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Query: EC:1.6.99.5 (
NADH dehydrogenase
)
2,135
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The mitochondrial rotenone-sensitive NADH:ubiquinone oxidoreductase (complex I) comprises more than 35 subunits, the majority of which are encoded by the nucleus. In Chlamydomonas reinhardtii, only five components (ND1, ND2, ND4,
ND5
and ND6) are coded for by the mitochondrial genome. Here, we characterize two mitochondrial mutants (dum5 and dum17) showing strong reduction or inactivation of complex I activity: dum5 is a 1T deletion in the 3' UTR of nd5 whereas dum17 is a 1T deletion in the coding sequence of nd6. The impact of these mutations and of mutations affecting nd1, nd4 and nd4/nd5 genes on the assembly of complex I is investigated. After separation of the respiratory complexes by blue native (BN)-PAGE or sucrose gradient centrifugation, we demonstrate that the absence of intact ND1 or ND6 subunit prevents the assembly of the 850 kDa whole complex, whereas the loss of ND4 or ND4/
ND5
leads to the formation of a subcomplex of 650 kDa present in reduced amount. The implications of our findings for the possible role of these ND subunits on the activity of complex I and for the structural organization of the membrane arm of the enzyme are discussed. In mitochondria from all the strains analyzed, we moreover detected a 160-210 kDa fragment comprising the hydrophilic 49 kDa and 76 kDa subunits of the complex I peripheral arm and showing
NADH dehydrogenase
activity.
...
PMID:Impact of mutations affecting ND mitochondria-encoded subunits on the activity and assembly of complex I in Chlamydomonas. Implication for the structural organization of the enzyme. 1207 58
Fenpyroximate is a potent inhibitor of the mitochondrial proton-translocating
NADH-quinone oxidoreductase
(complex I). We synthesized its photoaffinity analogue [(3)H](trifluoromethyl)phenyldiazirinylfenpyroximate ([(3)H]TDF). When bovine heart submitochondrial particles (SMP) were illuminated with UV light in the presence of [(3)H]TDF, radioactivity was mostly incorporated into a 50 kDa band. There was a good correlation between radioactivity labeling of the 50 kDa band and inhibition of the NADH oxidase activity, indicating that a 50 kDa protein is responsible for the inactivation of complex I. Blue native gel electrophoresis of the [(3)H]TDF-labeled SMP revealed that the majority of radioactivity was found in complex I. Analysis of the complex I band on an SDS gel showed a major peak of radioactivity at approximately 50 kDa. There are three subunits in complex I that migrate in this region: FP51K, IP49K, and
ND5
. Further analysis using the 2D gel electrophoresis implied that the labeled protein was the
ND5
subunit. Labeling of the
ND5
subunit was stimulated by NADH/NADPH but was prevented by various complex I inhibitors. Amiloride derivatives that are known to be inhibitors of Na(+)/H(+) antiporters also diminished the labeling. In agreement with the protective effect, we observed that the amiloride derivatives inhibited NADH-ubiquinone-1 reductase activity but not NADH-K(3)Fe(CN)(6) reductase activity in bovine SMP. These results suggest that the
ND5
subunit is involved in construction of the inhibitor- and quinone-binding site(s). Furthermore, it seems likely that the
ND5
subunit may participate in H(+)(Na(+)) translocation in coupling site 1.
...
PMID:The ND5 subunit was labeled by a photoaffinity analogue of fenpyroximate in bovine mitochondrial complex I. 1253 87
The proton-translocating
NADH-quinone oxidoreductase
in mitochondria (complex I) and bacteria (NDH-1) was shown to be inhibited by amiloride derivatives that are known as specific inhibitors for Na(+)/H(+) exchangers. In bovine submitochondrial particles, the effective concentrations were about the same as those for the Na(+)/H(+) exchangers, whereas in bacterial membranes the inhibitory potencies were lower. These results together with our earlier observation that the amiloride analogues prevent labeling of the
ND5
subunit of complex I with a fenpyroximate analogue suggest the involvement of
ND5
in H(+) (Na(+)) translocation and no direct involvement of electron carriers in H(+) (Na(+)) translocation.
...
