Molecular Genetics of the Mammalian NADH–Ubiquinone Oxidoreductase

A serendipitous observation led to the first characterization of a respiration-deficient Chinese hamster mutant cell line. It has guided the design of an enrichment scheme for the isolation of additional mutant cell lines. Several complementation groups were identified with mutations affecting complex I. The X-linked NDUFA1 gene encoding the MWFE protein represents one group. Several mutant alleles isolated independently are described that yield very low activities and demonstrate that the MWFE protein is essential for activity. A phylogenetic sequence analysis of this highly conserved protein has directed attention to species-specific differences that make the primate MWFE protein inactive in hamster cells. Based on such comparisons, mutant alleles made by site-directed mutagenesis were expressed in a null mutant and reduced complex I activities were observed, with the mutant protein assembled into the complex. These and other mutants promise to be valuable for structure–function analyses, especially in conjunction with a high-resolution structure to be expected in the future. The possibility for transgenic and knock-in mice as models for mitochondrial diseases is being explored.     

Import and orientation of the MWFE protein in mitochondrial NADH-ubiquinone oxidoreductase

The MWFE subunit of the mitochondrial NADH-ubiquinone oxidoreductase (complex I) is a small, essential membrane protein of 70 amino acids that is made in the cytosol, imported into mitochondria, and assembled without further proteolytic processing. The experiments identify the first approximately 30 amino acids as a minimal mitochondrial targeting sequence, and establish its orientation in the inner membrane and in complex I. This sequence has a highly conserved glutamate at position 4, which is not typical of a mitochondrial targeting signal. However, it is not essential for MWFE function. Within this sequence there is also a 'stop-transfer' signal. The membrane anchor cannot be replaced by that from another subunit within complex I.     

Development and characterization of a conditional mitochondrial complex I assembly system

We developed a conditional complex I assembly system in a Chinese hamster fibroblast mutant line, CCL16-B2, that does not express the NDUFA1 gene (encoding the MWFE protein). In this mutant, a hemagglutinin (HA) epitope-tagged MWFE protein was expressed from a doxycycline-inducible promoter. The expression of the protein was absolutely dependent on the presence of doxycycline, and the gene could be turned off completely by removal of doxycycline. These experiments demonstrated a key role of MWFE in the pathway of complex I assembly. Upon induction the MWFE.HA protein reached steady-state levels within 24 h, but the appearance of fully active complex I was delayed by another approximately 24 h. The MWFE appeared in a precomplex that probably includes one or more subunits encoded by mtDNA. The fate of MWFE and the stability of complex I were themselves very tightly linked to the activity of mitochondrial protein synthesis and to the assembly of subunits encoded by mtDNA (ND1-6 and ND4L). This novel conditional system can shed light not only on the mechanism of complex I assembly but emphasizes the role of subunits previously thought of as "accessory." It promises to have broader applications in the study of cellular energy metabolism and production of reactive oxygen species and related processes.     

The 9.8 kDa subunit of complex I,related to bacterial Na(+)-translocating NADH dehydrogenases,is required for enzyme assembly and function in Neurospora crassa

A nuclear gene encoding a 9.8 kDa subunit of complex I, the homologue of mammalian MWFE protein, was identified in the genome of Neurospora crassa. The gene was cloned and inactivated in vivo by the generation of repeat-induced point mutations. Fungal mutant strains lacking the 9.8 kDa polypeptide were subsequently isolated. Analyses of mitochondrial proteins from mutant nuo9.8 indicate that the membrane and peripheral arms of complex I fail to assemble. Respiration of mutant mitochondria on matrix NADH is rotenone-insensitive, confirming that the 9.8 kDa protein is required for the assembly and activity of complex I. We found a similarity between the MWFE homologues and the C-terminal part of the nqrA subunit of bacterial Na(+)-translocating NADH:quinone oxidoreductases (Na(+)-NQR), suggesting a link between proton-pumping and sodium-pumping NADH dehydrogenases.     

The phosphorylation of subunits of complex I from bovine heart mitochondria

In bovine heart mitochondria and in submitochondrial particles, membrane-associated proteins with apparent molecular masses of 18 and 10 kDa become strongly radiolabeled by [(32)P]ATP in a cAMP-dependent manner. The 18-kDa phosphorylated protein is subunit ESSS from complex I and not as previously reported the 18 k subunit (with the N-terminal sequence AQDQ). The phosphorylated residue in subunit ESSS is serine 20. In the 10 kDa band, the complex I subunit MWFE was phosphorylated on serine 55. In the presence of protein kinase A and cAMP, the same subunits of purified complex I were phosphorylated by [(32)P]ATP at the same sites. Subunits ESSS and MWFE both contribute to the membrane arm of complex I. Each has a single hydrophobic region probably folded into a membrane spanning alpha-helix. It is likely that the phosphorylation site of subunit ESSS lies in the mitochondrial matrix and that the site in subunit MWFE is in the intermembrane space. Subunit ESSS has no known role, but subunit MWFE is required for assembly into complex I of seven hydrophobic subunits encoded in the mitochondrial genome. The possible effects of phosphorylation of these subunits on the activity and/or the assembly of complex I remain to be explored.     

