Electron transfer properties of NADH:ubiquinone reductase in the ND1/3460 and the ND4/11778 mutations of the Leber hereditary optic neuroretinopathy (LHON)

We report the electron transfer properties of the NADH:ubiquinone oxidoreductase complex of the respiratory chain (Complex I) in mitochondria of cells derived from LHON patients with two different mutations in mitochondrial DNA (mtDNA). The mutations occur in the mtDNA genes coding for the ND1 and ND4 subunits of Complex I. The ND1/3460 mutation exhibits 80% reduction in rotenone-sensitive and ubiquinone-dependent electron transfer activity, whereas the proximal NADH dehydrogenase activity of the Complex is unaffected. This is in accordance with the proposal that the ND1 subunit interacts with rotenone and ubiquinone. In contrast, the ND4/11778 mutation had no effect on electron transfer activity of the Complex in inner mitochondrial membrane preparations; also Km for NADH and NADH dehydrogenase activity were unaffected. However, in isolated mitochondria with the ND4 mutation, the rate of oxidation of NAD-linked substrates, but not of succinate, was significantly decreased. This suggests that the ND4 subunit might be involved in specific aggregation of NADH-dependent dehydrogenases and Complex I, which may result in fast ('solid state') electron transfer from the former to the latter.     

Analysis of mitochondrial ND4 gene DNA sequence in Finnish families with Leber hereditary optic neuroretinopathy

A mutation in the mitochondrial DNA at nt 11,778 has recently been found in Leber hereditary optic neuroretinopathy (LHON), a maternally inherited ocular disease. The mutation is located in the ND4 gene encoding subunit 4 of the respiratory chain enzyme NADH dehydrogenase. The mutation was subsequently not found in 9 of the 20 known Finnish families with LHON, implying that there are at least two different mutations associated with the disease. Using direct sequencing of PCR-amplified mtDNA, we have now sequenced the entire ND4 region in the families without the nt 11,778 mutation to find the other mutations. No new mutations in the ND4 region were found, suggesting that the putative mtDNA mutation in these families may be in the coding regions for other subunits of NADH dehydrogenase enzyme. The sequence of ND4 gene as found to be highly homogeneous.     

The mtDNA-encoded ND6 subunit of mitochondrial NADH dehydrogenase is essential for the assembly of the membrane arm and the respiratory function of the enzyme.

Seven of the approximately 40 subunits of the mammalian respiratory NADH dehydrogenase (Complex I) are encoded in mitochondrial DNA (mtDNA). Their function is almost completely unknown. In this work, a novel selection scheme has led to the isolation of a mouse A9 cell derivative defective in NADH dehydrogenase activity. This cell line carries a near-homoplasmic frameshift mutation in the mtDNA gene for the ND6 subunit resulting in an almost complete absence of this polypeptide, while lacking any mutation in the other mtDNA-encoded subunits of the enzyme complex. Both the functional defect and the mutation were transferred with the mutant mitochondria into mtDNA-less (rho0) mouse LL/2-m21 cells, pointing to the pure mitochondrial genetic origin of the defect. A detailed biosynthetic and functional analysis of the original mutant and of the rho0 cell transformants revealed that the mutation causes a loss of assembly of the mtDNA-encoded subunits of the enzyme and, correspondingly, a reduction in malate/glutamate-dependent respiration in digitonin-permeabilized cells by approximately 90% and a decrease in NADH:Q1 oxidoreductase activity in mitochondrial extracts by approximately 99%. Furthermore, the ND6(-) cells, in contrast to the parental cells, completely fail to grow in a medium containing galactose instead of glucose, indicating a serious impairment in oxidative phosphorylation function. These observations provide the first evidence of the essential role of the ND6 subunit in the respiratory function of Complex I and give some insights into the pathogenic mechanism of the known disease-causing ND6 gene mutations.     

