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.     

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     

Mutations in mitochondrial tRNA genes: a frequent cause of neuromuscular diseases.

We have sequenced the tRNA genes of mtDNA from patients with chronic progressive external ophthalmoplegia (CPEO) without detectable mtDNA deletions. Four point mutations were identified, located within highly conserved regions of mitochondrial tRNA genes, namely tRNA(Leu)(UAG), tRNA(Ser)(GCU), tRNA(Gly) and tRNA(Lys). One of these mutations (tRNA(Leu)(UAG)) was found in four patients with different forms of mitochondrial myopathy. An accumulation of three different tRNA point mutations (tRNA(Leu)(UAG)), tRNA(Ser)(GCU) and tRNA(Gly) was observed in a single patient, suggesting that mitochondrial tRNA genes represent hotspots for point mutations causing neuromuscular diseases.     

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.     

Mitochondrial replication origin stability and propensity of adjacent tRNA genes to form putative replication origins increase developmental stability in lizards

Secondary structure stability of mitochondrial origins of light-strand replication (OL) presumably reduces delayed formation of light-strand initiating replication forks on the heavy strand. Delayed replication initiation prolongs single strandedness of the heavy strand. More mutations accumulate during the prolonged time spent single stranded. Presumably, delayed replication initiation and excess mutations affect mitochondrial biochemical processes and ultimately morphological outcomes of development at the whole-organism level. This predicts that developmental stability increases with OL secondary structure stability and with formation of OL-like structures by the five tRNA genes flanking recognized OLs. Stable OLs and high percentages of OL-resembling secondary structures of adjacent tRNA genes (predicted by Mfold) correlate positively with developmental stability in three lizard families (Anguidae, Amphisbaenidae, and Polychrotidae). Accounting for effects of the regular OL, Sfold-predicted OL-like propensity of the entire tRNA gene cluster (not of individual genes) correlates with increased developmental stability in Anguidae, also across the entire free-energy range of Boltzmann's distribution of secondary structures. In the fossorial Amphisbaenidae, the OL-like structure-forming propensity of tRNA genes correlates positively with developmental stability for the distribution's sub-optimally stable regions, and negatively for its optimally stable regions, suggesting the thermoregulated functioning of OL vs. flanking tRNA genes as replication origins. Results for polychrotid tRNA genes are intermediate. Anguid tRNA genes possibly function in addition to the regular OL. Mitochondrial tRNA genes may thus frequently acquire and lose the alternative OL function, without sequence (gene) duplication and loss of their primary function.     

Recruitment of mitochondrial tRNA genes as auxiliary variability markers for both intra- and inter-species analysis: The paradigm of brown hare (Lepus europaeus)

We sequenced and analyzed the mitochondrial tRNA(Thr) and tRNA(Pro) genes from brown hare (Lepus europaeus) individuals of different geographic distribution and we investigated the role of various nucleotide substitutions that were detected. We compared these tRNAs with the respective available mitochondrial tRNA genes sequences within Lepus species and among mammals. The mutations that were detected represent specific and conserved polymorphisms that do not seem to affect the structural and functional features that are required for participation of tRNA molecules in mitochondrial protein synthesis. These changes however, possibly reflect on the evolutionary background of the species, which is based on the high intra-genomic variability and the evolutionary dynamic of the mitochondrial DNA. In an attempt to compare the phylogeny that is based on these specific tRNA genes with the phylogeny that is produced from sequencing data of the mitochondrial variable loop, we came up with results that indicate similar phylogeographic clusters. This observation implies that the tRNA mutations that were used for the present study have been well tolerated during evolution and they define an additional genetic and biochemical tag that can be used for such studies. Based on this notion and according to our results, we propose that mitochondrial tRNA genes can be used as valuable auxiliary molecular markers for contemporaneous and linked biochemical and genetic analyses.     

Analysis of the regions coding for transfer RNAs in Kluyveromyces lactis mitochondrial DNA.

The major regions coding for the transfer RNA genes in the mitochondrial DNA of K. lactis were studied. Twenty one, out of a supposed twenty four tRNA genes were identified and localized with respect to other mitochondrial genes. Most of the tRNA genes were found in a cluster downstream of the large ribosomal RNA gene. The order of a few groups of genes is conserved with respect to S. cerevisiae and T. glabrata. The highly diverged intergenic sequences contained a large number of guanine-cytosine clusters which frequently formed long palindromic sequences.     

Sequence evolution of mitochondrial tRNA genes and deep-branch animal phylogenetics

Mitochondrial DNA sequences are often used to construct molecular phylogenetic trees among closely related animals. In order to examine the usefulness of mtDNA sequences for deep-branch phylogenetics, genes in previously reported mtDNA sequences were analyzed among several animals that diverged 20–600 million years ago. Unambiguous alignment was achieved for stem-forming regions of mitochondrial tRNA genes by virtue of their conservative secondary structures. Sequences derived from stem parts of the mitochondrial tRNA genes appeared to accumulate much variation linearly for a long period of time: nearly 100 Myr for transition differences and more than 350 Myr for transversion differences. This characteristic could be attributed, in part, to the structural variability of mitochondrial tRNAs, which have fewer restrictions on their tertiary structure than do nonmitochondrial tRNAs. The tRNA sequence data served to reconstruct a well-established phylogeny of the animals with 100% bootstrap probabilities by both maximum parsimony and neighbor joining methods. By contrast, mitochondrial protein genes coding for cytochrome b and cytochrome oxidase subunit I did not reconstruct the established phylogeny or did so only weakly, although a variety of fractions of the protein gene sequences were subjected to tree-building. This discouraging phylogenetic performance of mitochondrial protein genes, especially with respect to branches originating over 300 Myr ago, was not simply due to high randomness in the data. It may have been due to the relative susceptibility of the protein genes to natural selection as compared with the stem parts of mitochondrial tRNA genes. On the basis of these results, it is proposed that mitochondrial tRNA genes may be useful in resolving deep branches in animal phylogenies with divergences that occurred some hundreds of Myr ago. For this purpose, we designed a set of primers with which mtDNA fragments encompassing clustered tRNA genes were successfully amplified from various vertebrates by the polymerase chain reaction.Abbreviations AA stem amino acid-acceptor stem - AC stem anticodon stem - COI cytochrome oxidase subunit I - cytb cytochrome b - D stem dihydrouridine stem - MP maximum parsimony - mtDNA mitochondrial DNA - Myr million years - NJ neighbor joining - PCR polymerase chain reaction - Ti transition - T stem tC stem - Tv transversion Correspondence to: Y. Kumazawa