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.     

Mitochondrial DNA background modulates the assembly kinetics of OXPHOS complexes in a cellular model of mitochondrial disease

Leber's hereditary optic neuropathy (LHON), the most frequent mitochondrial disorder, is mostly due to three mitochondrial DNA (mtDNA) mutations in respiratory chain complex I subunit genes: 3460/ND1, 11778/ND4 and 14484/ND6. Despite considerable clinical evidences, a genetic modifying role of the mtDNA haplogroup background in the clinical expression of LHON remains experimentally unproven. We investigated the effect of mtDNA haplogroups on the assembly of oxidative phosphorylation (OXPHOS) complexes in transmitochondrial hybrids (cybrids) harboring the three common LHON mutations. The steady-state levels of respiratory chain complexes appeared normal in mutant cybrids. However, an accumulation of low molecular weight subcomplexes suggested a complex I assembly/stability defect, which was further demonstrated by reversibly inhibiting mitochondrial protein translation with doxycycline. Our results showed differentially delayed assembly rates of respiratory chain complexes I, III and IV amongst mutants belonging to different mtDNA haplogroups, revealing that specific mtDNA polymorphisms may modify the pathogenic potential of LHON mutations by affecting the overall assembly kinetics of OXPHOS complexes.     

Mutations in FASTKD2 are associated with mitochondrial disease with multi‐OXPHOS deficiency

Mutations in FASTKD2, a mitochondrial RNA binding protein, have been associated with mitochondrial encephalomyopathy with isolated complex IV deficiency. However, deficiencies related to other oxidative phosphorylation system (OXPHOS) complexes have not been reported. Here, we identified three novel FASTKD2 mutations, c.808_809insTTTCAGTTTTG, homoplasmic mutation c.868C>T, and heteroplasmic mutation c.1859delT/c.868C>T, in patients with mitochondrial encephalomyopathy. Cell‐based complementation assay revealed that these three FASTKD2 mutations were pathogenic. Mitochondrial functional analysis revealed that mutations in FASTKD2 impaired the mitochondrial function in patient‐derived lymphocytes due to the deficiency in multi‐OXPHOS complexes, whereas mitochondrial complex II remained unaffected. Consistent results were also found in human primary muscle cell and zebrafish with knockdown of FASTKD2. Furthermore, we discovered that FASTKD2 mutation is not inherently associated with epileptic seizures, optic atrophy, and loss of visual function. Alternatively, a patient with FASTKD2 mutation can show sinus tachycardia and hypertrophic cardiomyopathy, which was partially confirmed in zebrafish with knockdown of FASTKD2. In conclusion, both in vivo and in vitro studies suggest that loss of function mutation in FASTKD2 is responsible for multi‐OXPHOS complexes deficiency, and FASTKD2‐associated mitochondrial disease has a high degree of clinical heterogenicity.     

Mitochondrial DNA (mtDNA) in brain samples from patients with major psychiatric disorders: Gene expression profiles,MtDNA content and presence of the MtDNA common deletion

Several lines of evidence support a mitochondrial dysfunction in major psychiatric disorders. The objective of this study was to determine whether mitochondrial DNA (mtDNA) expression or content are implicated in the mitochondrial dysfunction observed in schizophrenia (SCH), bipolar disorder (BD), and major depressive disorder (MDD). MtDNA gene expression and mtDNA content (including the MT‐ND4 deletion) were measured by RT‐qPCR and qPCR, respectively. Post‐mortem brain tissue from 60 subjects, divided evenly into four diagnostic groups (SCH, BD, MDD, and control (C)), was analyzed. MT‐ND1 gene expression was significantly increased in the BD group compared with the C group. MDD and SCH patients showed a similar pattern of mtDNA expression, which was different from that in BD patients. Similarly, a larger number of MDD and SCH patients tended to have the MT‐ND4 gene deleted compared with BD and C subjects. However, no other significant differences were observed in mtDNA gene expression and mtDNA content. Notably, high variability was observed in the mtDNA gene expression and content in each diagnostic group. Previous studies and the present work provide evidence for a role of mtDNA in SCH, BD and MDD. However, further studies with larger patient and control groups as well as by analyzing distinct brain regions are needed to elucidate the role of mtDNA in major psychiatric disorders. © 2013 Wiley Periodicals, Inc.     