Nuclear suppression of mitochondrial defects in cells without the ND6 subunit

Previously, we characterized a mouse cell line, 4A, carrying a mitochondrial DNA mutation in the subunit for respiratory complex I, NADH dehydrogenase, in the ND6 gene. This mutation abolished the complex I assembly and disrupted the respiratory function of complex I. We now report here that a galactose-resistant clone, 4AR, was isolated from the cells carrying the ND6 mutation. 4AR still contained the homoplasmic mutation, and apparently there was no ND6 protein synthesis, whereas the assembly of other complex I subunits into complex I was recovered. Furthermore, the respiratory activity and mitochondrial membrane potential were fully recovered. To investigate the genetic origin of this compensation, the mitochondrial DNA (mtDNA) from 4AR was transferred to a new nuclear background. The transmitochondrial lines failed to grow in galactose medium. We further transferred mtDNA with a nonsense mutation at the ND5 gene to the 4AR nuclear background, and a suppression for mitochondrial deficiency was observed. Our results suggest that change(s) in the expression of a certain nucleus-encoded factor(s) can compensate for the absence of the ND6 or ND5 subunit.     

The Deafness-Associated Mitochondrial DNA Mutation at Position 7445, Which Affects tRNASer(UCN) Precursor Processing, Has Long-Range Effects on NADH Dehydrogenase Subunit ND6 Gene Expression

The pathogenetic mechanism of the deafness-associated mitochondrial DNA (mtDNA) T7445C mutation has been investigated in several lymphoblastoid cell lines from members of a New Zealand pedigree exhibiting the mutation in homoplasmic form and from control individuals. We show here that the mutation flanks the 3′ end of the tRNA^Ser(UCN) gene sequence and affects the rate but not the sites of processing of the tRNA precursor. This causes an average reduction of ~70% in the tRNA^Ser(UCN) level and a decrease of ~45% in protein synthesis rate in the cell lines analyzed. The data show a sharp threshold in the capacity of tRNA^Ser(UCN) to support the wild-type protein synthesis rate, which corresponds to ~40% of the control level of this tRNA. Strikingly, a 7445 mutation-associated marked reduction has been observed in the level of the mRNA for the NADH dehydrogenase (complex I) ND6 subunit gene, which is located ~7 kbp upstream and is cotranscribed with the tRNA^Ser(UCN) gene, with strong evidence pointing to a mechanistic link with the tRNA precursor processing defect. Such reduction significantly affects the rate of synthesis of the ND6 subunit and plays a determinant role in the deafness-associated respiratory phenotype of the mutant cell lines. In particular, it accounts for their specific, very significant decrease in glutamate- or malate-dependent O₂ consumption. Furthermore, several homoplasmic mtDNA mutations affecting subunits of NADH dehydrogenase may play a synergistic role in the establishment of the respiratory phenotype of the mutant cells.     

Efficient selection and characterization of mutants of a human cell line which are defective in mitochondrial DNA-encoded subunits of respiratory NADH dehydrogenase.

The mitochondrial NADH dehydrogenase (complex I) in mammalian cells is a multimeric enzyme consisting of approximately 40 subunits, 7 of which are encoded in mitochondrial DNA (mtDNA). Very little is known about the function of these mtDNA-encoded subunits. In this paper, we describe the efficient isolation from a human cell line of mutants affected in any of these subunits. In the course of analysis of eight mutants of the human cell line VA2B selected for their resistance to high concentrations of the complex I inhibitor rotenone, seven were found to be respiration deficient, and among these, six exhibited a specific defect of complex I. Transfer of mitochondria from these six mutants into human mtDNA-less cells revealed, surprisingly, in all cases a cotransfer of the complex I defect but not of the rotenone resistance. This result indicated that the rotenone resistance resulted from a nuclear mutation, while the respiration defect was produced by an mtDNA mutation. A detailed molecular analysis of the six complex I-deficient mutants revealed that two of them exhibited a frameshift mutation in the ND4 gene, in homoplasmic or in heteroplasmic form, resulting in the complete or partial loss, respectively, of the ND4 subunit; two other mutants exhibited a frameshift mutation in the ND5 gene, in near-homoplasmic or heteroplasmic form, resulting in the ND5 subunit being undetectable or strongly decreased, respectively. It was previously reported (G. Hofhaus and G. Attardi, EMBO J. 12:3043-3048, 1993) that the mutant completely lacking the ND4 subunit exhibited a total loss of NADH:Q1 oxidoreductase activity and a lack of assembly of the mtDNA-encoded subunits of complex I. By contrast, in the mutant characterized in this study in which the ND5 subunit was not detectable and which was nearly totally deficient in complex I activity, the capacity to assemble the mtDNA-encoded subunits of the enzyme was preserved, although with a decreased efficiency or a reduced stability of the assembled complex. The two remaining complex I-deficient mutants exhibited a normal rate of synthesis and assembly of the mtDNA-encoded subunits of the enzyme, and the mtDNA mutation(s) responsible for their NADH dehydrogenase defect remains to be identified. The selection scheme used in this work has proven to be very valuable for the isolation of mutants from the VA2B cell line which are affected in different mtDNA-encoded subunits of complex I and may be applicable to other cell lines.     

