EC:3.6.3.14 - FACTA Search

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Query: EC:3.6.3.14 (ATP synthase)
7,042 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The single sulfhydryl residue (cysteine-63) of the beta subunit of the chloroplast ATP synthase F1 (CF1) was accessible to labeling reagents only after removal of the beta subunit from the enzyme complex. This suggests that cysteine-63 may be located at an interface between the beta and the alpha subunits of CF1, although alternative explanations such as a conformational change in beta brought about by its release from CF1 cannot be ruled out. Cysteine-63 was specifically labeled with [(diethylamino)methylcoumarinyl]-maleimide, and the distance between this site and trinitrophenyl-ADP at the nucleotide binding site on beta was mapped using fluorescence resonance energy transfer. Cysteine-63 is located in a hydrophobic pocket, 42 A away from the nucleotide binding site on beta.
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PMID:Structural mapping of cysteine-63 of the chloroplast ATP synthase beta subunit. 153 53

Immunochemical studies demonstrated the specific accumulation of subunit c of mitochondrial ATP synthase in the brain homogenates of late infantile and juvenile forms of Batten's disease. It is not stored in the infantile form. Storage of subunit alpha of mitochondrial ATP synthase and cytochrome c oxidase subunit IV, an inner membrane protein of mitochondria was not detected in the brains. There was also no difference in the levels of cathepsin B between the two forms of Batten's disease and controls. In cultured skin fibroblasts subunit c accumulates in the late infantile form, whereas it does not in other lysosomal storage diseases. Crude mitochondrial lysosomal preparations of control fibroblasts were separated into high-density fractions rich in a lysosomal marker and low-density fractions rich in a mitochondrial marker on Percoll density gradients. Subunit c was mostly recovered in low-density mitochondrial fractions, but in cells from the late infantile disease a part of subunit c was recovered in the high-density lysosomal fractions. Immunolocalization studies demonstrated a dot-like staining of storage materials for subunit c in the cells from late infantile patients and the staining pattern of subunit c is similar to that of a lysosomal membrane marker, lgp120. Immunostaining failed to detect subunit c in control cells. These results indicate a specific accumulation of subunit c in lysosomes, and suggest that the two forms of Batten's disease are caused by a specific failure in the degradation of subunit c.
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PMID:Specific storage of subunit c of mitochondrial ATP synthase in lysosomes of neuronal ceroid lipofuscinosis (Batten's disease). 153 18

We have investigated the biophysical properties of a 35 amino acid peptide representing the entire length of a chloroplastic targeting sequence. The peptide, termed gamma-tp, corresponds in sequence to the transit peptide of the gamma subunit of the chloroplast ATP synthase from Chlamydomonas reinhardtii. We found that gamma-tp blocks the import of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase into isolated pea chloroplasts (KI approximately 5 microM), suggesting that it interacts with higher plant plastids in a physiological manner. We also found the gamma-tp to have a high affinity for nonpolar environments, but not to cause a general disruption of membrane integrity. Hydrophobic moment analysis suggests that the gamma-tp can adopt an amphipathic beta structure. However, circular dichroism measurements indicate that the peptide is largely a random coil, in both the presence and absence of sodium laurylsulfate micelles. In the absence of a recognizable secondary structural targeting motif, we asked whether the presence of a transit peptide on a chloroplast protein increases the protein's overall affinity for nonpolar environments. Phase-partition experiments with Triton X-114 suggest that this is not the case. These results are discussed in relation to the mechanism of protein targeting to chloroplasts.
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PMID:Biophysical characterization of a transit peptide directing chloroplast protein import. 153 91

(1) Previous mutational analyses have shown that residue beta R398 of the beta-subunit is a key residue for binding of the inhibitory antibiotic aurovertin to Escherichia coli F1Fo-ATP synthase. Here, we studied purified F1 from the beta R398C and beta R398W mutants. ATPase activity in both cases was resistant to aurovertin inhibition. The fluorescence spectrum (lambda exc = 278 or 295 nm) of beta R398W F1 showed a significant red-shift as compared to wild-type and beta R398C enzymes, indicating that residue beta R398 lies in a polar environment. On the basis of this and previous evidence, we propose that aurovertin binding to F1-ATPase involves a specific charged donor-acceptor H-bond between residue beta R398 and the 7-hydroxyl group of aurovertin. (2) The fluorescent substrate analog lin-benzo-ADP was shown to bind to beta R398W F1 catalytic sites with the same Kd values as to wild-type F1, and with the same quenching of the fluorescence of the analog. Fluorescence energy transfer was seen between the beta R398W residue and bound lin-benzo-ADP. Analysis of transfer efficiency at varying stoichiometry of bound lin-benzo-ADP showed that interaction occurred between one beta R398W residue and one catalytic-site-bound analog molecule at a distance of approximately 23 A. The relationships of the aurovertin and catalytic sites in the primary and tertiary structure are discussed.
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PMID:Investigation of the aurovertin binding site of Escherichia coli F1-ATPase by fluorescence spectroscopy and site-directed mutagenesis. 153 96