Investigations of the potential effects of phosphorylation of the MWFE and ESSS subunits on complex I activity and assembly

There have been several reports on the phosphorylation of various subunits of NADH-ubiquinone oxidoreductase (complex I) in mammalian mitochondria. The effects of phosphorylation on assembly or activity of these subunits have not been investigated directly. The cAMP-dependent phosphorylation of the MWFE and ESSS subunits in isolated bovine heart mitochondria has been recently reported. We have investigated the significance of potential phosphorylation of these two subunits in complex I assembly and function by mutational analysis of the phosphorylation sites. Chinese hamster mutant cell lines missing either the MWFE or the ESSS subunits were transfected and complemented with the corresponding wild type and mutant cDNAs made by site-directed mutagenesis. In MWFE the serine 55 was substituted by alanine, glutamate, glutamine, and aspartate (S55A, S55E, S55Q, and S55D, respectively). The glutamate substitutions might be expected to mimic the phosphorylated state of the protein. With the exception of the MWFE(S55A) mutant protein the assembly of complex I was completely blocked, and no activity could be detected. Various substitutions in the ESSS protein (S2A, S2E, S8A, S8E, T21A, T21E, S30A, S30E) appeared to cause lower levels of mature protein and a significantly reduced complex I activity measured polarographically. The ESSS (S2/8A) double mutant protein caused a complete failure to assemble. These mutational analyses suggest that if phosphorylation occurs in vivo, the effects on complex I activity are significant.     

The role of the ESSS protein in the assembly of a functional and stable mammalian mitochondrial complex I (NADH-ubiquinone oxidoreductase).

The ESSS protein is a recently identified subunit of mammalian mitochondrial complex I. It is a relatively small integral membrane protein (122 amino acids) found in the beta-subcomplex. Genomic sequence database searches reveal its localization to the X-chromosome in humans and mouse. The ESSS cDNA from Chinese hamster cells was cloned and shown to complement one complementation group of our previously described mutants with a proposed X-linkage. Sequence analyses of the ESSS cDNA in these mutants revealed chain termination mutations. In two of these mutants the protein is truncated at the C-terminus of the targeting sequence; the mutants are null mutants for the ESSS subunit. There is no detectable complex I assembly and activity in the absence of the ESSS subunit as revealed by blue native polyacrylamide gel electrophoresis (BN/PAGE) analysis and polarography. Complex I activity can be restored with ESSS subunits tagged with either hemagglutinin (HA) or hexahistidine (His6) epitopes at the C-terminus. Although, the accumulation of ESSS-HA is not dependent upon the presence of mtDNA-encoded subunits (ND1-6,4 L), it is incorporated into complex I only in presence of compatible complex I subunits from the same species.     

Molecular genetics of complex I-deficient Chinese hamster cell lines

The work from our laboratory on complex I-deficient Chinese hamster cell mutants is reviewed. Several complementation groups with a complete defect have been identified. Three of these are due to X-linked mutations, and the mutated genes for two have been identified. We describe null mutants in the genes for the subunits MWFE (gene: NDUFA1) and ESSS. They represent small integral membrane proteins localized in the Ialpha (Igamma) and Ibeta subcomplexes, respectively [J. Hirst, J. Carroll, I.M. Fearnley, R.J. Shannon, J.E. Walker. The nuclear encoded subunits of complex I from bovine heart mitochondria. Biochim. Biophys. Acta 1604 (7-10-2003) 135-150.]. Both are absolutely essential for assembly and activity of complex I. Epitope-tagged versions of these proteins can be expressed from a poly-cistronic vector to complement the mutants, or to be co-expressed with the endogenous proteins in other hamster cell lines (mutant or wild type), or human cells. Structure-function analyses can be performed with proteins altered by site-directed mutagenesis. A cell line has been constructed in which the MWFE subunit is conditionally expressed, opening a window on the kinetics of assembly of complex I. Its targeting, import into mitochondria, and orientation in the inner membrane have also been investigated. The two proteins have recently been shown to be the targets for a cAMP-dependent kinase [R. Chen, I.M. Fearnley, S.Y. Peak_Chew, J.E. Walker. The phosphorylation of subunits of complex I from bovine heart mitochondria. J. Biol. Chem. xx (2004) xx-xx.]. The epitope-tagged proteins can be cross-linked with other complex I subunits.     