A novel G3337A mitochondrial ND1 mutation related to cardiomyopathy co-segregates with tRNALeu(CUN) A12308G and tRNAThr C15946T mutations

We describe a novel mutation in human mitochondrial NADH dehydrogenase 1 gene (ND1), a G to A transition at nucleotide position 3337, which is co-segregated with two known mutations in tRNALeu(CUN) A12308G and tRNAThr C15946T. These mutations were detected in two unrelated patients with different clinical phenotypes, exhibiting cardiomyopathy as the common symptom. The ND1 G3337A mutation that was detected was found almost homoplasmic in the two patients and it was absent in 150 individuals that were tested as control group. Mitochondrial respiratory chain complex I activity of the patients platelets was also tested and found decreased compared to those of controls. We suggest that the co-existence of mutations in tRNA and ND1 genes may act synergistically affecting the clinical phenotype. Our study highlights the enormous phenotypic diversity that exists among pathogenic mtDNA mutations and re-emphasizes the need for a more careful clinical approach.     

Somatic mutations of mitochondrial genome in hepatocellular carcinoma

Somatic mutations have been identified in mitochondrial DNA (mtDNA) of various human primary cancers. However, their roles in the pathophysiology of cancers are still unclear. In our previous study, high frequency of somatic mutations was found in the D-loop region of mtDNA of hepatocellular carcinomas (HCCs). In the present study, we examined 44 HCCs and corresponding non-cancerous liver tissues, and identified 13 somatic mutations in the coding region of mtDNAs from 11 HCC samples (11/44, 25%). Among the 13 mtDNA mutations, six mutations (T6787C, G7976A, A9263G, G9267A, A9545G and A11708G) were homoplasmic while seven mutations (956delC, T1659C, G3842A, G5650A, 11032delA, 12418insA and a 66 bp deletion) were heteroplasmic. Moreover, the G3842A transition created a premature stop codon and the 66 bp deletion could omit 22 amino acid residues in the NADH dehydrogenase (ND) subunit 1 (ND1) gene. The 11032delA and 12418insA could result in frame-shift mutation in the ND4 and ND5 genes, respectively. The T1659C transition in tRNA^Val gene and G5650A in tRNA^Ala gene were reported to be clinically associated with some mitochondrial disorders. In addition, the T6787C (cytochrome c oxidase subunit I, COI), G7976A (COII), G9267A (COIII) and A11708G (ND4) mutations could result in amino acid substitutions in the highly conserved regions of the affected mitochondrial genes. These mtDNA mutations (10/13, 76.9%) have the potential to cause mitochondrial dysfunction in HCCs. Taken these results together, we suggest that there may be a higher frequency of mtDNA mutations in HCC than in normal liver tissues from the same individuals.     