Mitochondrial genome architecture in non‐alcoholic fatty liver disease

Non‐alcoholic fatty liver disease (NAFLD) is associated with mitochondrial dysfunction, a decreased liver mitochondrial DNA (mtDNA) content, and impaired energy metabolism. To understand the clinical implications of mtDNA diversity in the biology of NAFLD, we applied deep‐coverage whole sequencing of the liver mitochondrial genomes. We used a multistage study design, including a discovery phase, a phenotype‐oriented study to assess the mutational burden in patients with steatohepatitis at different stages of liver fibrosis, and a replication study to validate findings in loci of interest. We also assessed the potential protein‐level impact of the observed mutations. To determine whether the observed changes are tissue‐specific, we compared the liver and the corresponding peripheral blood entire mitochondrial genomes. The nuclear genes POLG and POLG2 (mitochondrial DNA polymerase‐γ) were also sequenced. We observed that the liver mtDNA of patients with NAFLD harbours complex genomes with a significantly higher mutational (1.28‐fold) rate and degree of heteroplasmy than in controls. The analysis of liver mitochondrial genomes of patients with different degrees of fibrosis revealed that the disease severity is associated with an overall 1.4‐fold increase in mutation rate, including mutations in genes of the oxidative phosphorylation (OXPHOS) chain. Significant differences in gene and protein expression patterns were observed in association with the cumulative number of OXPHOS polymorphic sites. We observed a high degree of homology (～98%) between the blood and liver mitochondrial genomes. A missense POLG p.Gln1236His variant was associated with liver mtDNA copy number. In conclusion, we have demonstrated that OXPHOS genes contain the highest number of hotspot positions associated with a more severe phenotype. The variability of the mitochondrial genomes probably originates from a common germline source; hence, it may explain a fraction of the ‘missing heritability’ of NAFLD. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Deciphering exome sequencing data: Bringing mitochondrial DNA variants to light

The expanding use of exome sequencing (ES) in diagnosis generates a huge amount of data, including untargeted mitochondrial DNA (mtDNA) sequences. We developed a strategy to deeply study ES data, focusing on the mtDNA genome on a large unspecific cohort to increase diagnostic yield. A targeted bioinformatics pipeline assembled mitochondrial genome from ES data to detect pathogenic mtDNA variants in parallel with the “in‐house” nuclear exome pipeline. mtDNA data coming from off‐target sequences (indirect sequencing) were extracted from the BAM files in 928 individuals with developmental and/or neurological anomalies. The mtDNA variants were filtered out based on database information, cohort frequencies, haplogroups and protein consequences. Two homoplasmic pathogenic variants (m.9035T>C and m.11778G>A) were identified in 2 out of 928 unrelated individuals (0.2%): the m.9035T>C (MT‐ATP6) variant in a female with ataxia and the m.11778G>A (MT‐ND4) variant in a male with a complex mosaic disorder and a severe ophthalmological phenotype, uncovering undiagnosed Leber's hereditary optic neuropathy (LHON). Seven secondary findings were also found, predisposing to deafness or LHON, in 7 out of 928 individuals (0.75%). This study demonstrates the usefulness of including a targeted strategy in ES pipeline to detect mtDNA variants, improving results in diagnosis and research, without resampling patients and performing targeted mtDNA strategies.     

Human Mitochondrial Cytochrome b Variants Studied in Yeast: Not All Are Silent Polymorphisms

Variations in mitochondrial DNA (mtDNA) cytochrome b (mt‐cyb) are frequently found within the healthy population, but also occur within a spectrum of mitochondrial and common diseases. mt‐cyb encodes the core subunit (MT‐CYB) of complex III, a central component of the oxidative phosphorylation system that drives cellular energy production and homeostasis. Despite significant efforts, most mt‐cyb variations identified are not matched with corresponding biochemical data, so their functional and pathogenic consequences in humans remain elusive. While human mtDNA is recalcitrant to genetic manipulation, it is possible to introduce human‐associated point mutations into yeast mtDNA. Using this system, we reveal direct links between human mt‐cyb variations in key catalytic domains of MT‐CYB and significant changes to complex III activity or drug sensitivity. Strikingly, m.15257G>A (p.Asp171Asn) increased the sensitivity of yeast to the antimalarial drug atovaquone, and m.14798T>C (p.Phe18Leu) enhanced the sensitivity of yeast to the antidepressant drug clomipramine. We demonstrate that while a small number of mt‐cyb variations had no functional effect, others have the capacity to alter complex III properties, suggesting they could play a wider role in human health and disease than previously thought. This compendium of new mt‐cyb‐biochemical relationships in yeast provides a resource for future investigations in humans.     

