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1.
James W. Casey Huey-Juang Hsu Godfrey S. Getz Murray Rabinowitz Hiroshi Fukuhara 《Journal of molecular biology》1974,88(4):735-747
We have used transfer RNA-DNA hybridization to show that seven tRNAs, i.e. tyrosyl, glutamyl, aspartyl, prolyl, lysyl, histidyl and seryl, hybridize with grande yeast mitochondrial DNA. These tRNA species are in addition to the seven which we previously showed to be gene products of mitochondrial DNA. Escherichia coli aminoacyl-synthetase preparations also were shown to catalyze specific acylation of yeast mitochondrial leucyl and tyrosyl-tRNA, but not of the isoaccepting tRNAs localized in the cell supernatant. Cytoplasmic tRNAs were found to be present in our purified mitochondrial preparations. 相似文献
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The number of 4-S RNA genes on yeast mitochondrial DNA 总被引:3,自引:0,他引:3
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Johannes L. Bos 《Molecular & general genetics : MGG》1981,181(4):420-423
Summary The omega locus controls the polarity of recombination and transmission of genetic markers in the 21S ribosomal RNA region in yeast mtDNA. Polarity is observed in crosses between omega+ and omega- strains. These two strains differ by the presence of an intervening sequence in the 21S ribosomal RNA gene of omega+ strains. Mutations of the omega- allele, omega neutral (omegan), can eliminate the polarity effect. We have made DNA:RNA hybrids containing ribosomal RNA from an omegan strain and mtDNA from Saccharomyces carlsbergensis (identical to omega- in the nucleotide sequence of the omega region). These hybrids contain no mismatch at the omega region detectable by digestion with S1 nuclease. We conclude that omegan differs from omega- only in a point mutation or analogous small alteration and that the omegan mutation can result either m a Cr phenotype (omeganCr) or in the phenotypic suppression of pre-existing Cr mutations (omeganCs). All results can be explained by a model which postulates interaction in the ribosome between the Cr and omegan regions of the ribosomal RNA and interference of the omegan mutation with splicing of the precursor ribosomal RNA in omega+ strains. The mechanism of omega-directed polarity is discussed.Abbreviations rRNA
ribosomal RNA
- bp
base pair(s)
- kb
kilo base pair(s) 相似文献
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James W. Casey Huey-Juang Hsu Murray Rabinowitz Godfrey S. Getz Hiroshi Fukuhara 《Journal of molecular biology》1974,88(4):717-733
Hybridization saturation analyses of mitochondrial DNA from 11 petite clones genetically characterized with respect to chloramphenicol and erythromycin resistance markers, have been carried out with 11 individual mitochrondrial transfer RNAs. Mitochondrial tRNA cistrons were lost, retained, or amplified in different petite strains. In some cases hybridization levels corrected for kinetic complexity of the mtDNA3 were two- to threefold greater than that for grande mtDNA indicating selective amplification, or increased number of copies, of the segment of mtDNA containing that tRNA cistron. Hybridization levels corrected for reduced kinetic complexity of petite mtDNAs in many cases were only 1 to 10% of that for grande mtDNA suggesting a low level of intracellular molecular heterogeneity of mtDNA with respect to tRNA cistrons. Some petite clones that retained tRNA genes continued to transcribe mitochondrial tRNAs, since tRNA isolated from these strains could be aminoacylated with Escherichia, coli synthetases and hybridized with mtDNA. Hybridization data allow us to order several of the tRNA cistrons on the mitochondrial genome with respect to the chloramphenicol and erythromycin antibiotic resistance markers. 相似文献
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Transfer RNA genes in Drosophila mitochondrial DNA: related 5'' flanking sequences and comparisons to mammalian mitochondrial tRNA genes. 总被引:4,自引:8,他引:4 下载免费PDF全文
Genes for tRNAgly and tRNAserUCN have been identified within sequences of mtDNA of Drosophila yakuba. The tRNAgly gene lies between the genes for cytochrome c oxidase subunit III and URF3, and all three of these genes are contained in the same strand of the mtDNA molecule. The tRNAserUCN gene is adjacent to the URF1 gene. These genes are contained in opposite strands of the mtDNA molecule and their 3' ends overlap. The structures of the tRNAgly and tRNAserUCN genes, and of the four tRNA genes of D. yakuba mtDNA reported earlier (tRNAile, tRNAgln, tRNAf-met and tRNAval) are compared to each other, to non-organelle tRNAs, and to corresponding mammalian mitochondrial tRNA genes. Within 19 nucleotides upstream from the 5' terminal nucleotide of each of the Drosophila mitochondrial tRNAgly, tRNAserUCN, tRNAile, tRNAgln and tRNAf-met genes occurs the sequence 5'TTTATTAT, or a sequence differing from it by one nucleotide substitution. Upstream from this octanucleotide sequence, and separated from it by 3, 4 and 11 nucleotides, respectively, in the 5' flanking regions of the tRNAile, tRNAserUCN and tRNAgly genes occurs the sequence 5'GATGAG. 相似文献
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Transfer RNA gene recruitment in mitochondrial DNA 总被引:11,自引:0,他引:11