Mutants of Chlamydomonas reinhardtii deficient in mitochondrial complex I: characterization of two mutations affecting the nd1 coding sequence.

The mitochondrial rotenone-sensitive NADH:ubiquinone oxidoreductase (complex I) comprises more than 30 subunits, the majority of which are encoded by the nucleus. In Chlamydomonas reinhardtii, only five components of complex I are coded for by mitochondrial genes. Three mutants deprived of complex I activity and displaying slow growth in the dark were isolated after mutagenic treatment with acriflavine. A genetical analysis demonstrated that two mutations (dum20 and dum25) affect the mitochondrial genome whereas the third mutation (dn26) is of nuclear origin. Recombinational analyses showed that dum20 and dum25 are closely linked on the genetic map of the mitochondrial genome and could affect the nd1 gene. A sequencing analysis confirmed this conclusion: dum20 is a deletion of one T at codon 243 of nd1; dum25 corresponds to a 6-bp deletion that eliminates two amino acids located in a very conserved hydrophilic segment of the protein.     

Mitochondrial ND5 mutations in idiopathic Parkinson's disease

Idiopathic Parkinson's disease (PD) is characterized by a systemic loss of activity of complex I (NADH:ubiquinone oxidoreductase), the target enzyme of the parkinsonism producing neurotoxin, MPTP. Cybrid experiments strongly suggest that the loss of complex I activity arises from mitochondrial DNA. We prospectively evaluated low frequency, amino acid changing, heteroplasmic mutations in a narrow region of ND5, a mitochondrial gene encoding a complex I subunit, in brain tissue from PD and controls. The presence or absence of amino acid changing mutations correctly classified 15 of 16 samples. Heteroplasmic mutations in a specific region of ND5 largely segregate PD from controls and may be of major pathogenic importance in idiopathic PD.     

Biogenesis of mitochondria: DNA sequence analysis of mit- mutations in the mitochondrial oli1 gene coding for mitochondrial ATPase subunit 9 in Saccharomyces cerevisiae.

The nucleotide sequence of the yeast mitochondrial olil gene has been obtained in a series of mit- mutants with mutations in this gene, which codes for subunit 9 of of the mitochondrial ATPase complex. Subunit 9 is the proteolipid, 76 amino acids in length, necessary for the proton translocation function of the membrane Fo-sector. These mutants were classified on the basis of their rescue by a petite strain shown here to retain the entire wild-type olil gene. The mutation in one mit- strain removes a positively charged residue (Arg39----Met) which is likely to be located in a segment of subunit 9 that protrudes from the inner mitochondrial membrane. In a second mit- mutant, a negatively charged residue replaces a conserved glycine residue (Gly18----Asp) in a glycine-rich segment of the protein that is most likely embedded within the membrane. Other mit- mutations result in frameshifts with predicted products 7, 65 and 68 amino acid residues long. In each mit- mutant, there is the loss of one or more of the amino acid residues that are highly conserved among diverse species. The location and nature of specific changes pinpoint amino acid residues in subunit 9 essential to the activity of the mitochondrial ATPase complex.     

Mitochondrial dysfunction impairs tumor suppressor p53 expression/function

Recently, mitochondria have been suggested to act in tumor suppression. However, the underlying mechanisms by which mitochondria suppress tumorigenesis are far from being clear. In this study, we have investigated the link between mitochondrial dysfunction and the tumor suppressor protein p53 using a set of respiration-deficient (Res(-)) mammalian cell mutants with impaired assembly of the oxidative phosphorylation machinery. Our data suggest that normal mitochondrial function is required for γ-irradiation (γIR)-induced cell death, which is mainly a p53-dependent process. The Res(-) cells are protected against γIR-induced cell death due to impaired p53 expression/function. We find that the loss of complex I biogenesis in the absence of the MWFE subunit reduces the steady-state level of the p53 protein, although there is no effect on the p53 protein level in the absence of the ESSS subunit that is also essential for complex I assembly. The p53 protein level was also reduced to undetectable levels in Res(-) cells with severely impaired mitochondrial protein synthesis. This suggests that p53 protein expression is differentially regulated depending upon the type of electron transport chain/respiratory chain deficiency. Moreover, irrespective of the differences in the p53 protein expression profile, γIR-induced p53 activity is compromised in all Res(-) cells. Using two different conditional systems for complex I assembly, we also show that the effect of mitochondrial dysfunction on p53 expression/function is a reversible phenomenon. We believe that these findings will have major implications in the understanding of cancer development and therapy.     