The ceroid-lipofuscinoses (Batten disease) are neurodegenerative inherited lysosomal storage diseases of children and animals. A common finding is the occurrence of fluorescent storage bodies (lipopigment) in cells. These have been isolated from tissues of affected sheep. Direct protein sequencing established that the major component is identical to the dicyclohexylcarbodiimide (DCCD) reactive proteolipid, subunit c, of mitochondrial ATP synthase and that this protein accounts for at least 50% of the storage body mass. No other mitochondrial components are stored. Direct sequencing of storage bodies isolated from tissues of children with juvenile and late infantile ceroid-lipofuscinosis established that they also contain large amounts of complete and normal subunit c. It is also stored in the disease in cattle and dogs but is not present in storage bodies from the human infantile form. Subunit c is normally found as part of the mitochondrial ATP synthase complex and accounts for 2-4% of the inner mitochondrial membrane protein. Mitochondria from affected sheep contain normal amounts of this protein. The P1 and P2 genes that code for it are normal as are mRNA levels. Oxidative phosphorylation is also normal. These findings suggest that ovine ceroid-lipofuscinosis is caused by a specific failure in the degradation of subunit c after its normal inclusion into mitochondria, and its consequent abnormal accumulation in lysosomes. This implies a unique pathway for subunit c degradation. It is probable that the human late infantile and juvenile diseases and the disease in cattle and dogs involve lesions in the same pathway.
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PMID:Mitochondrial ATP synthase subunit c storage in the ceroid-lipofuscinoses (Batten disease). 153 79

Distinct pathological and histopathological changes distinguish the ceroid-lipofuscinoses from other storage diseases of humans and animals. These various disease entities likely reflect a variety of mutations of the same gene, or mutations of different genes associated with metabolism of the same or similar substrates. The disease in sheep most closely resembles the juvenile human disease. In it 50% of the lipopigment consists of subunit c of mitochondrial ATP synthase while the remaining constituents are considered normal for a lysosomal derived cytosome. The same subunit c has been shown to be also stored in affected English Setter, Border Collie, and Tibetan Terrier dogs, the Devon cow, and in the late infantile and juvenile human forms of disease but not in the infantile form. Thus it gives a chemical unity to at least some members of the group and allows a major conceptual change in regard to further directions of research.
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PMID:Sheep and other animals with ceroid-lipofuscinoses: their relevance to Batten disease. 153 80

Studies to establish the structure/function relationships of oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase were carried out using genetic engineering and biochemical approaches. A full-length cDNA clone encoding OSCP was isolated from a bovine heart cDNA library, and the mature form of OSCP was expressed in Escherichia coli using plasmid expression vector pKP1500. Recombinant OSCP was found to accumulate in the cytoplasmic inclusion bodies, by virtue of which the recombinant protein could be purified to greater than 85% purity by simple low speed centrifugation of cell lysates. Recombinant OSCP was found to be indistinguishable from OSCP isolated from mitochondria with respect to (i) apparent molecular mass on sodium dodecyl sulfate gel electrophoresis, (ii) immunological reactivity to anti-OSCP serum, (iii) biological activity in restoring oligomycin-sensitive ATPase and Pi-ATP exchange activities to OSCP-depleted ATP synthase complexes, and (iv) insensitivity of the biological activity to sulfhydryl-directed alkylating reagents. The amino-terminal sequence of the recombinant protein revealed that the initiating methionine was not removed by E. coli, although that apparently did not affect protein folding or its biological activity. Data on nested deletion mutations starting from the carboxyl terminus in OSCP demonstrated that, in each instance, the mutant form was expressed and the protein product was sequestered in cytoplasmic inclusion bodies, similar to the wild-type form. However, none of the variants, including the one in which only the last 10 residues were deleted, was able to restore cold-stable oligomycin-sensitive ATPase or Pi-ATP exchange activity in OSCP-depleted complexes. Taken together, these data suggest that amino acid residues 181-190 (or some of the residues in this region) in the OSCP sequence may be important for OSCP-F1 interactions.
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PMID:Oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase. The carboxyl-terminal region of OSCP is essential for the reconstitution of oligomycin-sensitive H(+)-ATPase. 153 27