Transfer RNA (tRNA) is the adaptor molecule that mediates recognition of the codon sequence in mRNA and enables its translation into the appropriate amino acid. Accordingly, phylogenetic relationships among tRNA genes are often thought to recapitulate the evolution of the genetic code. However, it has been demonstrated experimentally that one tRNA gene can be replaced with a copy of another carrying a single mutation in its anticodon sequence. In this article, we show that such "gene recruitment" has occurred recently and repeatedly in the mitochondrial genome of the demosponge Axinella corrugata and appears to be a common phenomenon in the evolution of the tRNA multigene family. 相似文献
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Summary We have fractionated fragments of yeast mtDNA, obtained with restriction endonucleases, on poly(U)-Sephadex columns using the procedure of Flavell and Van den Berg (FEBS Letters (1975) 58, 90–93). The poly(U) forms a triple helix with (dA·dT) clusters in duplex DNA and fractionates DNA fragments on the basis of the length and number of clusters contained in them.mtDNA fragments obtained with endonucleases PstI, BamHI, HindII, HindII+III, EcoRI, HapII and HhaI were separated by poly(U)-Sephadex in three groups: fragments not retained by the column in 2M LiCl, fragments partially retained and fragments (nearly) completely bound in 2 M LiCl and only eluted by 0.1 M LiCl. The separation obtained is adequate for analytical fractionation of fragments and it can be used for the preparative isolation of firmly-bound fragments.In mtDNA digests made with endonuclease HapII, which gives about 70 separable fragments under our conditions, only about 10% of the fragments were firmly bound to poly(U)-Sephadex. This shows that the number of (dA·dT) clusters long enough to result in binding is limited in yeast mtDNA and its suggests that large fragments are bound by only one or a few clusters.Corresponding segments of the physical map of the mtDNAs from Saccharomyces carlsbergensis and Saccharomyces cerevisiae strains JS1-3D and KL14-4A were bound to the column, showing that the (dA·dT) clusters responsible for binding are conserved in the evolution of mtDNA. However, one 3,000 bp insert, only present on KL14-4A mtDNA, causes the loss of a binding site, another long insert introduces a new binding site.Fragments firmly bound to the columns are clustered in one quadrant of the physical map of these three mtDNAs. This quadrant also contains the large insertions present in KL14-4A mtDNA and absent from S. carlsbergensis mtDNA. The possible relation between (dA·dT) clusters and insertions is discussed.Abbreviation bp
base pairs 相似文献
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The nucleotide sequence of a segment of the mtDNA molecule of Drosophila yakuba which contains the A+T-rich region and the small and large rRNA genes separated by the tRNAval gene has been determined. The 5' end of the small rRNA gene was located by S1 protection analysis. In contrast to mammalian mtDNA, a tRNA gene was not found at the 5' end of the D. yakuba small rRNA gene. The small and large rRNA genes are 20.7% and 16.7% G+C and contain only 789 and 1326 nucleotides. The 5' regions of the small rRNA gene (371 nucleotides) and of the large rRNA gene (643 nucleotides) are extremely low in G+C (14.6% and 9.5%, respectively) and convincing sequence homologies between these regions and the corresponding regions of mouse mt-rRNA genes were found only for a few short segments. Nevertheless, the entire lengths of both of the D. yakuba mt-rRNA genes can be folded into secondary structures which are remarkably similar to secondary structures proposed for the rRNAs of mouse mtDNA. The replication origin-containing, A+T-rich region (1077 nucleotides; 92.8% A+T), which lies between the tRNAile gene and the small rRNA gene, lacks open reading frames greater than 123 nucleotides. 相似文献
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A H Schinkel M J Groot Koerkamp A W Teunissen H F Tabak 《Nucleic acids research》1988,16(19):9147-9163
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Richard F. Selden Andre Steinmetz Lee McIntosh Lawrence Bogorad Gerard Burkard Mfika Mubumbila Marcel Kuntz Edwin J. Crouse Jacques H. Weil 《Plant molecular biology》1983,2(3):141-153
A minimum of 37 genes corresponding to tRNAs for 17 different amino acids have been localized on the restriction endonuclease cleavage site map of theZea mays chloroplast DNA molecule. Of these, 14 genes corresponding to tRNAs for 11 amino acids are located in the larger of the two single-copy regions which separate the two inverted copies of the repeat region. One tRNA gene is in the smaller single-copy region. Each copy of the large repeated sequence contains, in addition to the ribosomal RNA genes, 11 tRNA genes corresponding to tRNAs for 8 amino acids. The genes for tRNA2 Ile and tRNAAla map in the ribosomal spacer sequence separating the 16S and 23S ribosomal RNA genes. The three isoaccepting species for the tRNAsLeu and the three for tRNAsSer, as well as the two isoaccepting species for tRNAAsn, tRNAGly, tRNAsIle, tRNAsMet, tRNAsThr, are shown to be encoded at different loci. Two independent methods have been used for the localization of tRNA genes on the physical map of the maize chloroplast DNA molecule: (a) cloned chloroplast DNA fragments were hybridized with radioactively-labelled total 4S RNAs, the hybridized RNAs were then eluted, and identified by two-dimensional polyacrylamide gel electrophoresis, and (b) individual tRNAs were32P-labelledin vitro and hybridized to DNA fragments generated by digestion of maize chloroplast DNA with various restriction endonucleases. 相似文献