Mitochondrial NADH-ubiquinone reductase: complementary DNA sequences of import precursors of the bovine and human 24-kDa subunit

The 24-kDa subunit of mitochondrial NADH-ubiquinone reductase (complex I) is an iron-sulfur protein that is present in the flavoprotein or NADH dehydrogenase II subcomplex. It is a nuclear gene product and is imported into the organelle. A group of human patients with mitochondrial myopathy have been shown to have reduced levels of subunits of complex I in skeletal muscle mitochondria, and in one patient the 24-kDa subunit appears to be absent (Schapira et al., 1988). To investigate the genetic basis of this type of myopathy, cDNA clones have been isolated from a bovine library derived from heart and liver mRNA by hybridization with two mixtures of 48 synthetic oligonucleotides 17 bases in length that were designed on the basis of known protein sequences. The recombinant DNA sequence has been determined, and it encodes a precursor of the mature 24-kDa protein. The N terminus of the mature protein is preceded by a presequence of 32 amino acids that has properties that are characteristic of mitochondrial import sequences. The sequence of the mature protein deduced from the cDNA contains a segment of nine amino acids that was not determined in an earlier partial protein sequence analysis. The bovine clone has been employed as a hybridization probe to identify cDNA clones of the human homologue of the 24-kDa protein. Its DNA sequence has also been determined, and it codes for a protein that is closely related to the bovine protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

A single amino acid change in the Newcastle disease virus fusion protein alters the requirement for HN protein in fusion

The role of a leucine heptad repeat motif between amino acids 268 and 289 in the structure and function of the Newcastle disease virus (NDV) F protein was explored by introducing single point mutations into the F gene cDNA. The mutations affected either folding of the protein or the fusion activity of the protein. Two mutations, L275A and L282A, likely interfered with folding of the molecule since these proteins were not proteolytically cleaved, were minimally expressed at the cell surface, and formed aggregates. L268A mutant protein was cleaved and expressed at the cell surface although the protein migrated slightly slower than wild type on polyacrylamide gels, suggesting an alteration in conformation or processing. L268A protein was fusion inactive in the presence or absence of HN protein expression. Mutant L289A protein was expressed at the cell surface and proteolytically cleaved at better than wild-type levels. Most importantly, this protein mediated syncytium formation in the absence of HN protein expression although HN protein enhanced fusion activity. These results show that a single amino acid change in the F(1) portion of the NDV F protein can alter the stringent requirement for HN protein expression in syncytium formation.     

The 30-kilodalton subunit of bovine mitochondrial complex I is homologous to a protein coded in chloroplast DNA

In cattle, 7 of the 30 or more subunits of the respiratory enzyme NADH:ubiquinone reductase (complex I) are encoded in mitochondrial DNA, and potential genes (open reading frames, orfs) for related proteins are found in the chloroplast genomes of Marchantia polymorpha and Nicotiana tabacum. Homologues of the nuclear-coded 49- and 23-kDa subunits are also coded in chloroplast DNA, and these orfs are clustered with four of the homologues of the mammalian mitochondrial genes. These findings have been taken to indicate that chloroplasts contain a relative of complex I. The present work provides further support. The 30-kDa subunit of the bovine enzyme is a component of the iron-sulfur protein fraction. Partial protein sequences have been determined, and synthetic oligonucleotide mixtures based on them have been employed as hybridization probes to identify cognate cDNA clones from a bovine library. Their sequences encode the mitochondrial import precursor of the 30-kDa subunit. The mature protein of 228 amino acids contains a segment of 57 amino acids which is closely related to parts of proteins encoded in orfs 169 and 158 in the chloroplast genomes of M. polymorpha and N. tabacum. Moreover, the chloroplast orfs are found near homologues of the mammalian mitochondrial genes for subunit ND3. Therefore, the plant chloroplast genomes have at least two separate clusters of potential genes encoding homologues of subunits of mitochondrial complex I. The bovine 30-kDa subunit has no extensive sequences of hydrophobic amino acids that could be folded into membrane-spanning alpha-helices, and although it contains two cysteine residues, there is no clear evidence in the sequence that it is an iron-sulfur protein.     

