Genes for tRNAAsp,tRNAPro, tRNATyr and two tRNAsSer in wheat mitochondrial DNA

We have begun a systematic search for potential tRNA genes in wheat mtDNA, and present here the sequences of regions of the wheat mitochondrial genome that encode genes for tRNA^Asp (anticodon GUC), tRNA^Pro (UGG), tRNA^Tyr (GUA), and two tRNAs^Ser (UGA and GCU). These genes are all solitary, not immediately adjacent to other tRNA or known protein coding genes. Each of the encoded tRNAs can assume a secondary structure that conforms to the standard cloverleaf model, and that displays none of the structural aberrations peculiar to some of the corresponding mitochondrial tRNAs from other eukaryotes. The wheat mitochondrial tRNA sequences are, on average, substantially more similar to their eubacterial and chloroplast counterparts than to their homologues in fungal and animal mitochondria. However, an analysis of regions 150 nucleotides upstream and 100 nucleotides downstream of the tRNA coding regions has revealed no obvious conserved sequences that resemble the promoter and terminator motifs that regulate the expression of eubacterial and some chloroplast tRNA genes. When restriction digests of wheat mtDNA are probed with ³²P-labelled wheat mitochondrial tRNAs, <20 hybridizing bands are detected, whether enzymes with 4 bp or 6 bp recognition sites are used. This suggests that the wheat mitochondrial genome, despite its large size, may carry a relatively small number of tRNA genes.     

Platyhelminth mitochondrial DNA: Evidence for early evolutionary origin of a tRNAserAGN that contains a dihydrouridine arm replacement loop,and of serine-specifying AGA and AGG codons

Summary The nucleotide sequence of a segment of the mitochondrial DNA (mtDNA) molecule of the liver flukeFasciola hepatica (phylum Platyhelminthes, class Trematoda) has been determined, within which have been identified the genes for tRNA^ala, tRNA^asp, respiratory chain NADH dehydrogenase subunit I (ND1), tRNA^asn, tRNA^pro, tRNA^ile, tRNA^lys, ND3, tRNA^serAGN, tRNA^trp, and cytochromec oxidase subunit I (COI). The 11 genes are arranged in the order given and are all transcribed from the same strand of the molecule. The overall order of theF. hepatica mitochondrial genes differs from what is found in other metazoan mtDNAs. All of the sequenced tRNA genes except the one for tRNA^serAGN can be folded into a secondary structure with four arms resembling most other metazoan mitochondrial tRNAs, rather than the tRNAs that contain a TψC arm replacement loop, found in nematode mtDNAs. TheF. hepatica mitochondrial tRNA^serAGN gene contains a dihydrouridine arm replacement loop, as is the case in all other metazoan mtDNAs examined to date. AGA and AGG are found in theF. hepatica mitochondrial protein genes and both codons appear to specify serine. These findings concerningF. hepatica mtDNA indicate that both a dihydrouridine arm replacement loop-containing tRNA^serAGN gene and the use of AGA and AGG codons to specify serine must first have occurred very early in, or before, the evolution of metazoa.     

Nuclear and mitochondrial revertants of a yeast mitochondrial tRNA mutant

Summary We isolated revertants capable of respiration from the respiratory deficient yeast mutant, FF1210-6C/ 170, which displays greatly decreased mitochondrial protein synthesis due to a single base substitution at the penultimate base of the tRNA^Asp gene on mitochondrial (mt) DNA. Three classical types of revertant were identified: (1) same-site revertants; (2) intragenic revertants which restore the base pairing in the acceptor stem of the mitochondrial tRNA^Asp; and (3) extragenic suppressors located in nuclear DNA. In addition a fourth type of revertant was identified in which the mutant tRNA^Asp is amplified due to the maintenance of both the original mutant mtDNA and a modified form of the mutant mtDNA in which only a small region around the tRNA^Asp gene is retained and amplified. The latter form resembles the mtDNA in vegetative petite (rho ^-) strains which normally segregates rapidly from the wild-type mtDNA. Each revertant type was characterized genetically and by both DNA sequence analysis of the mitochondrial tRNA^Asp gene and analysis of the quantity and size of RNA containing the tRNA^Asp sequence. These results indicate that the mitochondrial tRNA^Asp of the mutant retains a low level of activity and that the presence of the terminal base pair in tRNA^Asp is a determinant of both tRNA^Asp function and the maintenance of wild-type levels of tRNA^Asp.     