Complete sequence analysis of mitochondrial DNA of aplastic anemia patients

This study was primarily undertaken to test the hypothesis that mitochondrial DNA (mtDNA) mutations may be associated with aplastic anemia (AA). We analyzed mtDNA sequences from 15 patients with AA. The samples were obtained from bone marrow, and patients' oral epithelial cells were collected for normal tissue comparison. Total DNA was amplified by PCR after extraction, and these segments were then sent for sequencing. The results were compared with those of oral epithelial tissues as well as mtDNA sequences in the revised Cambridge Reference Sequence (rCRS) database. We detected 61 heteroplasmic mutations in 11 genes, including those encoding NADH dehydrogenase (ND)1-2 and 4-6, tRNA glutamic acid (TRNE), ribosomal RNA (RNR) 1 and 2, cytochrome c oxidase (COX1), cytochrome b (CYTB), and tRNA glycine (TRNG); mutation rates were particularly high in ND2 (34.4%) and ND4 (21.3%) in the patients' mtDNA genomes. The products of these genes are involved in oxidation in the respiratory chain, and a large number of homoplasmic mutations were found. Interestingly, these 162 polymorphisms were mostly in the D-loop DNA structure (54.3%), in which numerous mutations associated with leukemia and myelodysplastic syndromes are found. We conclude that functional impairment of the mitochondrial respiratory chain induced by mutation may be an important reason for hematopoietic failure in AA patients.     

Reconstruction of a human mitochondrial complex I mutation in the unicellular green alga Chlamydomonas

Defects in complex I (NADH:ubiquinone oxidoreductase (EC 1.6.5.3)) are the most frequent cause of human respiratory disorders. The pathogenicity of a given human mitochondrial mutation can be difficult to demonstrate because the mitochondrial genome harbors large numbers of polymorphic base changes that have no pathogenic significance. In addition, mitochondrial mutations are usually found in the heteroplasmic state, which may hide the biochemical effect of the mutation. We propose that the unicellular green alga Chlamydomonas could be used to study such mutations because (i) respiratory complex-deficient mutants are viable and mitochondrial mutations are found in the homoplasmic state, (ii) transformation of the mitochondrial genome is feasible, and (iii) Chlamydomonas complex I is similar to that of humans. To illustrate this proposal, we introduced a Leu157Pro substitution into the Chlamydomonas ND4 subunit of complex I in two recipient strains by biolistic transformation, demonstrating that site-directed mutagenesis of the Chlamydomonas mitochondrial genome is possible. This substitution did not lead to any respiratory enzyme defects when present in the heteroplasmic state in a patient with chronic progressive external ophthalmoplegia. When present in the homoplasmic state in the alga, the mutation does not prevent assembly of whole complex I (950 kDa) and the NADH dehydrogenase activity of the peripheral arm of the complex is mildly affected. However, the NADH:duroquinone oxidoreductase activity is strongly reduced, suggesting that the substitution could affect binding of ubiquinone to the membrane domain. The in vitro defects correlate with a decrease in dark respiration and growth rate in vivo.     

Detection of point mutations in codon 331 of mitochondrial NADH dehydrogenase subunit 2 in Alzheimer's brains.

Point mutations in codon 331 of mitochondrial NADH dehydrogenase subunit 2 (ND2) were detected in 10 of 19 Alzheimer's brains but not in 11 normal brains. The same mutations were also detected in 2 of 6 patients with amyotrophic lateral sclerosis (ALS). However, neurofibrillary tangles and neuritic plaques characteristic of Alzheimer's disease were found histologically in the brain of one ALS patient who was positive of the mutation. The finding suggests that a point mutation in ND2 is a potential risk factor for Alzheimer's disease.     

Use of transmitochondrial cybrids to assign a complex I defect to the mitochondrial DNA-encoded NADH dehydrogenase subunit 6 gene mutation at nucleotide pair 14459 that causes Leber hereditary optic neuropathy and dystonia.

