Assembly of mitochondrial ATP synthase in cultured human cells: implications for mitochondrial diseases

Nijtmans, Leo; Klement, Petr; Houštěk, Josef; Bogert, Coby Van den

doi:10.1016/0925-4439(95)00087-9

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

1995

DOI: 10.1016/0925-4439(95)00087-9

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Assembly of mitochondrial ATP synthase in cultured human cells: implications for mitochondrial diseases

Leo Nijtmans

Petr Klement

Josef Houštěk

et al.

Abstract: To study the assembly of mitochondrial F1F0 ATP synthase, cultured human cells were labeled with [35S]methionine in pulse-chase experiments. Next, two-dimensional electrophoresis and fluorography were used to analyze the assembly pattern. Two assembly intermediates could be demonstrated. First the F1 part appeared to be assembled, and next an intermediate product that contained F1 and subunit c. This product probably also contained subunits b, F6 and OSCP, but not the mitochondrially encoded subunits a and A6L… Show more

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Cited by 81 publications

(62 citation statements)

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“…Assembly of the 13 subunits of cytochrome-c oxidase starts with the association of subunit I with subunit IV. Then a larger subcomplex is formed, lacking only subunits VIa and either VIIa or VIIb.Keywords : cytochrome-c oxidase; assembly; respiratory chain ; cultured human cell.Cytochrome-c oxidase (COX) is the terminal enzyme of the in a stable intermediate complex made up solely of nuclear-encoded subunits [10,11]. respiratory chain located in the inner mitochondrial membrane.…”

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“…Cytochrome-c oxidase (COX) is the terminal enzyme of the in a stable intermediate complex made up solely of nuclear-encoded subunits [10,11]. respiratory chain located in the inner mitochondrial membrane.…”

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confidence: 99%

“…Western blotting was performed as described [11], and blots methionine-free medium, [ 35 S]methionine (specific activity were developed with monoclonal antibodies [16] against COX I Ͼ 960 Ci/mmol) was added to 20 µCi/ml, at a cell density of 10 6 (1D6-E1-A8), COX II (12C4-F12) or COX IV (10G8-D12-cells/ml. After 1 h, cells were washed twice with NaCl/P i and C12).…”

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confidence: 99%

“…After transfer to nitrocellulose membrane, the proteins were probed with a variety of COX antibodies. Four [11]. We used a similar approach in the present study to obtain more information on COX subcomplexes.…”

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Assembly of cytochrome‐c oxidase in cultured human cells

Nijtmans

Taanman

Muijsers

et al. 1998

European Journal of Biochemistry

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222

213

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The assembly of cytochrome-c oxidase was studied in human cells cultured in the presence of inhibitors of mitochondrial or cytosolic protein synthesis. Mitochondrial fractions were resolved using twodimensional PAGE (blue native PAGE and tricine/SDS/PAGE) and subsequent western blots were developed with monoclonal antibodies against specific subunits of cytochrome-c oxidase. Proteins were also visualized using metabolic labeling followed by two-dimensional electrophoresis and fluorography. These techniques allowed identification of two assembly intermediates of cytochrome-c oxidase. Assembly of the 13 subunits of cytochrome-c oxidase starts with the association of subunit I with subunit IV. Then a larger subcomplex is formed, lacking only subunits VIa and either VIIa or VIIb.Keywords : cytochrome-c oxidase; assembly; respiratory chain ; cultured human cell.Cytochrome-c oxidase (COX) is the terminal enzyme of the in a stable intermediate complex made up solely of nuclear-encoded subunits [10,11]. respiratory chain located in the inner mitochondrial membrane. The enzyme complex catalyses the oxidation of cytochrome c Basic questions regarding the assembly of COX remain to be resolved. What is the order of assembly of the subunits? How by molecular oxygen; the energy released in this reaction is used to translocate protons across the inner mitochondrial membrane. is assembly regulated and what are the rate-limiting steps? Answers to these questions are not only important to understand The proton gradient resulting from the activity of the different respiratory-chain complexes is used to drive ATP synthesis. the function and regulation of the enzyme, but they will also provide information on causes of COX deficiency in patients. Mammalian COX contains 13 subunits, three of which (COX I, II and III) are encoded by the mitochondrial genome, while the Most investigations of the assembly pathway of COX employed metabolic labeling followed by immunoprecipitation [8Ϫ remaining ten subunits (COX IV, Va, Vb, VIa, VIb, VIc, VIIa, VIIb, VIIc and VIII) are nuclear-encoded [1Ϫ5].10, 12]. This approach may give erroneous results because there are differences in epitope availability in partially assembled The recent resolution of bovine heart COX by X-ray analysis [6, 7] not only revealed the exact topology of its subunits, but complexes or because there is selective loss of subunits during immunoprecipitation. We have used two-dimensional electroalso assists studies aimed at clarifying the reaction mechanism of the enzyme. Moreover, the quarternary structure of the com-phoresis in combination with translational inhibitors and metabolic labeling to analyze COX assembly. Two assembly intermeplex puts certain structural constraints on models regarding the assembly pathway of COX. To resolve the assembly process of diates could be detected. the enzyme, however, additional experimental approaches are required. Previous studies of the assembly pathway of COX have shown that pools of unassembled subunits exist and that EXPERIMENTAL PR...