A whole mitochondrial genome screening in a MELAS patient: A novel mitochondrial tRNA mutation

Mitochondrial encephalopathy, lactic acidosis and strokelike episodes (MELAS) syndrome is a mitochondrial disorder characterized by a wide variety of clinical presentations and a multisystemic organ involvement. In this study, we report a Tunisian girl with clinical features of MELAS syndrome who was negative for the common m.3243A>G mutation, but also for the reported mitochondrial DNA (mtDNA) mutations and deletions. Screening of the entire mtDNA genome showed several known mitochondrial variants besides to a novel transition m.1640A>G affecting a wobble adenine in the anticodon stem region of the tRNA^Val. This nucleotide was conserved and it was absent in 150 controls suggesting its pathogenicity. In addition, no mutations were found in the nuclear polymerase gamma-1 gene (POLG1). These results suggest further investigation nuclear genes encoding proteins responsible for stability and structural components of the mtDNA or to the oxidative phosphorylation machinery to explain the phenotypic variability in the studied family.     

Structure and Evolution of the Atypical Mitochondrial Genome of <Emphasis Type="Italic">Armadillidium vulgare</Emphasis> (Isopoda,Crustacea)

The crustacean isopod Armadillidium vulgare is characterized by an unusual ∼42-kb-long mitochondrial genome consisting of two molecules co-occurring in mitochondria: a circular ∼28-kb dimer formed by two ∼14-kb monomers fused in opposite polarities and a linear ∼14-kb monomer. Here we determined the nucleotide sequence of the fundamental monomeric unit of A. vulgare mitochondrial genome, to gain new insight into its structure and evolution. Our results suggest that the junction zone between monomers of the dimer structure is located in or near the control region. Direct sequencing indicated that the nucleotide sequences of the different monomer units are virtually identical. This suggests that gene conversion and/or replication processes play an important role in shaping nucleotide sequence variation in this mitochondrial genome. The only heteroplasmic site we identified predicts an alloacceptor tRNA change from tRNA^Ala to tRNA^Val. Therefore, in A. vulgare, tRNA^Ala and tRNA^Val are found at the same locus in different monomers, ensuring that both tRNAs are present in mitochondria. The presence of this heteroplasmic site in all sequenced individuals suggests that the polymorphism is selectively maintained, probably because of the necessity of both tRNAs for maintaining proper mitochondrial functions. Thus, our results provide empirical evidence for the tRNA gene recruitment model of tRNA evolution. Moreover, interspecific comparisons showed that the A. vulgare mitochondrial gene order is highly derived compared to the putative ancestral arthropod type. By contrast, an overall high conservation of mitochondrial gene order is observed within crustacean isopods.     

Nucleotide sequence of nine protein-coding genes and 22 tRNAs in the mitochondrial DNA of the sea starPisaster ochraceus

Summary We have cloned and sequenced over 9 kb of the mitochondrial genome from the sea starPisaster ochraceus. Within a continuous 8.0-kb fragment are located the genes for NADH dehydrogenase subunits 1, 2, 3, and 4L (ND1, ND2, ND3, and ND4L), cytochrome oxidase subunits I, II, and III (COI, COII, and COIII), and adenosine triphosphatase subunits 6 and 8 (ATPase 6 and ATPase 8). This large fragment also contains a cluster of 13 tRNA genes between ND1 and COI as well as the genes for isoleucine tRNA between ND1 and ND2, arginine tRNA between COI and ND4L, lysine tRNA between COII and ATPase 8, and the serine (UCN) tRNA between COIII and ND3. The genes for the other five tRNAs lie outside this fragment. The gene for phenylalanine tRNA is located between cytochrome b and the 12S ribosomal genes. The genes for tRNA^glu and tRNA^thr are 3 to the 12S ribosomal gene. The tRNAs for histidine and serine (AGN) are adjacent to each other and lie between ND4 and ND5. These data confirm the novel gene order in mitochondrial DNA (mtDNA) of sea stars and delineate additional distinctions between the sea star and other mtDNA molecules.     