Mutations in the ND5 subunit of complex I of the mitochondrial DNA are a frequent cause of oxidative phosphorylation disease

Background

Detection of mutations in the mitochondrial DNA (mtDNA) is usually limited to common mutations and the transfer RNA genes. However, mutations in other mtDNA regions can be an important cause of oxidative phosphorylation (OXPHOS) disease as well.

Objective

To investigate whether regions in the mtDNA are preferentially mutated in patients with OXPHOS disease.

Methods

Screening of the mtDNA for heteroplasmic mutations was performed by denaturing high‐performance liquid chromatography analysis of 116 patients with OXPHOS disease but without the common mtDNA mutations.

Results

An mtDNA sequence variant was detected in 15 patients, 5 of which were present in the ND5 gene. One sequence variant was new and three were known, one of which was found twice. The novel sequence variant m.13511A→T occurred in a patient with a Leigh‐like syndrome. The known mutation m.13513G→A, associated with mitochondrial encephalomyopathy lactic acidosis and stroke‐like syndrome (MELAS) and MELAS/Leigh/Leber hereditary optic neuropathy overlap syndrome, was found in a relatively low percentage in two patients from two different families, one with a MELAS/Leigh phenotype and one with a MELAS/chronic progressive external ophthalmoplegia phenotype. The known mutation m.13042G→A, detected previously in a patient with a MELAS/myoclonic epilepsy, ragged red fibres phenotype and in a family with a prevalent ocular phenotype, was now found in a patient with a Leigh‐like phenotype. The sequence variant m.12622G→A was reported once in a control database as a polymorphism, but is reported in this paper as heteroplasmic in three brothers, all with infantile encephalopathy (Leigh syndrome) fatal within the first 15 days of life. Therefore, a causal relationship between the presence of this sequence variant and the onset of mitochondrial disease cannot be entirely excluded at this moment.

Conclusions

Mutation screening of the ND5 gene is advised for routine diagnostics of patients with OXPHOS disease, especially for those with MELAS‐ and Leigh‐like syndrome with a complex I deficiency.Mitochondria are key for many cellular processes. One of the most important mechanisms is oxidative phosphorylation (OXPHOS) resulting in the production of cellular energy in the form of ATP. The OXPHOS system consists of five multiprotein complexes (I–V) and two mobile electron carriers (coenzyme q and cytochrome c) embedded in the lipid bilayer of the mitochondrial inner membrane.^1,2 The mitochondrial genome encodes 13 essential polypeptides of the OXPHOS system and the necessary RNA machinery (two ribosomal RNAs and 22 transfer RNAs (tRNA)). The remaining structural proteins and proteins involved in import, assembly and mitochondrial DNA (mtDNA) replication are encoded by the nucleus and specifically targeted to the mitochondria. OXPHOS disease is characterised by a wide variety of clinical symptoms, in which one or more organs can be involved, and by genetic and clinical heterogeneity.^2,3 With an estimated total number of about 1500 nuclear mitochondrial genes of which 600 have been identified so far,⁴ this complicates the process of identification of the underlying genetic defect. Although mutations in the mtDNA tRNA genes have been reported far more often than other mutations in mtDNA protein‐coding genes,² this figure is highly biased by a preferential screening of these genes.In this study, the complete mtDNA was screened for heteroplasmic mutations using denaturing high‐performance liquid chromatography (DHPLC) analysis in a group of 116 unrelated patients suspected for OXPHOS disease but without the common mutations for mitochondrial encephalomyopathy, lactic acidosis and stroke‐like syndrome (MELAS) m.3243A→G, myoclonic epilepsy, ragged red fibres (MERRF) m.8344A→G, Leigh/neuropathy, ataxia and retinitis pigmentosa m.8993T→G/C or large deletions. For this group of patients, we report that the ND5 gene is a commonly mutated gene.     