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Richard B. Hallick Margaret J. Hollingsworth Jac A. Nickoloff 《Plant molecular biology》1984,3(3):169-175
Summary Transfer RNA genes have been mapped to at least nine different loci on the physical map of the Euglena gracilis chloroplast genome. One of these loci in the ribosomal RNA operons is present three times per genome. The DNA sequences of six of the nine different loci, containing 21 different tRNA genes, have been determined. Genes corresponding to the amino acids Ala, Arg, Asn, Cys, Gln, Gly (2), Glu, His, Ile, Leu (2), Met (2), Phe, Ser, Thr, Trp, Tyr, Val, and one unassigned species have been identified. All genes except one are found in clusters of 2–6 genes. None of the known genes contains introns, nor codes for the 3-CCA terminus. In addition to these genes, two pseudo tRNA genes are present in the rDNA leader region. 相似文献
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We have investigated the organization of sequences in ten rho- petite mtDNAs by restriction enzyme analysis and electron microscopy. From the comparison of the physical maps of the petite mtDNAs with the physical map of the mtDNA of the parental rho+ strain we conclude that there are at least three different classes of petite mtDNAs: I. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA. II. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA with a terminal inverted duplication. III. Mixed repeats of an (almost) continuous rho+ mtDNA segment. In out petite mtDNAs of the second type, the inverted duplications do not cover the entire conserved rho+ mtDNA segment. We have found that the petite mtDNAs of the third type contain a local inverted duplication at the site where repeating units can insert in two orientations. At least in one case this local inverted duplication must have arisen by mutation. The rearrangements that we have found in the petite mtDNAs do not cluster at specific sites on the rho+ mtDNA map. Large rearrangements or deletions within the conserved rho+ mtDNA segment seem to contribute to the suppressiveness of a petite strain. There is also a positive correlation between the retention of certain segments of the rho+ mtDNA and the suppressiveness of a petite strain. We found no correlation between the suppressiveness of a petite strain and its genetic complexity. The relevance of these findings for the mechanism of petite induction and the usefulness of petite strains for the physical mapping of mitochondrial genetic markers and for DNA sequence analysis are discussed. 相似文献
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Knight JA 《Genetics》1980,94(1):69-92
A large number of mitochondrial antibiotic-resistant mutants have been isolated following mutagenesis with manganese. These include several different phenotypic classes of mutants, as distinguished by cross-resistance patterns, that have been found to be allelic at cap1 or ery1; some have been found to be heteroallelic.--Seven chloramphenicol-resistant mutants have been identified that are nonallelic by recombination tests with the three loci (cap1, spi1 and ery1) previously identified in the ribosomal region. Four of these are allelic with each other and define a new locus, cap3; two others are allelic and define another new locus, cap2; the seventh maps at yet a different locus, cap4. One new spiramycin-resistant mutant has been identified that defines still another new locus, spi2. A variety of genetic techniques have been used to map these loci within the ribosomal region of the mitochondrial genome.-Manganese has been shown to be effective in inducing the mutation from omega(-) to omega(n) in many mutants that experience a simultaneous mutation at the closely linked cap1 locus. The omega(n) mutation has also been described in the cap4 mutant, and this locus has been shown to be more closely linked to omega than cap1 is to omega. 相似文献
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1. We have determined the physical location of mitochondrial genetic markers in the 21S region of yeast mtDNA by genetic analysis of petite mutants whose mtDNA has been physically mapped on the wild-type mtDNA. 2. The order of loci, determined in this study, is in agreement with the order deduced from recombination analysis and coretention analysis except for the position of omega+: we conclude that omega+ is located between C321 (RIB-1) and E514 (RIB-3). 3. The marker E514 (RIB-3) has been localized on a DNA segment of 3800 bp, and the markers E354, E553 and cs23 (RIB-2) on a DNA segment of 1100 base pairs; both these segments overlap the 21S rRNA cistron. The marker C321 (RIB-1) has been localized within a segment of 240 bp which also overlaps the 21S rRNA cistron, and we infer on the basis of indirect evidence that this marker lies within this cistron. 4. In all our rho+ as well as rho- strains there is a one-to-one correlation between the omega+ phenotype, the ability to transmit the omega+ allele and the presence of a mtDNA segment of about 1000 bp long, located between sequences specifying RIB-3 and sequences corresponding to the loci RIB-1 and RIB-2. This segment may be inserted at this same position into omega- mtDNA by recombination. 5. The role which the different allelic forms of omega may play in the polarity of recombination is discussed. 相似文献