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confidence: 99%

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Assembly of cytochrome‐c oxidase in cultured human cells

Nijtmans

Taanman

Muijsers

et al. 1998

European Journal of Biochemistry

Self Cite

222

213

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“…Structural protein defects of the subunit a, which is encoded by the mitochondrial gene ATP6, have been shown to result in incomplete assembly of the complex V holoenzyme. This is known from studies in tissues and cultured cells with the mutation T8993G (10,30), associated with NARP disease but also from rho 0 cells, which lack mitochondrial DNA (31) as well as cells with inhibited mitochondrial protein synthesis (32), where increased content of unassembled or released F 1 of 390 kD and accumulation of atypical ATPase subcomplex of 460 kD was found (10,30). In the case of our patient, as detected by BN-PAGE and Western blots of solubilized OX-PHOS complexes, possibly some amount of F 1 -like intermediate could be present.…”

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Reduced Respiratory Control with ADP and Changed Pattern of Respiratory Chain Enzymes as a Result of Selective Deficiency of the Mitochondrial ATP Synthase

Mayr¹,

Paul

Pecina

et al. 2004

Pediatr Res

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The F o F 1 -ATPase, a multisubunit protein complex of the inner mitochondrial membrane, produces most of the ATP in mammalian cells. Mitochondrial diseases as a result of a dysfunction of ATPase can be caused by mutations in mitochondrial DNA-encoded ATPase subunit a or rarely by an ATPase defect of nuclear origin. Here we present a detailed functional and immunochemical analysis of a new case of selective and generalized ATPase deficiency found in an Austrian patient. The defect manifested with developmental delay, muscle hypotonia, failure to thrive, ptosis, and varying lactic acidemia (up to 12 mmol/L) beginning from the neonatal period. A low-degree dilated cardiomyopathy of the left ventricle developed between the age of 1 and 2 y. A Ͼ90% decrease in oligomycin-sensitive ATPase activity and an 86% decrease in the content of the ATPase complex was found in muscle mitochondria. It was associated with a significant decrease of ADP-stimulated respiration of succinate (1.5-fold) and respiratory control with ADP (1.7-fold) in permeabilized muscle fibers, and with a slight decrease of the respiratory chain complex I and compensatory increase in the content of complexes III and IV. The same ATPase deficiency without an increase in respiratory chain complexes was found in fibroblasts, suggesting a generalized defect with tissue-specific manifestation. Absence of any mutations in mitochondrial ATP6 and ATP8 genes indicates a nuclear origin of the defect. Mitochondrial disorders caused by impairment of mitochondrial oxidative phosphorylation (OXPHOS) affect predominantly tissues with high-energy demands: muscle, brain, and heart. Subunits of OXPHOS complexes are encoded in two separate genomes: nuclear and mitochondrial. A pathogenic mutation in both genomes can cause an OX-PHOS defect. Defects in complex V-mitochondrial F o F 1 -ATPase are less frequent than the defects of the respiratory chain complexes, but they are mostly very severe and can be caused by mitochondrial DNA (mtDNA) mutations or by mutations in nuclear genes.Mitochondrial ATPase is a multisubunit complex composed of 16 different subunits (1). Six of these compose the globular F 1 part, which is responsible for enzymatic catalysis of ATP synthesis or hydrolysis. Ten remaining subunits form the membrane-spanning F o part, which performs H ϩ translocation across the inner mitochondrial membrane. Four subunits of F o form stalks that connect F 1 and F o parts. Only two subunits from F o part are encoded by mitochondrial genome: subunits a and A6L (subunits 6 and 8) (2). All of the other 14 subunits of the ATPase are encoded by the nuclear genes.Specific defects in mitochondrial ATPase are caused mainly by mtDNA mutations that affect subunit a; no mutations in subunit A6L have been described so far. The most frequent mutation in subunit a is T8993G mutation (3-7) or T8993C mutation (8)

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High throughput two-dimensional blue-native electrophoresis: A tool for functional proteomics of mitochondria and signaling complexes

Brookes¹,

Pinner²,

Ramachandran³

et al. 2002

Proteomics

154

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The recent upsurge in proteomics research has been facilitated largely by streamlining of two-dimensional (2-D) gel technology and the parallel development of facile mass spectrometry for analysis of peptides and proteins. However, application of these technologies to the mitochondrial proteome has been limited due to the considerable complement of hydrophobic membrane proteins in mitochondria, which precipitate during first dimension isoelectric focusing of standard 2-D gels. In addition, functional information regarding protein:protein interactions is lost during 2-D gel separation due to denaturing conditions in both gel dimensions. To resolve these issues, 2-D blue-native gel electrophoresis was applied to the mitochondrial proteome. In this technique, membrane protein complexes such as those of the respiratory chain are solubilized and resolved in native form in the first dimension. A second dimension sodium dodecyl sulfate-polyacrylamide gel electrophoresis gel then denatures the complexes and resolves them into their component subunits. Refinements to this technique have yielded the levels of throughput and reproducibility required for proteomics. By coupling to tryptic peptide fingerprinting using matrix-assisted laser desorption/ionization-time of flight mass spectrometry, a partial mitochondrial proteome map has been assembled. Applications of this functional mitochondrial proteomics method are discussed.

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Assembly of mitochondrial ATP synthase in cultured human cells: implications for mitochondrial diseases

Cited by 81 publications

References 27 publications

Assembly of cytochrome‐c oxidase in cultured human cells

Assembly of cytochrome‐c oxidase in cultured human cells

Reduced Respiratory Control with ADP and Changed Pattern of Respiratory Chain Enzymes as a Result of Selective Deficiency of the Mitochondrial ATP Synthase

High throughput two-dimensional blue-native electrophoresis: A tool for functional proteomics of mitochondria and signaling complexes

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