A heteroplasmic G-to-A transition at nucleotide pair (np) 14459 within the mitochondrial DNA (mtDNA)-encoded NADH dehydrogenase subunit 6 (ND6) gene has been identified as the cause of Leber hereditary optic neuropathy (LHON) and/or pediatric-onset dystonia in three unrelated families. This ND6 np 14459 mutation changes a moderately conserved alanine to a valine at amino acid position 72 of the ND6 protein. Enzymologic analysis of mitochondrial NADH dehydrogenase (complex I) with submitochondrial particles isolated from Epstein-Barr virus-transformed lymphoblasts revealed a 60% reduction (P < 0.005) of complex I-specific activity in patient cell lines compared with controls, with no differences in enzymatic activity for complexes II plus III, III and IV. This biochemical defect was assigned to the ND6 np 14459 mutation by using transmitochondrial cybrids in which patient Epstein-Barr virus-transformed lymphoblast cell lines were enucleated and the cytoplasts were fused to a mtDNA-deficient (p 0) lymphoblastoid recipient cell line. Cybrids harboring the np 14459 mutation exhibited a 39% reduction (p < 0.02) in complex I-specific activity relative to wild-type cybrid lines but normal activity for the other complexes. Kinetic analysis of the np 14459 mutant complex I revealed that the Vmax of the enzyme was reduced while the Km remained the same as that of wild type. Furthermore, specific activity was inhibited by increasing concentrations of the reduced coenzyme Q analog decylubiquinol. These observations suggest that the np 14459 mutation may alter the coenzyme Q-binding site of complex I.     

Lack of complex I activity in human cells carrying a mutation in MtDNA-encoded ND4 subunit is corrected by the Saccharomyces cerevisiae NADH-quinone oxidoreductase (NDI1) gene

The gene for the single subunit, rotenone-insensitive, and flavone-sensitive internal NADH-quinone oxidoreductase of Saccharomyces cerevisiae (NDI1) can completely restore the NADH dehydrogenase activity in mutant human cells that lack the essential mitochondrial DNA (mtDNA)-encoded subunit ND4. In particular, the NDI1 gene was introduced into the nuclear genome of the human 143B.TK(-) cell line derivative C4T, which carries a homoplasmic frameshift mutation in the ND4 gene. Two transformants with a low or high level of expression of the exogenous gene were chosen for a detailed analysis. In these cells the corresponding protein is localized in mitochondria, its NADH-binding site faces the matrix compartment as in yeast mitochondria, and in perfect correlation with its abundance restores partially or fully NADH-dependent respiration that is rotenone-insensitive, flavone-sensitive, and antimycin A-sensitive. Thus the yeast enzyme has become coupled to the downstream portion of the human respiratory chain. Furthermore, the P:O ratio with malate/glutamate-dependent respiration in the transformants is approximately two-thirds of that of the wild-type 143B.TK(-) cells, as expected from the lack of proton pumping activity in the yeast enzyme. Finally, whereas the original mutant cell line C4T fails to grow in medium containing galactose instead of glucose, the high NDI1-expressing transformant has a fully restored capacity to grow in galactose medium. The present observations substantially expand the potential of the yeast NDI1 gene for the therapy of mitochondrial diseases involving complex I deficiency.     

Lack of assembly of mitochondrial DNA-encoded subunits of respiratory NADH dehydrogenase and loss of enzyme activity in a human cell mutant lacking the mitochondrial ND4 gene product.

In most eukaryotic cells, the respiratory chain NADH dehydrogenase (Complex I) is a multimeric enzyme under dual (nuclear and mitochondrial) genetic control. Several genes encoding subunits of this enzyme have been identified in the mitochondrial genome from various organisms, but the functions of these subunits are in most part unknown. We describe here a human cell line in which the enzyme lacks the mtDNA-encoded subunit ND4 due to a frameshift mutation in the gene. In this cell line, the other mtDNA-encoded subunits fail to assemble, while at least some of the nuclear-encoded subunits involved in the redox reactions appear to be assembled normally. In fact, while there is a complete loss of NADH:Q1 oxidoreductase activity, the NADH:Fe(CN)6 oxidoreductase activity is normal. These observations provide the first clear evidence that the ND4 gene product is essential for Complex I activity and give some insights into the function and the structural relationship of this polypeptide to the rest of the enzyme. They are also significant for understanding the pathogenetic mechanism of the ND4 gene mutation associated with Leber's hereditary optic neuropathy.     

Does strong hypertrophic condition induce fast mitochondrial DNA mutation of rabbit heart?

