Transfer RNA genes in the cap-oxil region of yeast mitochondrial DNA.

A cytoplasmic "petite" (rho-) clone of Saccharomyces cerevisiae has been isolated and found through DNA sequencing to contain the genes for cysteine, histidine, leucine, glutamine, lysine, arginine, and glycine tRNAs. This clone, designated DS502, has a tandemly repeated 3.5 kb segment of the wild type genome from 0.7 to 5.6 units. All the tRNA genes are transcribed from the same strand of DNA in the direction cap to oxil. The mitochondrial DNA segment of DS502 fills a sequence gap that existed between the histidine and lysine tRNAs. The new sequence data has made it possible to assign accurate map positions to all the tRNA genes in the cap-oxil span of the yeast mitochondrial genome. A detailed restriction map of the region from 0 to 17 map units along with the locations of 16 tRNA genes have been determined. The secondary structures of the leucine and glutamine tRNAs have been deduced from their gene sequences. The leucine tRNA exhibits 64% sequence homology to an E. coli leucine tRNA.     

The primary structure of cytoplasmic initiator transfer ribonucleic acid from Torulopsis utilis

Cytoplasmic initiator transfer ribonucleic acid (tRNAinit) was purified from bulk Torulopsis (Candida) utilis tRNA by a series of column chromatography procedures. Sequence analysis of the products of complete and partial digestion of this tRNA with ribonuclease A [EC 3.1.4.22] and ribonuclease T1 [EC 3.1.4.8] enabled us to determine the complete primary structure of the molecule. The chain length of this tRNA was 76, including 11 modified nucleotides. The structure of the tRNA was arranged into a cloverleaf model and compared with those of other initiator tRNA species. As in the cytoplasmic initiator tRNA's of most other eukaryotic cells, the sequence -A-U-C-G- is contained in this tRNA in place of the usual -T-psi-C-G (or A)- found in other tRNA's.     

Assembly of the mitochondrial membrane system: two separate genes coding for threonyl-tRNA in the mitochondrial DNA of Saccharomyces cerevisiae.

1. Mitochondria of Saccharomyces cerevisiae contain two tRNA's that are acylated with threonine. The two isoaccepting species (tRNA1Thr and tRNA2Thr) can be separated by reversed-phase chromatography on RPC-5. 2. A cytoplasmic mutant has been isolated which lacks tRNA1Thr but has normal levels of tRNA2Thr. This mutation was previously shown to map between the oxi 1 and oxi 2 loci on mitochondrial DNA. 3. tRNA1Thr and tRNA2Thr hybridize to wild type mitochondrial but not nuclear DNA and are capable of partially competing with each other. Hybridization of each species to different segments of mitochondrial DNA isolated from p- clones indicate that there are two threonyl tRNA genes. One gene is located between oxi 1 and oxi 2 and codes for tRNA1Thr. The second gene codes for tRNA2Thr and is near the cap locus. 4. Binding assays to E. coli ribosomes indicate that tRNA2Thr recognizes the threonine triplet ACA and may also recognize the other three triplets but with a much lower efficiency. None of the four codons for threonine stimulate the binding of tRNA1Thr to the ribosomes.     

Isolation and partial characterization of three Escherichia coli mutants with altered transfer ribonucleic acid methylases.

Seven transfer ribonucleic acid (tRNA) methylase mutants were isolated from Escherichia coli K-12 by examining the ability of RNA prepared from clones of unselected mutagenized cells to accept methyl groups from S-adenosylmethionine catalyzed by crude enzymes from wild-type cells. Five of the mutants had an altered uracil-tRNA methylase; consequently their tRNA's lacked ribothymidine. One mutant had tRNA deficient in 7-methylguanosine, and one mutant contained tRNA lacking 2-thio-5-methylaminomethyluridine. The genetic loci of the three tRNA methylase mutants were distributed over the E. coli genome. The mutant strain deficient in 7-methylguanosine biosynthesis showed a reduced efficiency in the suppression of amber mutations carried by T4 or lambda phages.     

Neurospora crassa mitochondrial transfer RNAs.