PMID:Amiloride inhibition of the proton-translocating NADH-quinone oxidoreductase of mammals and bacteria. 1291 22
Mammalian mitochondrial
NADH dehydrogenase
(complex I) is a multimeric complex consisting of at least 45 subunits, 7 of which are encoded by mitochondrial DNA (mtDNA). The function of these subunits is largely unknown. We have established an efficient method to isolate and characterize cells carrying mutations in various mtDNA-encoded complex I genes. With this method, 15 mouse cell lines with deficiencies in complex I-dependent respiration were obtained, and two near-homoplasmic mutations in mouse
ND5
and ND6 genes were isolated. Furthermore, by generating a series of cell lines with the same nuclear background but different content of an mtDNA nonsense mutation, we analyzed the genetic and functional thresholds in mouse mitochondria. We found that in wild-type cells, about 40% of
ND5
mRNA is in excess of that required to support a normal rate of
ND5
subunit synthesis. However, there is no indication of compensatory upsurge in either transcription or translation with the increase in the proportion of mutant
ND5
genes. Interestingly, the highest
ND5
protein synthesis rate was just sufficient to support the maximum complex I-dependent respiration rate, suggesting a tight regulation at the translational level. In another line of research, we showed that the mitochondrial
NADH-quinone oxidoreductase
of Saccharomyces cerevisiae (NDI1), although consisting of a single subunit, can completely restore respiratory
NADH dehydrogenase
activity in mutant human cells that lack the essential mtDNA-encoded subunit ND4. In particular, in these transfected cells, the yeast enzyme becomes integrated into the human respiratory chain and fully restores the capacity of the cells to grow in galactose medium.
...
PMID:Genetic and functional analysis of mitochondrial DNA-encoded complex I genes. 1512 3
We have investigated the topologies of Ndh (a plastid complex with
NADH dehydrogenase
activity) and its NDH-F subunit in thylakoids by trypsin and proteinase V8 digestion of both intact and Triton X-100-permeabilized barley thylakoids and identification of the products with antibodies against specific sequences of the NDH-A, NDH-K and NDH-F subunits. Antibody binding and protection against proteinases were also assayed. The analysis of the digestion products of NDH-F by immunodetection and matrix-assisted laser-desorption ionization-time-of-flight allowed us to propose its membrane topology and to compare it with bioinformatic predictions and with that of the homologous subunit (
ND5
/NuoL/NQO12) of the respiratory complex I. Results indicate that the thylakoid Ndh complex may have an L-shaped structure, similar to that of respiratory complex I, with the hydrophilic arm orientated towards the stroma and the hydrophobic arm inserted into the thylakoid. NDH-A and NDH-K may be located at the bridge between the two arms. Similar to
ND5
/NuoL/NQO12 of complex I, NDH-F must be distally located in the hydrophobic arm. NDH-F would include up to 15 transmembrane helices and 14 hydrophilic regions. A conserved His-349 in the X transmembrane helix could be involved in H+ pumping. The conserved Thr-181 NDH-F, whose probable phosphorylation increases the activity of the Ndh complex, is located within the hydrophilic region between the V and VI transmembrane helices.
...
PMID:Topology of the plastid Ndh complex and its NDH-F subunit in thylakoid membranes. 1512 88
Mitochondria-encoded ND (
NADH dehydrogenase
) subunits, as components of the hydrophobic part of complex I, are essential for NADH:ubiquinone oxidoreductase activity. Mutations or lack of expression of these subunits have significant pathogenic consequences in humans. However, the way these events affect complex I assembly is poorly documented. To understand the effects of particular mutations in ND subunits on complex I assembly, we studied four human cell lines: ND4 non-expressing cells,
ND5
non-expressing cells, and rho degrees cells that do not express any ND subunits, in comparison with normal complex I control cells. In control cells, all the seven analysed nuclear-encoded complex I subunits were found to be attached to the mitochondrial inner membrane, except for the 24 kDa subunit, which was nearly equally partitioned between the membranes and the matrix. Absence of a single ND subunit, or even all the seven ND subunits, caused no major changes in the nuclear-encoded complex I subunit content of mitochondria. However, in cells lacking ND4 or
ND5
, very low amounts of 24 kDa subunit were found associated with the membranes, whereas most of the other nuclear-encoded subunits remained attached. In contrast, membrane association of most of the nuclear subunits was significantly reduced in the absence of all seven ND proteins. Immunopurification detected several subcomplexes. One of these, containing the 23, 30 and 49 kDa subunits, also contained prohibitin. This is the first description of prohibitin interaction with complex I subunits and suggests that this protein might play a role in the assembly or degradation of mitochondrial complex I.
...