The pathophysiology of mitochondrial biogenesis: towards four decades of mitochondrial DNA research

Mitochondria are with very few exceptions ubiquitous organelles in eukaryotic cells where they are essential for cell life and death. Mitochondria play a central role not only in a variety of metabolic pathways including the supply of the bulk of cellular ATP through oxidative phosphorylation (OXPHOS), but also in complex processes such as development, apoptosis, and aging. Mitochondria contain their own genome that is replicated and expressed within the organelle. It encodes 13 polypeptides all of them components of the OXPHOS system, and thus, the integrity of the mitochondrial DNA (mtDNA) is critical for cellular energy supply. In the past 12 years more than 50 point mutations and around 100 rearrangements in the mtDNA have been associated with human diseases. Also in recent years, several mutations in nuclear genes that encode structural or regulatory factors of the OXPHOS system or the mtDNA metabolism have been described. The development of increasingly powerful techniques and the use of cellular and animal models are opening new avenues in the study of mitochondrial medicine. The detailed molecular characterization of the effects produced by different mutations that cause mitochondrial cytopathies will be critical for designing rational therapeutic strategies for this group of devastating diseases.     

Analysis of mitochondrial DNA sequences in patients with isolated or combined oxidative phosphorylation system deficiency

Background

Enzyme deficiencies of the oxidative phosphorylation (OXPHOS) system may be caused by mutations in the mitochondrial DNA (mtDNA) or in the nuclear DNA.

Objective

To analyse the sequences of the mtDNA coding region in 25 patients with OXPHOS system deficiency to identify the underlying genetic defect.

Results

Three novel non‐synonymous substitutions in protein‐coding genes, 4681T→C in MT‐ND2, 9891T→C in MT‐CO3 and 14122A→G in MT‐ND5, and one novel substitution in the 12S rRNA gene, 686A→G, were found. The definitely pathogenic mutation 3460G→A was identified in an 18‐year‐old woman who had severe isolated complex I deficiency and progressive myopathy.

Conclusions

Bioinformatic analyses suggest a pathogenic role for the novel 4681T→C substitution found in a boy with Leigh''s disease. These results show that the clinical phenotype caused by the primary Leber''s hereditary optic neuropathy mutation 3460G→A is more variable than has been thought. In the remaining 23 patients, the role of mtDNA mutations as a cause of the OXPHOS system deficiency could be excluded. The deficiency in these children probably originates from mutations in the nuclear genes coding for respiratory enzyme subunits or assembly factors.The oxidative phosphorylation (OXPHOS) system consists of five enzyme complexes composed of >70 subunits encoded by the nuclear genome and 13 subunits encoded by mitochondrial DNA (mtDNA). Both isolated and combined enzyme complex deficiencies have been reported in children with various clinical phenotypes. Defects in the OXPHOS system are common causes of inborn errors in energy metabolism, with an estimated incidence of 1 per 10 000 live births.¹ The inheritance pattern is autosomal recessive in most cases, but autosomal dominant and X‐chromosomal inheritance has also been described. Maternal inheritance points to a mutation in mtDNA as the cause of the disease.²More than 2000 human mtDNA‐coding region sequences have been reported since 2000, and about half of these sequences are from Europeans.^3,4,5,6,7,8 The total number of non‐synonymous mutations leading to an amino acid replacement in mtDNA of European origin has been estimated to be 1081, but as many as 18 100 sequences should be analysed to identify 95% of these substitutions.⁹ Sequencing of the complete mtDNA from patients with an OXPHOS system deficiency will evidently lead to the identification of novel pathogenic mutations. This approach has already yielded several novel mutations in MT‐ND genes so far, and some of them—for example, 10191T→C and 14487T→C—may not be uncommon causes of disease.^10,11

Key points

• Enzyme deficiencies of the oxidative phosphorylation (OXPHOS) system may be caused by mutations in the mitochondrial DNA (mtDNA) or in the nuclear DNA. The sequence of mtDNA‐coding region was analysed in 25 patients with OXPHOS system deficiency to identify the underlying genetic defect.
• 4681T→C, a novel substitution in MT‐ND2, was found in a patient with Leigh''s disease. Further analyses suggested a pathogenic role for this substitution.
• 3460G→A, one of the mutations causing Leber''s hereditary optic neuropathy, was identified in a patient with progressive myopathy. The finding suggests that the clinical phenotype caused by this mutation is more variable than what has been known.

