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Query: EC:1.9.3.1 (
cytochrome oxidase
)
8,822
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The region of yeast mitochondrial DNA between 10.7 and 17.9 map units has been characterized by restriction analysis and DNA sequencing. The DNA sequence was obtained from the partially overlapping genomes of the two rho- mutants DS200/A1 and DS302. Two tRNA genes have been found in the sequence upstream of the oxi1 gene. The deduced secondary structures indicate that the genes code for the methionine (5'-CAU-3') and the
asparagine
(5'-GUU-3') tRNAs of yeast mitochondria. The region between 10.7 and 17.9 units contains two reading frames. One of these corresponds to the oxi1 gene previously shown to code for subunit 2 of
cytochrome oxidase
(Coruzzi, G., and Tzagoloff, A. (1979) J. Biol. Chem. 254,. 9324-9330; Fox, T. D. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 6534-6538). The second reading frame can potentially code for a basic protein with 386 amino acid residues. It is not known at present if this putative gene is translated in vivo. Northern blots of wild type mitochondrial RNA were hybridized to single-stranded probes from the oxi1 gene and flanking regions. The results of these analyses indicate that the primary transcript of the oxi1 region is a high molecular weight RNA (larger than 3 kilobase pairs) which is processed in discrete steps to a mature 850-nucleotide messenger. The 5' leader of the messenger has been established to be 54 nucleotides long and to have a sequence identical with that of the genomic DNA immediately upstream of the oxi1 gene.
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PMID:Assembly of the mitochondrial membrane system. Analysis of the nucleotide sequence and transcripts in the oxi1 region of yeast mitochondrial DNA. 703 Oct 51
Since yeast is amenable to mitochondrial transformation, designed mutations can be introduced in the mitochondrially encoded subunits of the respiratory complexes. In the present work, six mutations have been introduced by the biolistic method into yeast (Saccharomyces cerevisiae)
cytochrome oxidase
subunits I and III. The effects of these mutations on respiratory growth competence,
cytochrome oxidase
activity and optical properties were then characterized. Firstly, the conserved glutamate Glu-243 in the D-channel of subunit I was replaced by an
asparagine
or an aspartate residue. The effects of the mutations showed that Glu-243, which is essential for proton movement in bacterial oxidases, is also required for the activity of the eukaryotic enzyme. Secondly, four mutations associated with human disease were introduced in yeast, allowing detailed analysis of their deleterious effects on
cytochrome oxidase
function: Met-273-->Thr, Ile-280-->Thr and Gly-317-->Ser, affecting residues located in or near the K-channel in subunit I, and a short in-frame deletion comprising residues Phe-102 to Phe-106 in subunit III (DeltaF102-F106). The subunit III mutation was highly deleterious and abolished enzyme assembly. The change Gly-317-->Ser had no effect on respiratory function. However, mutations Met-273-->Thr and Ile-280-->Thr were mildly deleterious, decreased
cytochrome oxidase
activity and slightly perturbed the properties of the binuclear centre.
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PMID:Site-directed mutations in the mitochondrially encoded subunits I and III of yeast cytochrome oxidase. 1117 Nov 20
The heme-copper oxidases convert the free energy liberated in the reduction of O(2) to water into a transmembrane proton electrochemical potential (protonmotive force). One of the essential structural elements of the enzyme is the D-channel, which is thought to be the input pathway, both for protons which go to form H(2)O ("chemical protons") and for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel contains a chain of water molecules extending about 25 A from an aspartic acid (D132 in the Rhodobacter sphaeroides oxidase) near the cytoplasmic ("inside") enzyme surface to a glutamic acid (E286) in the protein interior. Mutations in which either of these acidic residues is replaced by their corresponding amides (D132N or E286Q) result in severe inhibition of enzyme activity. In the current work, an
asparagine
located in the D-channel has been replaced by the corresponding acid (N139 to D; N98 in bovine enzyme) with dramatic consequences. The N139D mutation not only completely eliminates proton pumping but, at the same time, confers a substantial increase (150-300%) in the steady-state
cytochrome oxidase
activity. The N139D mutant of the R. sphaeroides oxidase was further characterized by examining the rates of individual steps in the catalytic cycle. Under anaerobic conditions, the rate of reduction of heme a(3) in the fully oxidized enzyme, prior to the reaction with O(2), is identical to that of the wild-type oxidase and is not accelerated. However, the rate of reaction of the fully reduced enzyme with O(2) is accelerated by the N139D mutation, as shown by a more rapid F --> O transition. Whereas the rates of formation and decay of the oxygenated intermediates are altered, the nature of the oxygenated intermediates is not perturbed by the N139D mutation.