PMID:Structural organization of mitochondrial human complex I: role of the ND4 and ND5 mitochondria-encoded subunits and interaction with prohibitin. 1525 Aug 27
The mitochondrial DNA (mtDNA) from the salmon louse, Lepeophtheirus salmonis, is 15445 bp. It includes the genes coding for cytochrome B (Cyt B), ATPase subunit 6 and 8 (A6 and A8),
NADH dehydrogenase
subunits 1-6 and 4L (ND1, ND2, ND3, ND4, ND4L,
ND5
and ND6), cytochrome c oxidase subunits I-III (COI, COII and COIII), two rRNA genes (12S rRNA and 16S rRNA) and 22 tRNAs. Two copies of tRNA-Lys are present in the mtDNA of L. salmonis, while tRNA-Cys was not identified. Both DNA strands contain coding regions in the salmon louse, in contrast to the other copepod characterized Tigriopus japonicus, but only a few genes overlap. In vertebrates, ND4 and ND4L are transcribed as one bicistronic mRNA, and are therefore localized together. The same organization is also found in crustaceans, with the exceptions of T. japonicus, Neocalanus cristatus and L. salmonis that deviate from this pattern. Another exception of the L. salmonis mtDNA is that A6 and A8 do not overlap, but are separated by several genes. The protein-coding genes have a bias towards AT-rich codons. The mitochondrial gene order in L. salmonis differs significantly from the copepods T. japonicus, Eucalanus bungii, N. cristatus and the other 13 crustaceans previously characterized. Furthermore, the mitochondrial rRNA genes are encoded on opposite strands in L. salmonis. This has not been found in any other arthropods, but has been reported in two starfish species. In a phylogenetic analysis, using an alignment of mitochondrial protein sequences, L. salmonis groups together with T. japonicus, being distant relatives to the other crustaceans.
...
PMID:Genetic characterization of the mitochondrial DNA from Lepeophtheirus salmonis (Crustacea; Copepoda). A new gene organization revealed. 1598 68
Oxygen is a major regulator of nuclear gene expression. However, although mitochondria consume almost all of the O2 available to the cells, little is known about how O2 tension influences the expression of the mitochondrial genome. We show in O2-sensitive excitable rat PC12 cells that, among the mtDNA-encoded genes, hypoxia produced a specific down-regulation of the transcripts encoding mitochondrial complex I
NADH dehydrogenase
(ND) subunits, particularly ND4 and
ND5
mRNAs and a stable mRNA precursor containing the
ND5
and cytochrome b genes. This unprecedented effect of hypoxia was fast (developed in <30 min) and fairly reversible and occurred at moderate levels of hypoxia (O2 tensions in the range of 20-70 mm Hg). Hypoxic down-regulation of the mitochondrial complex I genes was paralleled by the reduction of complex I activity and was retarded by iron chelation, suggesting that an iron-dependent post-transcriptional mechanism could regulate mitochondrial mRNA stability. It is known that cell respiration is under tight control by the amount of proteins in mitochondrial complexes of the electron transport chain. Therefore, regulation of the expression of the mitochondrial (mtDNA)-encoded complex I subunits could be part of an adaptive mechanism to adjust respiration rate to the availability of O2 and to induce fast adaptive changes in hypoxic cells.
...
PMID:Oxygen tension regulates mitochondrial DNA-encoded complex I gene expression. 1625 62
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.
...
PMID:Nuclear suppression of mitochondrial defects in cells without the ND6 subunit. 1642 59
We determined the complete nucleotide sequence of the mitochondrial (mt) genome of a Malagasy poison frog, Mantella madagascariensis (family Mantellidae), and partial sequences of two Mantella (M. baroni and M. bernhardi) and two additional mantellid species (Boophis madagascariensis and Mantidactylus cf. ulcerosus). The M. madagascariensis genome was shown to be the largest (23kbp) of all vertebrate mtDNAs investigated so far. Furthermore, the following unique features were revealed: (1) the positions of some genes and gene regions were rearranged compared to mitochondrial genomes typical for vertebrates and other anuran groups, (2) two distinct genes and a pseudogene corresponding to transfer RNA gene for methionine (tRNA-Met) were encoded, and (3) two control regions with very high sequence homology were present. These features were shared by the two other Mantella species but not the other mantellid species, indicating dynamic genome reorganization in a common ancestor linage before divergence of the Mantella genus. The reorganization pathway could be explained by a model of gene duplication and deletion. Duplication and deletion events also seem to have been responsible for concerted sequence evolution of the control regions in Mantella mt genomes. It is also suggested that the pseudo tRNA-Met gene sustained for a long time in Mantella mt genomes possibly functions as a punctuation marker for
NADH dehydrogenase
subunit (ND) 2 mRNA processing. Phylogenetic analyses employing a large sequence data set of mt genes supported the monophyly of Mantellidae and Rhacophoridae and other recent phylogenetic views for ranoid frogs. The resultant phylogenetic relationship also suggested parallel occurrence of two tRNA-Met genes, duplicated control regions, and
ND5
gene translocation in independent ranoid lineages.
...
PMID:Complete nucleotide sequence of the mitochondrial genome of a Malagasy poison frog Mantella madagascariensis: evolutionary implications on mitochondrial genomes of higher anuran groups. 1644 6
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