Multiple sequence rearrangements accompanying the duplication of a tRNAPro gene in wheat mitochondrial DNA

In the course of isolating tRNA genes from wheat mtDNA, we have found the same tRNA^Pro gene in two different Hind III restriction fragments, H-P1 (0.7 kbp) and H-P2 (1.7 kbp). Sequences immediately flanking these duplicate genes are closely related, although not identical; sequence comparisons suggest that multiple rearrangements have occurred in the vicinity of the H-P2 tRNA^Pro gene, relative to the H-P1 version. The chimeric nature of H-P2 is emphasized by the presence of sequences that are also found upstream of the wheat mitochondrial 26S rRNA gene, as well as sequences derived from chloroplast DNA. Comparison of H-P2 with H-P1 plus upstream sequences provides some insight into possible molecular events that might have generated H-P2. In particular, such comparisons suggest a model in which the homologous sequences in H-P2 are seen to be derived from H-P1 plus upstream sequences as a result of an intragenomic, site-specific rearrangement event, followed by amplification of the product, its fixation in the mitochondrial genome, and subsequent sequence divergence (single base changes as well as insertions/deletions of up to 50 nucleotides). The results reported here implicate particular primary sequence motifs in certain of the rearrangements that characterize H-P2.     

Organization of the Mitochondrial Genome of a Deep-Sea Fish, Gonostoma gracile (Teleostei: Stomiiformes): First Example of Transfer RNA Gene Rearrangements in Bony Fishes

We determined the complete nucleotide sequence of the mitochondrial genome (except for a portion of the putative control region) for a deep-sea fish, Gonostoma gracile. The entire mitochondrial genome was purified by gene amplification using long polymerase chain reaction (long PCR), and the products were subsequently used as templates for PCR with 30 sets of newly designed, fish-universal primers that amplify contiguous, overlapping segments of the entire genome. Direct sequencing of the PCR products showed that the genome contained the same 37 mitochondrial structural genes as found in other vertebrates (two ribosomal RNA, 22 transfer RNA, and 13 protein-coding genes), with the order of all rRNA and protein-coding genes, and 19 tRNA genes being identical to that in typical vertebrates. The gene order of the three tRNAs (tRNA^Glu, tRNA^Thr, and tRNA^Pro) relative to cytochrome b, however, differed from that determined in other vertebrates. Two steps of tandem duplication of gene regions, each followed by deletions of genes, can be invoked as mechanisms generating such rearrangements of tRNAs. This is the first example of tRNA gene rearrangements in a bony fish mitochondrial genome. Received August 5, 1998; accepted February 19, 1999.     

Transfer RNA gene mapping studies on chloroplast DNA from Chlamydomonas reinhardii

Total tRNA of Chlamydomonas reinhardii was fractionated by 2-dimensional gel electrophoresis. Sixteen tRNAs specific for eleven amino acids could be identified by aminoacylation with Escherichia coli tRNA synthetases. Hybridization of these tRNAs with chloroplast restriction fragments allowed for the localization of the genes of tRNA^Tyr, tRNA^Pro, tRNA^Phe (2 genes), tRNA^Ile (2 genes) and tRNA^His (2 genes) on the chloroplast genome of C. reinhardii. The genes for tRNA^Ala (2 genes), tRNA^Asn and tRNA^Leu were mapped by using individual chloroplast tRNAs from higher plants as probes.     

Discrepancy in divergence of the mitochondrial and nuclear genomes ofDrosophila teissieri andDrosophila yakuba

Summary Restriction sites were compared in the mitochondrial DNA (mtDNA) molecules from representatives of two closely related species of fruit flies: nine strains ofDrosophila teissieri and eight strains ofDrosophila yakuba. Nucleotide diversities amongD. teissieri strains and amongD. yakuba strains were 0.07% and 0.03%, respectively, and the nucleotide distance between the species was 0.22%. Also determined was the nucleotide sequence of a 2305-nucleotide pari (ntp) segment of the mtDNA molecule ofD. teissieri that contains the noncoding adenine+thymine (A+T)-rich region (1091 ntp) as well as the genes for the mitochondrial small-subunit rRNA, tRNA^f-met, tRNA^gln, and tRNA^ile, and portions of the ND2 and tRNA^val genes. This sequence differs from the corresponding segment of theD. yakuba mtDNA by base substitutions at 0.1% and 0.8% of the positions in the coding and noncoding regions, respectively. The higher divergence due to base substitutions in the A+T-rich region is accompanied by a greater number of insertions/deletions than in the coding regions. From alignment of theD. teissieri A+T-rich sequence with those ofD. yakuba andDrosophila virilis, it appears that the 40% of this sequence that lies adjacent to the tRNA^ile gene has been highly conserved. Divergence between the entireD. teissieri andD. yakuba mtDNA molecules, estimated from the sequences, was 0.3%; this value is close to the value (0.22%) obtained from the restriction analysis, but 10 times lower than the value estimated from published DNA hybridization results. From consideration of the relationships of mitochondrial nucleotide distance and allozyme genetic distance found among seven species of theDrosophila melanogaster subgroup, the mitochondrial nucleotide distance observed forD. teissieri andD. yakuba is anomalously low in relation to the nuclear genetic distance.     

