the MELAS MT-TL1 m.3243A>G mutation.

Limb-girdle muscular dystrophy: diagnostic evaluation, frequency and clues to pathogenesis.

We characterized the frequency of limb-girdle muscular dystrophy (LGMD) subtypes in a cohort of 76 Australian muscular dystrophy patients using protein and DNA sequence analysis. Calpainopathies (8%) and dysferlinopathies (5%) are the most common causes of LGMD in Australia. In contrast to European populations, cases of LGMD2I (due to mutations in FKRP) are rare in Australasia (3%). We have identified a cohort of patients in whom all common disease candidates have been excluded, providing a valuable resource for identification of new disease genes. Cytoplasmic localization of dysferlin correlates with fiber regeneration in a subset of muscular dystrophy patients. In addition, we have identified a group of patients with unidentified forms of LGMD and with markedly abnormal dysferlin localization that does not correlate with fiber regeneration. This pattern is mimicked in primary caveolinopathy, suggesting a subset of these patients may also possess mutations within proteins required for membrane targeting of dysferlin.

Novel single base pair COX III subunit deletion of mitochondrial DNA associated with rhabdomyolysis.

A high number of cytochrome c oxidase (COX)-negative muscle fibres (approximately 45%) without ragged red fibres was found in a 27-year-old male patient with a single unprovoked episode of severe rhabdomyolysis. There was no family history of neuromuscular disorder and sequencing revealed a novel COX III single base pair deletion (MT-CO3{NC_012920.1}:m.[9559delC]). The deletion creates a frame shift and downstream termination codon affecting the last 136 amino acids (MT-CO3{YP_003024032.1}:p.[Pro118GlnfsX124]). The heteroplasmic mutation load in muscle was approximately 58% and single COX-negative fibres harboured significantly greater levels of mutant mitochondrial DNA than COX-positive fibres.

Chemical cleavage of mismatch (CCM) to locate base mismatches in heteroduplex DNA.

This protocol describes the use of the chemical cleavage of mismatch (CCM) method to assess whether a region of DNA contains mutations and to localize them. Compared with other mutation-detection techniques (such as single strand-conformation polymorphism (SSCP) analysis, denaturing high-performance liquid chromatography (DHPLC) and denaturing gradient gel electrophoresis (DGGE)) that detect mutations in short DNA fragments and require highly specific melting temperatures, CCM has a higher diagnostic sensitivity suited to the detection of mutations in tumor genes, and can analyze amplicons < or = 2 kb in length. To detect mutations, PCR heteroduplexes are incubated with two mismatch-specific reagents. Hydroxylamine modifies unpaired cytosine and potassium permanganate modifies unpaired thymine. The samples are then incubated with piperidine, which cleaves the DNA backbone at the site of the modified mismatched base. Cleavage products are separated by electrophoresis, revealing the identity and location of the mutation. The CCM method can efficiently detect point mutations as well as insertions and deletions. This protocol can be completed in 10 h.

Functional respiratory chain analyses in murid xenomitochondrial cybrids expose coevolutionary constraints of cytochrome b and nuclear subunits of complex III.

The large number of extant Muridae species provides the opportunity of investigating functional limits of nuclear/mitochondrial respiratory chain (RC) subunit interactions by introducing mitochondrial genomes from progressively more divergent species into Mus musculus domesticus mtDNA-less (rho0) cells. We created a panel of such xenomitochondrial cybrids, using as mitochondrial donors cells from six murid species with divergence from M. m. domesticus estimated at 2 to 12 Myr before present. Species used were Mus spretus, Mus caroli, Mus dunni, Mus pahari, Otomys irroratus, and Rattus norvegicus. Parsimony analysis of partial mtDNA sequences showed agreement with previous molecular phylogenies, with the exception that Otomys did not nest within the murinae as suggested by some recent nuclear gene analyses. Cellular production of lactate, a sensitive indicator of decreased respiratory chain ATP production, correlated with divergence. Functional characterization of the chimeric RC complexes in isolated mitochondria using enzymological analyses demonstrated varying decreases in activities of complexes I, III, and IV, which have subunits encoded in both mitochondrial and nuclear genomes. Complex III showed a striking decline in electron transfer function in the most divergent xenocybrids, being greatly reduced in the Rattus xenocybrid and virtually absent in the Otomys xenocybrid. This suggests that nuclear subunits interacting with cytochrome b face the greatest constraints in the coevolution of murid RC subunits. We sequenced the cytochrome b gene from the species used to identify potential amino acid substitutions involved in such interactions. The greater sensitivity of complex III to xenocybrid dysfunction may result from the encoding of redox center apoproteins in both nuclear and mitochondrial genomes, a unique feature of this RC complex.