There is a growing need to analyse complete mtDNA sequences with a high throughput and in a cost‐efficient manner. We analysed the entire coding region of mtDNA in 28 patients (consisting of children and young adults) with OXPHOS system deficiency using a protocol consisting of conformation‐sensitive gel electrophoresis (CSGE) of amplified mtDNA fragments and subsequent sequencing of those fragments that differed in mobility in CSGE. Obtained sequences were compared with previously reported mtDNA sequences to identify haplotype‐specific or novel variants, and to detect possible sequencing errors.¹² The quality of the sequences was confirmed by comparison of the sequences obtained using the CSGE protocol with those obtained using direct mtDNA sequencing, and by correct identification of three samples with a known pathogenic mutation. Three novel non‐synonymous substitutions and one novel rRNA substitution were detected, and their pathogenic potential was estimated on several criteria.     

Two Siblings with Homozygous Pathogenic Splice‐Site Variant in Mitochondrial Asparaginyl–tRNA Synthetase (NARS2)

A homozygous missense mutation (c.822G>C) was found in the gene encoding the mitochondrial asparaginyl–tRNA synthetase (NARS2) in two siblings born to consanguineous parents. These siblings presented with different phenotypes: one had mild intellectual disability and epilepsy in childhood, whereas the other had severe myopathy. Biochemical analysis of the oxidative phosphorylation (OXPHOS) complexes in both siblings revealed a combined complex I and IV deficiency in skeletal muscle. In‐gel activity staining after blue native‐polyacrylamide gel electrophoresis confirmed the decreased activity of complex I and IV, and, in addition, showed the presence of complex V subcomplexes. Considering the consanguineous descent, homozygosity mapping and whole‐exome sequencing were combined revealing the presence of one single missense mutation in the shared homozygous region. The c.822G>C variant affects the 3′ splice site of exon 7, leading to skipping of the whole exon 7 and a part of exon 8 in the NARS2 mRNA. In EBV‐transformed lymphoblasts, a specific decrease in the amount of charged mt‐tRNA^Asn was demonstrated as compared with controls. This confirmed the pathogenic nature of the variant. To conclude, the reported variant in NARS2 results in a combined OXPHOS complex deficiency involving complex I and IV, making NARS2 a new member of disease‐associated aaRS2.     

A study of 133 Chinese children with mitochondrial respiratory chain complex I deficiency

To investigate the clinical, enzymological and mitochondrial gene profiles of complex I deficiency in Chinese, clinical and laboratory data of the patients (79 boys, 54 girls) were retrospectively assessed. Activities of mitochondrial respiratory chain complexes in peripheral leucocytes were spectrophotometrically measured. The entire mitochondrial DNA (mtDNA) sequence was analyzed in 62 patients. Restriction fragment length polymorphism and gene sequencing analyses were performed in 15 families. Ninety‐one patients had isolated complex I deficiency; 42 had combined deficiencies of complex I and other complexes. The main clinical presentations were neuromuscular disorders (107 patients) and non‐neurological dysfunction (hepatopathy, renal damage and cardiomyopathy; 26 patients). In 32 of 62 patients who underwent mtDNA sequencing, 24 mutations were identified in 15 mitochondrial genes. The 12338T>C, 4833A>G and 14502T>C mutations were found in 12.9%, 11.3% and 4.8% patients, respectively. Seven patients had multiple mutations. Three novel mutations were identified. Chinese patients with complex I deficiency presented heterogeneous phenotypes and genotypes. Twenty‐four mutations were identified in 15 mitochondrial genes in 51.6% patients. mtDNA mutations were more common in isolated complex I deficiency than in combined complex deficiencies. The 12338T>C, 4833A>G and 14502T>C mutations were common.     