Homo- and heteroplasmic mitochondrial DNA (mtDNA) mutations were observed and identified in an isoproterenol-induced rabbit model of cardiac hypertrophy. Genes encoding proteins essential for catalyzing mitochondrial electron transfer and for generating the proton motive force, such as NADH dehydrogenases (ND2, ND3, ND4, and ND6), cytochrome b, and ATPase 8, showed increased susceptibility for mutation. Specifically, five mutations caused amino acid changes and were located in Complex I and Complex V gene clusters. To our knowledge, this is the first demonstration of a relationship between cardiac hypertrophy induced by a strong sympathetic load and rapid mtDNA mutations.     

Restriction fragment length polymorphism (RFLP) analysis provides evidence for a high degree of homology of mitochondrial DNAs from rat hepatomasVersus normal rat livers

Where differences have been reported between tumor and normal mitochondrial DNA (mtDNA), they have generally involved limited modifications of the genome (Taira et al., Nucleic Acids Res. 11:1635, 1983; Shay and Werbin, Mutat. Res. 186:149, 1987). However, Corral et al. (Nucleic Acids Res. 16:10935, 1988; 17:5191, 1989) observed recombination between cytochrome oxidase subunit I (COI) and NADH dehydrogenase subunit 6 (ND6), two genes normally on opposite sides of the circular mitochondrial genome. In rat hepatoma mtDNA COI and ND6 were reported to be separated by only 230 base pairs (Corral et al., 1988, 1989). We have performed RFLP analysis on mtDNA from normal rat livers and rat hepatomas, using COI and ND6 probes. Additional experiments compared end-labeled DNA fragments produced by EcoRI and HindIII digestion of mtDNA. These studies failed to provide any evidence for genetic recombination in rat hepatoma mtDNA, even in the same cell line used by Corral et al. Rather, they support the conclusion that mtDNA from tumor and normal tissues exhibits a low degree of heterogeneity.     

A Novel Mitochondrial Heteroplasmic C13806A Point Mutation Associated with Iranian Friedreich’s Ataxia

Friedreich’s ataxia (FRDA) is an autosomal recessive neurodegenerative disorder caused by decreased expression of the protein Frataxin. Frataxin deficiency leads to excessive free radical production and dysfunction of chain complexes. Mitochondrial DNA (mtDNA) could be considered a candidate modifier factor for FRDA disease, since mitochondrial oxidative stress is thought to be involved in the pathogenesis of this disease. It prompted us to focus on the mtDNA and monitor the nucleotide changes of genome which are probably the cause of respiratory chain defects and reduced ATP generation. We searched about 46% of the entire mitochondrial genome by temporal temperature gradient gel electrophoresis (TTGE) and DNA fragments showing abnormal banding patterns were sequenced for the identification of exact mutations. In 18 patients, for the first time, we detected 26 mtDNA mutations; of which 5 (19.2%) was novel and 21 (80.8%) have been reported in other diseases. Heteroplasmic C13806A polymorphisms were associated with Iranian FRDA patients (55.5%). Our results showed that NADH dehydrogenase (ND) genes mutations in FRDA samples were higher than normal controls (P < 0.001) and we found statistically significant inverse correlation (r = −0.8) between number of mutation in ND genes and age of onset in FRDA patients. It is possible that mutations in ND genes could constitute a predisposing factor which in combination with environmental risk factors affects age of onset and disease progression.     

Mitochondrial respiratory dysfunction and mutations in mitochondrial DNA in PINK1 familial Parkinsonism

A summary is presented of the cellular function and topology of the protein products of genes whose mutations are associated with familial forms of Parkinsonism, with particular emphasis on mitochondrial involvement. Observations are reviewed which show mitochondrial respiratory depression in the fibroblasts of a patient affected by familial Parkinsomism associated with homozygous PINK1 mutation. The respiratory depression, which was due to loss of mitochondrial cytochrome c, was associated with decreased capacity of respiratory chain oxidative phosphorylation and enhanced cellular level of ROS. Sequence analysis of the overall mtDNA revealed coexistence with the PINK1 mutation of homoplasmic point mutations in the ND5 and ND6 genes of complex I. The presence of these mutations appears to have an impact on the development of the Parkinsonism, which can also occur in the heterozygous PINK1 mutation state.