Transfer RNA genes associated with the 16S and 23S rRNA genes of Euglena chloroplast DNA

Hybridization studies of Euglena chloroplast ¹²⁵I-labeled tRNAs to restriction fragments of Euglena chloroplast DNA have shown that the spacer between the 16S and 23S rRNA genes, in two and possibly all three of the ribosomal DNA units, contains genes for tRNA^Ile and tRNA^Ala, whereas a tRNA gene (for either tRNA^Trp or tRNA^Glu) is located before probably all four 16S rRNA genes present on the chloroplast DNA molecule.     

Unlike in other monocotyledonous plants such as wheat and rice, the region containing the tRNA (UCC), tRNA (UCU) and CF1 ATPase α-subunit genes has not undergone recombination in the leek chloroplast DNA

The nucleotide sequence of a 1.1 kbp BamHI fragment of the leek chloroplast DNA (Allium porrum., fam. Liliaceae) has been determined. The fragment contains the 3' part of the tRNA^Gly (UCC) gene and the tRNA^Arg (UCU) gene on the same strand, and the 3' end of the atpA gene encoding the CF₁ ATPase α-subunit which is located on the opposite strand. The gene arrangement and nucleotide sequence of this fragment are similar to those of the corresponding region in the tobacco chloroplast DNA but differ significantly from what has been observed in other monocotyledonous plants such as wheat and rice, in which the region containing these genes has undergone intensive rearrangement.     

Evaluation of a novel 16S rRNA/tRNA mitochondrial marker for the identification and phylogenetic analysis of shrimp species belonging to the superfamily Penaeoidea

In this study, we infer the phylogenetic relationships within commercial shrimp using sequence data from a novel mitochondrial marker consisting of an approximately 530-bp region of the 16S ribosomal RNA (rRNA)/transfer RNA (tRNA)^Val genes compared with two other mitochondrial genes: 16S rRNA and cytochrome c oxidase I (COI). All three mitochondrial markers were considerably AT rich, exhibiting values up to 78.2% for the species Penaeus monodon in the 16S rRNA/tRNA^Val genes, notably higher than the average among other Malacostracan mitochondrial genomes. Unlike the 16S rRNA and COI genes, the 16S rRNA/tRNA^Val marker evidenced that Parapenaeus is more closely related to Metapenaeus than to Solenocera, a result that seems to be more in agreement with the taxonomic status of these genera. To our knowledge, our study using the 16S rRNA/tRNA^Val gene as a marker for phylogenetic analysis offers the first genetic evidence to confirm that Pleoticus muelleri and Solenocera agassizi constitute a separate group and that they are more related to each other than to genera belonging to the family Penaeidae. The 16S rRNA/tRNA^Val region was also found to contain more variable sites (56%) than the other two regions studied (33.4% for the 16S rRNA region and 42.7% for the COI region). The presence of more variable sites in the 16S rRNA/tRNA^Val marker allowed the interspecific differentiation of all 19 species examined. This is especially useful at the commercial level for the identification of a large number of shrimp species, particularly when the lack of morphological characteristics prevents their differentiation.     

Sequences of initiator and elongator methionine tRNAs in bean mitochondria

Summary Two bean mitochondria methionine transfer RNAs, purified by RPC-5 chromatography and two-dimensional gel electrophoresis, have been sequenced usingin vitro post-labeling techniques.One of these tRNAs^Met has been identified by formylation using anE. coli enzyme as the mitochondrial tRNA_F ^Met. It displays strong structural homologies with prokaryotic and chloroplast tRNA_F ^Met sequences (70.1–83.1%) and with putative initiator tRNA_m ^Met genes described for wheat, maize andOenothera mitochondrial genomes (88.3–89.6%).The other tRNA^Met, which is the mitochondrial elongator tRNA_F ^Met, shows a high degree of sequence homology (93.3–96%& with chloroplast tRNA_m ^Met, but a weak homology (40.7%) with a sequenced maize mitochondrial putative elongator tRNA_m ^Met gene.Bean mitochondrial tRNA_F ^Met and tRNA_m ^Met were hybridized to Southern blots of the mitochondrial genomes of wheat and maize, whose maps have been recently published (15, 22), in order to locate the position of their genes.     