Total mitochondrial tRNA from Neurospora crassa was characterized by base composition analysis, one- and two-dimensional gel electrophoreses and reversed-phase chromatography on RPC5. The guanosine + cytidine content was about 43%, as compared to 60% for cytoplasmic tRNA. The modified nucleoside content was low and about the same as that of total yeast mitochondrial tRNA, though the G + C content is very different. We found psi, T, hU, t6A, m1G, M2G, m22G. Neither the eukaryotic "Y" base, nor the prokaryotic s4U were present. On two-dimensional polyacrylamide gel electropherograms about 25 species were separated. One species for phenylalanine, two for leucine and two for methionine could be located. Neurospora crassa mitochondrial tRNA does not hybridize with yeast mitochondrial DNA.     

Amino acid specificity of the transfer RNA species coded for by HeLa cell mitochondrial DNA

The amino acid specificity of the tRNA species coded for by HeLa cell mitochondrial DNA has been investigated by carrying out hybridizations between amino acid-tRNA complexes labeled in the amino acid and separated mitochondrial DNA strands.The results indicate that there are in HeLa cell mitochondria at least 17 distinct tRNA species hybridizable with mitochondrial DNA, which are specific for 16 amino acids. For 14 of the 16 amino acids, amino-acyl-tRNA synthetase activities distinct from the cytoplasmic ones have been detected in mitochondria. The remaining four amino acids (asparagine, glutamine, histidine and proline) have consistently failed to charge to any detectable extent mitochondrial tRNA species hybridizable with mitochondrial DNA.No obvious relationship appears to exist between the amino acids incorporated into tRNAs hybridizable to mitochondrial DNA and the previously observed pattern of chloramphenicol-sensitive amino acid incorporation by HeLa cell mitochondria.     

Mapping of the mitochondrial 16S ribosomal RNA gene and its expression in the cytoplasmic petite mutants ofSaccharomyces cerevisiae

The 16S ribosomal RNA gene of yeast mitochondria was titrated in various cytoplasmic petite mutants by DNA-RNA hybridization. The gene was located close to the prolyl transfer RNA gene. The properties of the rho^? strains suggest that the gene order would be: - P_I - 16S - prolyl tRNA - valyl tRNA - (tRNAs) - R_I - R_III -; the 23S ribosomal gene is far from the 16S one. Several petite mutants were found which have retained, in addition to many transfer RNA genes, both of the 23S and 16S ribosomal RNA genes. The two genes seem to be transcribed in these mutants.     

Deletion mapping of mitochondrial transfer RNA genes in Saccharomyces cerevisiae by means of cytoplasmic petite mutants

Summary Mitochondrial transfer RNA genes have been ordered relative to the position of five mitochondrial drug resistance markers, namely, chloramphenicol (C), erythromycin (E), oligomycin I and II (O_I, O_II), and paromomycin (P). Forty-six petite yeast clones that were genetically characterized with respect to these markers were used for a study of these relationships. Different regions of the mitochondrial genome are deleted in these individual mutants, resulting in variable loss of genetic markers. Mitochondrial DNA was isolated from each mutant strain and hybridized with eleven individual mitochondrial transfer RNAs. The following results were obtained: i) Of the seven petite clones that retained C, E, and P resistance markers (but not O_I or O_II), four carried all eleven transfer RNA genes examined; the other three clones lost several transfer RNA genes, probably by secondary internal deletion; ii) Prolyl and valyl transfer RNA genes were located close to the P marker, whereas the histidyl transfer RNA gene was close to the C marker; iii) Except for a glutamyl transfer RNA gene that was loosely associated with the O_I region, no other transfer RNA genes were found in petite clones retaining only the O_I and/or the O_II markers; and iv) Two distinct mitochondrial genes were found for glutamyl transfer RNA, they were not homologous in DNA sequence and were located at two separate loci.The data indicate that the petite mitochondrial genome is the result of a primary deletion followed by successive additional deletions. Thus an unequivocal gene arrangement cannot be readily established by deletion mapping with petite mutants alone. Nevertheless, we have derived a tentative circular map of the yeast mitochondrial genome from the data; the map indicates that all but one of the transfer RNA genes are found between the C and P markers without forming a tight cluster. The following arrangement is suggested:-P-pro-val-ile-(phe, ala, tyr, asp)-glu₂-(lys-leu)-his-C-E-O_I-glu₁-O_II-P-.Supported in part by Cancer Center CCRC 111B-3. Present address: Laboratoire de Biologie Generale, Universite Paris-Sud Orsay, 91405, FranceThe Franklin McLean Memorial Research Institute is operated by the University of Chicago for the U.S. Energy Research and Development Administration under Contract E(11-1)69     