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PMID:A mutation in subunit I of cytochrome oxidase from Rhodobacter sphaeroides results in an increase in steady-state activity but completely eliminates proton pumping. 1241 87
Vegetables and fruits are essential components of the human diet as they are sources of vitamins, minerals, and fiber and provide antioxidants that prevent chronic diseases. Our goal is to improve durable nutritional quality of tomato fruit. We developed transgenic tomatoes expressing yeast S-adenosylmethionine decarboxylase (ySAMdc) gene driven by a fruit-specific E8 promoter to investigate the role of polyamines in fruit metabolism. Stable integration of E8-ySAMdc chimeric gene in tomato genome led to ripening-specific accumulation of polyamines, spermidine (Spd) and spermine (Spm), which in turn affected higher accumulation of glutamine,
asparagine
, and organic acids in the red fruit with significant decrease in the contents of valine, aspartate, sucrose, and glucose. The metabolite profiling analysis suggests that Spd/Spm are perceived as "signaling" organic-N metabolites by the fruit cells, resulting in the stimulation of carbon sequestration; enhanced synthesis of biomolecules; increased acid to sugar ratio, a good attribute for the fruit flavor; and in the accumulation of another "vital amine," choline, which is an essential micronutrient for brain development. A limited transcriptome analysis of the transgenic fruit that accumulate higher polyamines revealed a large number of differentially expressed genes, about 55% of which represented discrete functional categories, and the remaining 45% were novel, unknown, or unclassified: amino acid biosynthesis, carotenoid biosynthesis, cell wall metabolism, chaperone family, flavonoid biosynthesis, fruit ripening, isoprenoid biosynthesis, polyamine biosynthesis, signal transduction, stress/defense-related, transcription, translation, and vacuolar function. There was a good correspondence between some gene transcripts and their protein products, but not in the case of the tonoplast intrinsic protein, which showed post-transcriptional regulation. Higher metabolic activity of the transgenic fruit is reflected in higher respiratory activity, and upregulation of chaperones and mitochondrial
cytochrome oxidase
transcripts compared to the control. These transgenic plants are a new resource to understand the role of Spd/Spm in fruit biology. Transcriptome analysis and metabolic profiles of Spd/Spm accumulating, transgenic fruit suggest the presence of an intricate regulation and interconnection between certain metabolic pathways that are revived when Spd and Spm likely reach a certain threshold. Thus, polyamines act as antiapoptotic regulatory molecules and are able to revive metabolic memory in the tomato fruit.
...
PMID:Overaccumulation of higher polyamines in ripening transgenic tomato fruit revives metabolic memory, upregulates anabolism-related genes, and positively impacts nutritional quality. 1795 94
Infertility affects 10-15% of the population, of which approximately 40% is due to male etiology and consists primarily of low sperm count (oligozoospermia) and/or abnormal sperm motility (asthenozoospermia). Recently, it has been demonstrated that mtDNA substitutions can influence semen quality. In this study, we performed a sequence analysis of the mitochondrial
cytochrome oxidase
I (COXI) gene in 31 infertile men suffering from asthenozoospermia in comparison to 33 normozoospermic infertile men and 100 fertile men from the Tunisian population. A novel m.6307A>G mutation was found in sperm mitochondrial DNA (mtDNA). This mutation was found in six asthenozoospermic patients, and was absent in normozoospermic and fertile men. We also detected 21 known substitutions previously reported in the Human Mitochondrial Database. The m.6307A>G mutation substitutes a highly conserved
asparagine
at position 135 to serine. In addition, PolyPhen-2 analysis predicted that this variant is "probably damaging.
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PMID:A novel m.6307A>G mutation in the mitochondrial COXI gene in asthenozoospermic infertile men. 2371 56
Phylogenetic relationships within the family Rivulidae (order Cyprinodontiformes) are investigated using 1972 aligned base pairs of mitochondrial DNA (mtDNA) for samples representing 66 species. Genes analyzed include those encoding the 12S ribosomal RNA; transfer RNAs for valine, glutamine, methionine, tryptophan, alanine,
asparagine
, cysteine, and tyrosine; complete NADH dehydrogenase subunit II; and part of
cytochrome oxidase
I. Parsimony analysis of the aligned mtDNA sequences results in a single most parsimonious tree. The phylogeny reveals two independent origins of developmental diapause within the family Rivulidae. It is unlikely that diapause evolved de novo in each group, suggesting that the presence or absence of diapause is the result of developmental switches between alternative stabilized pathways. Phylogeny of the family Rivulidae shows high concordance with predictions derived from the geological history of South America and Central America. Basal lineages in the rivulid phylogeny are distributed primarily on geologically old areas, whereas more nested lineages occur in geologically younger areas. However, there is little concordance between the molecular phylogeny and currently available morphological hypotheses and existing taxonomies. Based on the mtDNA phylogeny, the genera Pterolebias, Rivulus, Pituna, and Plesiolebias are considered nonmonophyletic and warrant taxonomic reassessment.
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PMID:THE EVOLUTION OF DIAPAUSE IN THE KILLIFISH FAMILY RIVULIDAE (ATHERINOMORPHA, CYPRINODONTIFORMES): A MOLECULAR PHYLOGENETIC AND BIOGEOGRAPHIC PERSPECTIVE. 2856 41