A cDNA clone encoding the complete precursor of the gamma subunit of chloroplast ATP synthase has been isolated from a tobacco (Nicotiana tabacum) leaf cDNA library in lambda gt11. The 1.4 kb insert encodes a polypeptide of 377 amino acid residues, of which 55 residues constitute an N-terminal presequence and 322 residues make up the mature gamma subunit. Hybridisation of the cDNA to Southern blots of tobacco genomic DNA indicates the presence of two genes in the haploid genome. Transcription and translation of the cDNA in vitro produced a protein of 41 kDa which was imported by isolated pea chloroplasts and processed to the mature 36 kDa subunit. The gamma subunit precursor was processed to the mature size by a processing peptidase of 180 kDa present in pea stromal extracts.
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PMID:Import and processing of the precursor form of the gamma subunit of the chloroplast ATP synthase from tobacco. 153 3

Chromatophores from Rhodobacter capsulatus were incubated in the dark with NADPH and acetylpyridineadenine dinucleotide (AcPdAD+) in the presence of different concentrations of myxothiazol. The transhydrogenase activity was monitored until an appropriate mass action ratio, [AcPdAD+][NADPH]/[AcPdADH][NADP+], was reached. The sample was then illuminated and the initial rate of either AcPdAD+ reduction by NADPH or AcPdADH oxidation by NADP+ was recorded. The ratio of H+ translocated per H- equivalent transferred by transhydrogenase was calculated from the value of the membrane potential (delta pH = 0) at which illumination caused no net reaction in either direction. The mean value for the H+/H- ratio was 0.55. At greater values of [AcPdAD+][NADPH]/[AcPdADH][NADP+] than were employed in the above experiments and over a wider range of concentrations of myxothiazol, it was found that incremental increases in the membrane potential always gave rise to a decrease, never an increase in the rate of AcPdAD+ reduction. In contrast to the H(+)-ATP synthase, there is no evidence of any activation/deactivation of H(+)-transhydrogenase by the protonmotive force.
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PMID:Nicotinamide nucleotide transhydrogenase from Rhodobacter capsulatus; the H+/H- ratio and the activation state of the enzyme during reduction of acetyl pyridine adenine dinucleotide. 154

We have seen that there is no simple answer to the question 'what controls respiration?' The answer varies with (a) the size of the system examined (mitochondria, cell or organ), (b) the conditions (rate of ATP use, level of hormonal stimulation), and (c) the particular organ examined. Of the various theories of control of respiration outlined in the introduction the ideas of Chance & Williams (1955, 1956) give the basic mechanism of how respiration is regulated. Increased ATP usage can cause increased respiration and ATP synthesis by mass action in all the main tissues. Superimposed on this basic mechanism is calcium control of matrix dehydrogenases (at least in heart and liver), and possibly also of the respiratory chain (at least in liver) and ATP synthase (at least in heart). In many tissues calcium also stimulates ATP usage directly; thus calcium may stimulate energy metabolism at (at least) four possible sites, the importance of each regulation varying with tissue. Regulation of multiple sites may occur (from a teleological point of view) because: (a) energy metabolism is branched and thus proportionate regulation of branches is required in order to maintain constant fluxes to branches (e.g. to proton leak or different ATP uses); and/or (b) control over fluxes is shared by a number of reactions, so that large increases in flux requires stimulation at multiple sites because each site has relatively little control. Control may be distributed throughout energy metabolism, possibly due to the necessity of minimizing cell protein levels (see Brown, 1991). The idea that energy metabolism is regulated by energy charge (as proposed by Atkinson, 1968, 1977) is misleading in mammals. Neither mitochondrial ATP synthesis nor cellular ATP usage is a unique function of energy charge as AMP is not a significant regulator (see for example Erecinska et al., 1977). The near-equilibrium hypothesis of Klingenberg (1961) and Erecinska & Wilson (1982) is partially correct in that oxidative phosphorylation is often close to equilibrium (apart from cytochrome oxidase) and as a consequence respiration and ATP synthesis are mainly regulated by (a) the phosphorylation potential, and (b) the NADH/NAD+ ratio. However, oxidative phosphorylation is not always close to equilibrium, at least in isolated mitochondria, and relative proximity to equilibrium does not prevent the respiratory chain, the proton leak, the ATP synthase and ANC having significant control over the fluxes. Thus in some conditions respiration rate correlates better with [ADP] than with phosphorylation potential, and may be relatively insensitive to mitochondrial NADH/NAD+ ratio.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Control of respiration and ATP synthesis in mammalian mitochondria and cells. 159 89

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