Assembly of the mitochondrial membrane system. Sequences of yeast mitochondrial tRNA genes

Two cytoplasmic "petite" (rho-) clones of Saccharomyces cerevisiae have been selected for the retention of the aspartic acid tRNA gene. The two clones, designated DS200/A102 and DS200/A5, have tandemly repeated segments of mitochondrial DNA (mtDNA) with unit lengths of 1,000 and 6,400 base pairs, respectively. The DS200/A102 genome has a single tRNA gene with a 3'-CUG-5' anticodon capable of recognizing the 5'-GAC-3' and 5'-GAU-3' codons for aspartic acid. The mtDNA segment of DS200/A102 has been determined to represent the wild type sequence from 5.3 to 6.8 map units. The genome of DS200/A5 is more complex encompassing the region of wild type mtDNA from 3.5 to 12.7 units. A continuous sequence has been obtained from 3.5 to 8.6 units. In addition to the aspartic acid tRNA, this region codes for the tRNAUGCAla,tRNAUCUArg, tRNAACGArg, tRNAGCUSer,tRNAUCCGly and tRNAUUULys. The DNA sequence of the DS200/A5 genome has allowed us to deduce the secondary structures of the seven tRNAs and to assign precise map positions for their genes. All the tRNAs except tRNA GUCAsp exhibit most of the invariant features of prokaryotic and eukaryotic tRNAs. The aspartic acid tRNA has unusual D and T psi C loops. The structure of this tRNA is similar to the mitochondrial initiator tRNA of Neurospora crassa (Heckman, J.E., Hecker, L.I., Shwartzbach, S.D., Barnett, W.E., Baumstark, B., and RajBhandary, U.L. Cell 13, 83-95).     

Heterogeneity of mitochondrial DNA from Saccharomyces cerevisiae and genetic information for tRNA.

Mitochondrial DNA from wild-type Saccharomyces cerevisiae and from an "extreme" petite mutant were analyzed by hybridization of several tRNAs on DNA fragments of different buoyant density, obtained by sonication and fractionation on a CsCl gradient. The hybridization patterns show that the genes for tRNAser, tRNAphe, tRNAhis, tRNAval, tRNAileu are present on wild-type mitochondrial DNA, while only genes for tRNAser and tRNAhis are present on petite mitochondrial DNA; moreover the hybridization patterns indicate that these genes are not clustered and suggest that more than one gene might exist for tRNAser and tRNAhis.     

A mutation in a mitochondrial ABC transporter results in mitochondrial dysfunction through oxidative damage of mitochondrial DNA

We have isolated a Saccharomyces cerevisiae mutant that shows an increased tendency to form cytoplasmic petites (respiration-deficient ρ⁻ or ρ⁰ mutants) in response to treatment of cells growing on a solid medium with the DNA-damaging agent methyl methanesulfonate or ultraviolet light. The mutation in this strain, atm1-1, was found to cause a single amino acid substitution in ATM1, a nuclear gene that encodes the mitochondrial ATP-binding cassette (ABC) transporter. When the mutant cells were grown in liquid glucose medium, they accumulated free iron within the mitochondria and at the same time gave rise to spontaneous cytoplasmic petite mutants, as seen previously in cells carrying a mutation in a gene homologous to the human gene responsible for Friedreich's ataxia. Analysis of the effects of free iron and malonic acid (an inhibitor of oxidative respiration in mitochondria) on the incidence of petites among the mutant cells indicated that spontaneous induction of petites was a consequence of oxidative stress rather than a direct effect of either a defect in the ATM1 gene or the accumulation of free iron. We observed an increase in the incidence of strand breaks in the mitochondrial DNA of the atm1-1 mutant cells. Furthermore, we found that rates of induction of petites and accumulation of strand breaks in mitochondrial DNA were enhanced in the atm1-1 mutant by the introduction of another mutation, mhr1-1, which results in a deficiency in mitochondrial DNA repair. These observations indicate that spontaneous induction of petites in the atm1-1 mutant is a consequence of oxidative damage to mitochondrial DNA mediated by enhanced accumulation of mitochondrial iron. Received: 26 March 1999 / Accepted: 29 June 1999     

Induction of respiratory incompetent mutants by unsaturated fatty acid depletion in Saccharomyces cerevisiae

Constant levels of cellular unsaturated fatty acids were obtained by growing a fatty acid desaturase mutant of $\text{Saccharomyces cerevisiae}$ in glucose limited chemostat cultures supplemented with various concentrations of Tween 80. An increase in the frequency of cytoplasmic respiratory incompetent mutants was observed in cultures growing at low cellular levels of unsaturated fatty acids. This effect has been shown to result from an increase in the rate of mutation as the cellular unsaturated fatty acid level is decreased. The majority of induced petite mutants are ?° (contain no mitochondrial DNA).     

