Characterization of a yeast mitochondrial locus necessary for tRNA biosynthesis. Deletion mapping and restriction mapping studies

Yeast mitochondrial DNA codes for a complete set of tRNAs. Although most components necessary for the biosynthesis of mitochondrial tRNA are coded by nuclear genes, there is one genetic locus on mitochondrial DNA necessary for the synthesis of mitochondrial tRNAs other than the mitochondrial tRNA genes themselves. Characterization of mutants by deletion mapping and restriction enzyme mapping studies has provided a precise location of this yeast mitochondrial tRNA synthesis locus. Deletion mutants retaining various segments of mitochondrial DNA were examined for their ability to synthesize tRNAs from the genes they retain. A subset of these strains was also tested for the ability to provide the tRNA synthesis function in complementation tests with deletion mutants unable to synthesize mature mitochondrial tRNAs. By correlating the tRNA synthetic ability with the presence or absence of certain wild-type restriction fragments, we have confined the locus to within 780 base pairs of DNA located between the tRNAMetf gene and tRNAPro gene, at 29 units on the wild-type map. Heretofore, no genetic function or gene product had been localized in this area of the yeast mitochondrial genome.     

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.     

Sequence analysis of two yeast mitochondrial DNA fragments containing the genes for tRNA Ser UCR and tRNA Phe UUY.

Two restriction enzyme fragments containing yeast mitochondrial tRNA genes have been characterized by DNA sequence analysis. One of these fragments is 320 base pairs long and contains a tRNA Ser gene. The corresponding tRNA SER was isolated from yeast mitochondria and its nucleotide sequence also was determined. This mitochondrial tRNA is 90 nucleotides in length, has a G + C content of 38%, and has UGA as the anticodon. A portion of a 680-base-pair DNA fragment containing a tRNA Phe gene was also sequenced. The portion of this gene which codes for the mature tRNA is 75 base pairs in length, has a G + C content of 33%, and contains the anticodon GAA. Neither gene contains an intervening sequence or codes for the 3' CCA terminus. Both are surrounded by regions of more than 90% A + T. The significance of these sequences is discussed.     

IBM microcomputer programs that analyze DNA sequences for tRNA genes

A set of four computer programs that search DNA sequence datafiles for transfer RNA genes have been written in IBM (Microsoft)BASIC for the IBM personal computer. These programs locate andplot predicted secondary structures of tRNA genes in the cloverleafconformation. The set of programs are applicable to eukaryotictRNA genes, including those containing intervening sequences,and to prokaryotic and mitochondrial tRNA genes. In addition,two of the programs search up to 150 residues downstream oftRNA gene sequences for possible eukaryotic RNA polymerase IIItermination sites comprised of at least four consecutive T residues.Molecular biologists studying a variety of gene sequences andflanking regions can use these programs to search for the additionalpresence of tRNA genes. Furthermore, investigators studyingtRNA gene structure-to-function relationships would not needto do extensive restriction mapping to locate tRNA gene sequenceswithin their cloned DNA fragments. Received on October 29, 1985; accepted on January 28, 1986     

草鱼(Ctenopharyngodon idellus)线粒体DNA控制区及其两侧tRNA基因的克隆与结构分析

动物线粒体ＤＮＡ控制区是线粒体基因组复制与基因表达的最主要的调控区．采用杂交和测序的方法对草鱼线粒体ＤＮＡ控制区进行定位、克隆并测定了控制区及其旁侧的ｔＲＮＡＰｈｅ、ｒＲＮＡＰｒｏ和ｒＲＮＡＴｈｒ三个基因的序列,与多种脊椎动物的相应序列进行了比较,并进行了结构分析．草鱼线粒体控制区全长９２７ｂｐ,含有与酵母和爪蟾线粒体启动子相似的序列,其ＣＳＢⅠ、ＣＳＢⅡ和ＣＳＢⅢ序列与其他几种动物的ＣＳＢ比较相当保守,ＴＡＳ与其回文基序可形成稳定的茎环结构,成为Ｈ－链复制的终止信号．草鱼线粒体ｔＲＮＡＰｈｅ、ｔＲＮＡＰｒｏ和ｔＲＮＡＴｈｒ可折叠成三叶草形二级结构,其基因具有许多不同于细胞质ｔＲＮＡ基因的结构特点,可能反映了线粒体ｔＲＮＡ与线粒体核糖体具有不寻常的作用方式     

Assembly of the mitochondrial membrane system: sequences of yeast mitochondrial valine and an unusual threonine tRNA gene.