Genetic Epidemiology of Mitochondrial Pathogenic Variants Causing Nonsyndromic Hearing Loss in a Large Cohort of South Indian Hearing Impaired Individuals

Mitochondria play a critical role in the generation of metabolic energy in the form of ATP. Tissues and organs that are highly dependent on aerobic metabolism are involved in mitochondrial disorders including nonsyndromic hearing loss (NSHL). Seven pathogenic variants leading to NSHL have so far been reported on two mitochondrial genes: MT‐RNR1 encoding 12SrRNA and MT‐TS1 encoding tRNA for Ser^(UCN). We screened 729 prelingual NSHL subjects to determine the prevalence of MT‐RNR1 variants at position m.961, m.1555A>G and m.1494C>T, and MT‐TS1 m.7445A>G, m.7472insC m.7510T>C and m.7511T>C variants. Mitochondrial pathogenic variants were found in eight probands (1.1%). Five of them were found to have the m.1555A>G variant, two others had m.7472insC and one proband had m.7444G>A. The extended relatives of these probands showed variable degrees of hearing loss and age at onset. This study shows that mitochondrial pathogenic alleles contribute to about 1% prelingual hearing loss. This study will henceforth provide the reference for the prevalence of mitochondrial pathogenic alleles in the South Indian population, which to date has not been estimated. The m.1555A>G variant is a primary predisposing genetic factor for the development of hearing loss. Our study strongly suggests that mitochondrial genotyping should be considered for all hearing impaired individuals and particularly in families where transmission is compatible with maternal inheritance, after ruling out the most common variants.     

A Novel in‐Frame 18‐bp Microdeletion in MT‐CYB Causes a Multisystem Disorder with Prominent Exercise Intolerance

A novel heteroplasmic mitochondrial DNA (mtDNA) microdeletion affecting the cytochrome b gene (MT‐CYB) was identified in an Italian female patient with a multisystem disease characterized by sensorineural deafness, cataracts, retinal pigmentary dystrophy, dysphagia, postural and gait instability, and myopathy with prominent exercise intolerance. The deletion is 18‐base pair long and encompasses nucleotide positions 15,649–15,666, causing the loss of six amino acids (Ile‐Leu‐Ala‐Met‐Ile‐Pro) in the protein, but leaving the remaining of the MT‐CYB sequence in frame. The defective complex III function was cotransferred with mutant mtDNA in cybrids, thus unequivocally establishing its pathogenic role. Maternal relatives failed to show detectable levels of the deletion in blood and urinary epithelium, suggesting a de novo mutational event. This is the second report of an in‐frame intragenic deletion in MT‐CYB, which most likely occurred in early stages of embryonic development, associated with a severe multisystem disorder with prominent exercise intolerance.     

Functional consequences of mitochondrial tRNATrp and tRNAArg mutations causing combined OXPHOS defects

Combined oxidative phosphorylation (OXPHOS) system deficiencies are a group of mitochondrial disorders that are associated with a range of clinical phenotypes and genetic defects. They occur in approximately 30% of all OXPHOS disorders and around 4% are combined complex I, III and IV deficiencies. In this study we present two mutations in the mitochondrial tRNA^Trp (MT-TW) and tRNA^Arg (MT-TR) genes, m.5556G>A and m.10450A>G, respectively, which were detected in two unrelated patients showing combined OXPHOS complex I, III and IV deficiencies and progressive multisystemic diseases. Both mitochondrial tRNA mutations were almost homoplasmic in fibroblasts and muscle tissue of the two patients and not present in controls. Patient fibroblasts showed a general mitochondrial translation defect. The mutations resulted in lowered steady-state levels and altered conformations of the tRNAs. Cybrid cell lines showed similar tRNA defects and impairment of OXPHOS complex assembly as patient fibroblasts. Our results show that these tRNA^Trp and tRNA^Arg mutations cause the combined OXPHOS deficiencies in the patients, adding to the still expanding group of pathogenic mitochondrial tRNA mutations.     