Variations during leaf development of the relative amounts of two bean (Phaseolus vulgaris) chloroplast tRNAsPhe which differ in their minor nucleotide content

Bean (Phaseolus vulgaris cv. Saxa) chloroplasts contain two tRNA^Phe species, namely tRNA^Phe1 and tRNA^Phe2. By sequence determination, we show that tRNA^Phe2 is identical to the previously sequenced tRNA^Phe1 except for two undermodified nucleotides. By reversed-phase chromatography analyses, we demonstrate that the relative amounts of these two chloroplast tRNAs^Phe vary during leaf development: in etiolated leaves the undermodified tRNA^Phe2 only represents 15% of total chloroplast tRNA^Phe, during development and greening it increases to reach 60% in 8-day-old leaves, and it then decreases to 9% in senescing leaves.     

Isoaccepting mitochondrial glutamyl-tRNA species transcribed from different regions of the mitochondrial genome of Saccharomyces cerevisiae

Mitochondrial glutamyl-tRNA isolated from mitochondria of Saccharomyces cerevisiae was separated into two distinct species by re versed-phase chromatography. The migration of the two mitochondrial glutamyl-tRNAs (tRNA_I^Glu and tRNA_II^Glu) differed from that of two glutamyl-tRNA species found in the cytoplasm of a mitochondrial DNA-less petite strain. Both mitochondrial tRNAs hybridized with mitochondrial DNA. Three lines of evidence demonstrate that mitochondrial tRNA_I^Glu and tRNA_II^Glu are transcribed from different mitochondrial cistrons. First the level of hybridization of a mixture of the two tRNAs to mitochondrial DNA was equal to the sum of the saturation hybridization levels of each glutamyl-tRNA alone. Second, the two mitochondrial glutamyl-tRNAs did not compete with each other in hybridization competition experiments. Finally the tRNAs showed individual hybridization patterns with different petite mitochondrial DNAs.Hybridization of the tRNAs to mitochondrial DNA of genetically defined petite strains localized each tRNA with respect to antibiotic resistance markers. The two glutamyl-tRNA cistrons were spatially separated on the genetic map.     

Evolution of the noncoding regions inDrosophila mitochondrial DNA: Two intergenic regions

The sequences of the mitochondrial DNA (mtDNA) segment containing the two intergenic regions were determined for six species belonging to theDrosophila immigrans species group and compared to the corresponding segments ofDrosophila species which had been studied previously. We found remarkable differences in the evolutionary rates of the two intergenic regions. The Intergenic I region, which lies between thetRNA ^gln and thetRNA ^ile genes, was found to be highly conserved in terms of both size (30 ntp) and nucleotide sequence among the species studied. In contrast, the sequences of the Intergenic II region, which lies between thetRNA ^f-met and thetRNA ^ile genes, showed considerable variation. The size of the Intergenic II region ranged from 0 to 88 ntp, and accurate alignment was possible only among sequences from geographical strains or very closely related species in thenasuta species subgroup. The observed differences in conservation of the two mtDNA intergenic regions are discussed in light of functional constraints on mtDNA sequences.     

Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters. Received: 18 July 1997 / Accepted: 3 November 1997     

Homology between the ribosomal DNA of Escherichia coli and mitochondrial DNA preparations of maize is principally to sequences other than mitochondrial rRNA genes

E. coli ribosomal DNA has been used to probe maize mitochondrial DNA. It hybridizes primarily with chloroplast ribosomal DNA sequences and with fungal and bacterial sequences which may contaminate the mtDNA preparations. It also hybridizes to the chloroplast 16S ribosomal RNA gene sequence present in the mitochondrial genome (1) as well as to the mitochondrial 18S ribosomal RNA gene sequence. Weak sequence homology was detected between E. coli rDNA and the mitochondrial 26S ribosomal RNA gene.