The mitochondrial DNA segments of two independently isolated rho- clones of S. cerevisiae carrying a genetic marker for a threonine tRNA have been characterized by restriction endonuclease analysis and DNA sequencing. The DNA sequences of the two segments have been used to deduce the primary and secondary structures of the tRNA. The threonine tRNA is unusual in having a leucine anticodon (3'-GAU-5'). Despite the anomalous anticodon, the tRNA is proposed to function in mitochondrial protein synthesis. One of the rho- clones contains an additional coding sequence that has been identified as a valine tRNA genes have been located on the wild-type physical map and determined to be transcribed from two different strands.     

Isolation of yeast tRNALeu genes. DNA sequence of a cloned tRNALeu3 gene.

A library of cloned yeast DNA fragments generated by digestion of yeast DNA with the restriction endonuclease Bam HI has been screened by colony hybridization to total yeast [32P]tRNA. Four hundred colonies carrying yeast tRNA genes were isolated. By hybridization to 125I-tRNALeu3, we have isolated from this collection 14 colonies carrying fragments containing yeast tRNALeu genes. The size of the yeast Bam HI inserts ranged from 2.45 x 10(6) to 14 x 10(6) daltons. One of these fragments was mapped in detail by restriction endonuclease digestion and hybridization to 125I-tRNALeu3. The presence of a tRNALeu3 gene was confirmed by DNA sequence. The results indicate that the tRNALeu3 coding region is not co-linear with the tRNALeu3. An intervening tract of 33 base pairs interrupts the coding sequences 1 base pair past the anticodon coding region. The putative structure of a tRNALeu3 precursor is deduced in which the anticodon base pairs with residues from the intervening sequence.     

Lupin chloroplast and mitochondrial tRNA populations and their genes

Transfer RNAs isolated from lupin chloroplasts and mitochondria were compared by two-dimensional gel electrophoresis. Twenty chloroplast and 24 mitochondrial tRNA species were identified. The saturation hybridization between lupin chloroplast DNA and 125I-labelled lupin chloroplast tRNAs pointed to the presence of about 34 tRNA genes in lupin chloroplast DNA. The number of mitochondrial tRNA genes estimated by the same method was about 30 genes. EcoRI restriction digest of lupin mitochondrial DNA probed with 32P-labelled lupin mitochondrial tRNAs revealed only a small number of positive restriction fragments. Some of these mitochondrial restriction fragments hybridized with 32P-labelled chloroplast tRNA.     

Mapping and cloning of Neurospora crassa mitochondrial transfer RNA genes.

We have obtained collections of recombinant Escherichia coli plasmids containing restriction fragments of Neurospora crassa mitochondrial DNA cloned into pBR322. By hybridization of 32P end-labeled total mitochondrial tRNAs and seven different purified tRNAs to restriction digests of mitochondrial DNA and of recombinant plasmids carrying specific restriction fragments, we have located the tRNA genes on the mitochondrial DNA. We have found that the mitochondrial tRNA genes are present in two major clusters, one between the two ribosomal RNA genes and the second closely following the large rRNA gene. Only one of the two DNA strands within these clusters codes for tRNAs. All of the genes for the seven specific purified tRNAs examined--those for alanine, formylmethionine, leucine 1, leucine 2, threonine, tyrosine, and valine--lie within these clusters. Interestingly, the formylmethionine tRNA hybridizes to two loci within one of these gene clusters. We have obtained a fairly detailed restriction map of part of this cluster and have shown that the two "putative" genes for formylmethionine tRNA are not arranged in tandem but are separated by more than 900 base pairs and by at least two other tRNA genes, those for alanine and for leucine 1 tRNAs.     

Glutamate tRNA genes are adjacent to 5S RNA genes in Drosophila and reveal a conserved upstream sequence (the ACT-TA box).

In Drosophila melanogaster at least six transfer RNA genes are located adjacent to the 3' end of the 5S RNA gene cluster. Three of these have been sequenced and identified as coding for glutamate tRNA4. In the chromosome they are arranged as tandem repeats on the same DNA strand and transcribed in the same direction as is 5S DNA, towards the centromere. We have also identified a sequence, the ACT-TA box, that is highly conserved among the polymerase III transcribed genes. Usually the sequence is located at 37 +/- 8 base pairs upstream from the first nucleotide of the structural gene. A similar sequence is also observed upstream of yeast and silkworm tRNA genes and the mitochondrial tRNA genes of mouse and humans.     