Mapping of mitochondrial structural genes in Neurospora crassa

A hybridization method has been employed to study the organization of the mitochondrial genome of Neurospora crassa. The method involves the use of 5' end-labeled single-stranded restriction fragments obtained from cytoplasmic "petite" strains of Saccharomyces cerevisiae known to contain single mitochondrial genes. The presence and localization of genes homologous to Subunits 1, 2, and 3 of cytochrome oxidase, cytochrome b and Subunit 6 of the ATPase is thus established for the mitochondrial genome of N. crassa.     

Undermethylated transfer ribonucleic acid from a relaxed strain of Bacillus subtilis: construction of the strain and analysis of the transfer ribonucleic acid.

A strain of Bacillus subtilis is described from which undermethylated transfer ribonucleic acid (tRNA) can be obtained. The tRNA's from a methionine-limited culture were compared with those from a control culture with respect to general nucleoside composition, methylated components, and amino acid acceptor activity. The undermethylated tRNA's had the normal amounts of the four major nucleosides, pseudouridine, and 5-methyluridine (ribothymidine), but were deficient in methylated nucleosides other than 5-methyluridine. These methyl-deficient nucleosides can be fully remethylated in the presence of the appropriate methylases. Since the majority of the work characterizing undermethylated tRNA's has been done using Escherichia coli, the work with B. subtilis presents some interesting comparisons and offers an alternative substrate for methylase studies.     

Separation of isoacceptor cysteine transfer ribonucleic acids of bakers' yeasts

Summary Isoacceptor species of certain amino acidspecific transfer ribonucleic acids (tRNAs) were fractionated by gel permeation chromatography using Sephadex G-100. The separation is attributed to the 20% ethanol-1% NaCl solvent and to the characteristics of Sephadex. Isoacceptor tRNAs specific for cysteine, arginine, phenylalanine, and histidine were recovered from commercial tRNA of yeast by this method. Highly purified cysteine-specific tRNA, obtained by a method which would not be expected to separate isoacceptor molecules when fractionated by this procedure, was shown to contain two cysteine isoacceptor tRNAs.This investigation was supported in part by Public Health Service Research Grant AM-09131 from the National Institute of Arthritis and Metabolic Diseases.     

3种水稻线粒体tRNA~(Trp)突变体的克隆和活力鉴定

 设计并完成了 3种水稻线粒体tRNATrp的突变 ,体外转录并用枯草杆菌和人色氨酰tRNA合成酶 (TrpRS)对tRNATrp及其突变体进行了活力测定 .3种突变体的氨酰化活力比野生型水稻线粒体tRNATrp分别上升了 1 8、1 5和 5倍 .说明A1 U72和G5 C68对于提高线粒体tRNATrp被细胞质TrpRS氨酰化能力的作用并不大 ,细胞质tRNATrp与细胞质TrpRS的识别方式并不适用于线粒体tRNATrp与细胞质TrpRS的相互识别 .研究结果对于了解线粒体tRNATrp和细胞质TrpRS的相互识别及药物设计有重要意义     

Tumor-associated mutations of rat mitochondrial transfer RNA genes.

Mitochondrial DNA is a sensitive target of chemical carcinogens (Backer and Weinstein (1980) Science 209, 297-299), suggesting that mutations of the mitochondrial genome occur in tumor cells. We examined this point by comparing mitochondrial DNA sequences in four rat tumors with those of normal rat liver. Some novel mutations found in the tRNA genes of tumor mitochondria were as follows: nucleotides deletions in the aminoacyl-acceptor stem of the tRNATyr gene or in the anticodon stem of the tRNATrp gene and insertions in the "YpsiC" loop of the tRNACys gene. These structures are extraordinary compared with those of the tRNA genes of other mammals, indicating that these mutations are each associated with a corresponding tumor.