Selective synthesis of mitochondrial proteins by Chinese hamster ovary cells severely starved for various amino acids

Chinese hamster ovary (CHO) cells were subjected to severe amino acid starvation for histidine, leucine, methionine, asparagine, tyrosine, glutamine, valine, and lysine, using amino acid analogs or mutations in specific aminoacyl-tRNA synthetases. At protein synthetic rates of less than 5%, in all cases, the newly synthesized proteins were found on two- dimensional electrophoretic gels to consist of a few intensely labeled spots, with the exception of lysine. This pattern could also be produced by strong inhibition of cytoplasmic protein synthesis with cycloheximide, and was abolished by preincubation with the mitochondrial protein synthesis inhibitor chloramphenicol. It appears therefore that the spots represent mitochondrial protein synthesis and that animal cells must have separate aminoacyl-tRNA synthetases for mitochondrial tRNAs corresponding to all these amino acids except, possibly, for lysine.     

Functional importance of the conserved N-terminal domain of the mitochondrial replicative DNA helicase

The mitochondrial replicative DNA helicase is an essential cellular protein that shows high similarity with the bifunctional primase-helicase of bacteriophage T7, the gene 4 protein (T7 gp4). The N-terminal primase domain of T7 gp4 comprises seven conserved sequence motifs, I, II, III, IV, V, VI, and an RNA polymerase basic domain. The putative primase domain of metazoan mitochondrial DNA helicases has diverged from T7 gp4 and in particular, the primase domain of vertebrates lacks motif I, which comprises a zinc binding domain. Interestingly, motif I is conserved in insect mtDNA helicases. Here, we evaluate the effects of overexpression in Drosophila cell culture of variants carrying mutations in conserved amino acids in the N-terminal region, including the zinc binding domain. Overexpression of alanine substitution mutants of conserved amino acids in motifs I, IV, V and VI and the RNA polymerase basic domain results in increased mtDNA copy number as is observed with overexpression of the wild type enzyme. In contrast, overexpression of three N-terminal mutants W282L, R301Q and P302L that are analogous to human autosomal dominant progressive external ophthalmoplegia mutations results in mitochondrial DNA depletion, and in the case of R301Q, a dominant negative cellular phenotype. Thus whereas our data suggest lack of a DNA primase activity in Drosophila mitochondrial DNA helicase, they show that specific N-terminal amino acid residues that map close to the central linker region likely play a physiological role in the C-terminal helicase function of the protein.     

Identification of conserved amino acid residues critical for human immunodeficiency virus type 1 integrase function in vitro.

We have probed the structural organization of the human immunodeficiency virus type 1 integrase protein by limited proteolysis and the functional organization by site-directed mutagenesis of selected amino acid residues. A central region of the protein was relatively resistant to proteolysis. Proteins with altered amino acids in this region, or in the N-terminal part of the protein that includes a putative zinc-binding motif, were purified and assayed for 3' processing, DNA strand transfer, and disintegration activities in vitro. In general, these mutations had parallel effects on 3' processing and DNA strand transfer, suggesting that integrase may utilize a single active site for both reactions. The only proteins that were completely inactive in all three assays contained mutations at conserved amino acids in the central region, suggesting that this part of the protein may be involved in catalysis. In contrast, none of the mutations in the N-terminal region resulted in a protein that was inactive in all three assays, suggesting that this part of integrase may not be essential for catalysis. The disintegration reaction was particularly insensitive to these amino acid substitutions, indicating that some function that is important for 3' processing and DNA strand transfer may be dispensable for disintegration.     

Histidine-49 is necessary for the pH-dependent transition between active and inactive states of the bovine F1-ATPase inhibitor protein

The role of the histidyl residue at position 49 (H49) of the bovine mitochondrial F₁-ATPase inhibitor protein (F₁I) was examined by site-directed mutagenesis. Six amino acids (Q, E, K, V, L, and I) were substituted for H49 and the activities of the resulting inhibitor proteins were characterized with respect to pH. Each of the six mutations abolished the pH sensitivity which is characteristic of wild-type F₁I. At pH 8.0, each of the mutations caused an increase in apparent maximum inhibition and a decrease in apparent K_i relative to wild type. At pH 6.7 the hydrophilic substitutions had little effect on apparent K_i, while the hydrophobic substitutions caused increases of 3.5- to 8.5-fold relative to wild type. The ratios of apparent K_i at pH 8.0 to apparent K_i at pH 6.7 were in the range of 0.5 to 1.6 for the mutants, whereas the wild-type value is 15.0. The mutations appear to shift the equilibrium between active and inactive conformations of F₁I toward the active state. We find that H49 is required by F₁I for sensitivity to pH and that it may facilitate the transition between active and inactive states of F₁I. A possible role for H49 in the stabilization of the inactive state through participation in a multivalent complex with Zn²⁺ is also discussed.