Polymorphism in the structure of the yeast mitochondrial tRNA synthesis locus.

Yeast mitochondrial DNA contains a genetic locus, called the tRNA synthesis locus, which codes for information necessary for mitochondrial tRNA biosynthesis. A 9S RNA molecule coded by this locus is thought to be the trans-acting element required for the removal of 5' extensions from tRNA precursors. The DNA coding for this RNA maps to a region of mitochondrial DNA known to contain strain specific restriction site polymorphisms. Comparison of the tRNA synthesis locus in two such strains by sequence analysis demonstrates that the restriction enzyme polymorphisms are due to the deletion/insertion of a 50 base pair GC-rich element in the 5' flanking sequence of the 9S RNA coding region. There are also several differences between the 9S RNA coding region of these two strains which do not interfere with the tRNA synthesis function.     

Analysis of a drosophila tRNA gene cluster: two tRNALeu genes contain intervening sequences

A recombinant DNA phage containing a cluster of Drosophila melanogaster tRNA genes has been isolated and analyzed. The insert of this phage has been mapped by in situ hybridization to chromosomal region 50AB, a known tRNA site. Nucleotide sequencing of the entire Drosophila tRNA coding region reveals seven tRNA genes spanning 2.5 kb of chromosomal DNA. This cluster is separated from other tRNA regions on the chromosome by at least 2.7 kb on one side, and 9.6 kb on the other. Two tRNA genes are nearly identical and contain intervening sequences of length 38 and 45 bases, respectively, in the anticodon loop. These two genes are assigned to be tRNALeu genes because of significant sequence homology with yeast tRNA3Leu, and secondary structure homology with yeast tRNA3Leu intervening sequence. In addition, an 8 base sequence (AAAAUCUU) is conserved in the same location in the intervening sequences of Drosophila tRNALeu genes and a yeast tRNA3Leu gene. Similar sequenes occur in all other tRNAs containing intervening sequences. The remaining five genes are identical tRNAIle genes, which are also identical to a tRNAIle gene from chromosomal region 42A. The 5' flanking regions are only weakly homologous, but each set of isoacceptors contains short regions of strong homology approximately 20 nucleotides preceding the tRNA coding sequences: GCNTTTTG preceding tRNAIle genes; and GANTTTGG preceding tRNALeu genes. The genes are irregularly distributed on both DNA strands; spacing regions are divergent in sequence and length.     

Assembly of the mitochondrial membrane system: isolation of mitochondrial transfer ribonucleic acid mutants and characterization of transfer ribonucleic acid genes of Saccharomyces cerevisiae

A method is described for isolating cytoplasmic mutants of Saccharomyces cerevisiae with lesions in mitochondrial transfer ribonucleic acids (tRNA's). The mutants were selected for slow growth on glycerol and for restoration of wild-type growth by cytoplasmic "petite" testers that contain regions of mitochondrial deoxyribonucleic acid (DNA) with tRNA genes. The aminoacylated mitochondrial tRNA's of several presumptive tRNA mutants were analyzed by reverse-phase chromatography on RPC-5. Two mutant strains, G76-26 and G76-35, were determined to carry mutations in the cysteine and histidine tRNA genes, respectively. The cysteine tRNA mutant was used to isolate cytoplasmic petite mutants whose retained segments of mitochondrial DNA contain the cysteine tRNA gene. The segment of one such mutant (DS504) was sequenced and shown to have the cysteine, histidine, and threonine tRNA genes. The structures of the three mitochondrial tRNA's were deduced from the DNA sequence.     

Structural comparison of two yeast tRNA Glu 3 genes.

DNA sequences in a 1.7 kb Pst fragment from yeast have been determined. This fragment is part of a yeast 7.4 kb Hind III segment cloned ino pBR322 (pY 5). The fragment carries a single gene for a glutamate tRNA. The coding portion of this gene is identical in sequence to that of the tRNA Glu 3 gene from pY 20 [1]. The flanking regions differ in their sequences, but possible secondary structures within the 5'-flanking regions bear similar features. Sequence homologies between pY 5 and pY 20 were detected far outside the tRNA genes. More surprisingly, extended sequence homologies were seen between the flanking regions of the pY 20 tRNA Glu 3 gene and a tRNA Ser gene [2,3]. We have also checked the known tRNA genes for structural similarities. Hybridization studies indicate that portions of the Pst fragment are repeated within the yeast genome.