Pathogenic Mitochondrial tRNA Point Mutations: Nine Novel Mutations Affirm Their Importance as a Cause of Mitochondrial Disease

Mutations in the mitochondrial genome, and in particular the mt‐tRNAs, are an important cause of human disease. Accurate classification of the pathogenicity of novel variants is vital to allow accurate genetic counseling for patients and their families. The use of weighted criteria based on functional studies—outlined in a validated pathogenicity scoring system—is therefore invaluable in determining whether novel or rare mt‐tRNA variants are pathogenic. Here, we describe the identification of nine novel mt‐tRNA variants in nine families, in which the probands presented with a diverse range of clinical phenotypes including mitochondrial encephalomyopathy, lactic acidosis, and stroke‐like episodes, isolated progressive external ophthalmoplegia, epilepsy, deafness and diabetes. Each of the variants identified (m.4289T>C, MT‐TI; m.5541C>T, MT‐TW; m.5690A>G, MT‐TN; m.7451A>T, MT‐TS1; m.7554G>A, MT‐TD; m.8304G>A, MT‐TK; m.12206C>T, MT‐TH; m.12317T>C, MT‐TL2; m.16023G>A, MT‐TP) was present in a different tRNA, with evidence in support of pathogenicity, and where possible, details of mutation transmission documented. Through the application of the pathogenicity scoring system, we have classified six of these variants as “definitely pathogenic” mutations (m.5541C>T, m.5690A>G, m.7451A>T, m.12206C>T, m.12317T>C, and m.16023G>A), whereas the remaining three currently lack sufficient evidence and are therefore classed as ‘possibly pathogenic’ (m.4289T>C, m.7554G>A, and m.8304G>A).     

Clinical differences in patients with mitochondriocytopathies due to nuclear versus mitochondrial DNA mutations

Defects in oxidative phosphorylation (OXPHOS) are genetically unique because the different components involved in this process, respiratory chain enzyme complexes (I, III, and IV) and complex V, are encoded by nuclear and mitochondrial genome. The objective of the study was to assess whether there are clinical differences in patients suffering from OXPHOS defects caused by nuclear or mitochondrial DNA (mtDNA) mutations. We studied 16 families with > or = two siblings with a genetically established OXPHOS deficiency, four due to a nuclear gene mutation and 12 due to a mtDNA mutation. Siblings with a nuclear gene mutation showed very similar clinical pictures that became manifest in the first years (ranging from first months to early childhood). There was a severe progressive course. Seven of the eight children died in their first decade. Conversely, siblings with a mtDNA mutation had clinical pictures that varied from almost alike to very distinct. They became symptomatic at an older age (ranging from childhood to adulthood), with the exception of defects associated with Leigh or Leigh-like phenotype. The clinical course was more gradual and relatively less severe; four of the 26 patients died, one in his second year, another in her second decade and two in their sixth decade. There are differences in age at onset, severity of clinical course, outcome, and intrafamilial variability in patients affected of an OXPHOS defect due to nuclear or mtDNA mutations. Patients with nuclear mutations become symptomatic at a young age, and have a severe clinical course. Patients with mtDNA mutations show a wider clinical spectrum of age at onset and severity. These differences may be of importance regarding the choice of which genome to study in affected patients as well as with respect to genetic counseling.     

Complete Mitochondrial Genome Analysis and Clinical Documentation of a Five‐Generational Indian Family with Mitochondrial 1555A>G Mutation and Postlingual Hearing Loss

Hearing loss is the most common sensory disorder and is genetically heterogeneous. Apart from nuclear gene mutations, a number of inherited mitochondrial mutations have also been implicated. The m.1555A>G mutation in the mitochondrial MT‐RNR1 gene is reported as the most common mutation causing nonsyndromic hearing loss in various ethnic populations. We report here for the first time the clinical, genetic and molecular characterisation of a single large five‐generational Tamil‐speaking South Indian family with maternally inherited nonsyndromic postlingual hearing loss. Molecular analysis led to identification of m.1555A>G in 28 maternal relatives with variable degree of phenotypic expression. The penetrance of hearing loss among the maternal relatives in this family was 55%. Sequence analysis of the complete mitochondrial genome in 36 members of this pedigree identified 25 known variants and one novel variant co‐transmitted along with m.1555A>G mutation. The mtDNA haplotype analysis revealed that the maternal relatives carry the R*T₂ haplotype similar to Europeans and South Asians. Sequencing of the coding exon of GJB2 nuclear gene did not show any pathogenic mutations. The results suggest that other nuclear or environmental modifying factors could have played a role in the differential expression of mutation m.1555A>G in postlingual hearing loss in this family.