Organization and sequence of five tRNA genes and of an unidentified reading frame in the wheat chloroplast genome: evidence for gene rearrangements during the evolution of chloroplast genomes

Summary The genes for the initiator tRNA_CAU ^Met. tRNA_UCC ^Gly, tRNA_GGU ^Thr, tRNA_UUC ^Glu and tRNA_GUA ^Tyr and an open reading frame of 62 codons have been identified by sequencing a 2,358 by BamHl and a 1,378 by BamHI-Sst2 DNA fragments from wheat chloroplasts. A comparison of the organization of these five tRNA genes and of the open reading frame on the wheat, tobacco and spinach chloroplast genomes suggests that at least three genomic inversions must have occurred during the evolution of the wheat chloroplast genome from a spinach-like ancestor genome. Furthermore, it seems that in wheat the 91 by intergenic region between the genes for the initiator tRNA^Met and the gene for tRNA_UCC ^Gly is one end-point of the 20 kbp genomic inversion proposed by Palmer and Thompson in the case of maize (Palmer and Thompson 1982). A 119 bp duplication is located at this junction: the first copy comprises the 91 by of the intergenic region and the first 28 by of the tRNA^Met gene, the second copy is found downstream of the tRNA^Met gene.     

The essential Gcd10p–Gcd14p nuclear complex is required for 1-methyladenosine modification and maturation of initiator methionyl-tRNA

Gcd10p and Gcd14p are essential proteins required for the initiation of protein synthesis and translational repression of GCN4 mRNA. The phenotypes of gcd10 mutants were suppressed by high-copy-number IMT genes, encoding initiator methionyl tRNA (tRNA_i^Met), or LHP1, encoding the yeast homolog of the human La autoantigen. The gcd10-504 mutation led to a reduction in steady-state levels of mature tRNA_i^Met, attributable to increased turnover rather than decreased synthesis of pre-tRNA_i^Met. Remarkably, the lethality of a GCD10 deletion was suppressed by high-copy-number IMT4, indicating that its role in expression of mature tRNA_i^Met is the essential function of Gcd10p. A gcd14-2 mutant also showed reduced amounts of mature tRNA_i^Met, but in addition, displayed a defect in pre-tRNA_i^Met processing. Gcd10p and Gcd14p were found to be subunits of a protein complex with prominent nuclear localization, suggesting a direct role in tRNA_i^Met maturation. The chromatographic behavior of elongator and initiator tRNA^Met on a RPC-5 column indicated that both species are altered structurally in gcd10Δ cells, and analysis of base modifications revealed that 1-methyladenosine (m¹A) is undetectable in gcd10Δ tRNA. Interestingly, gcd10 and gcd14 mutations had no effect on processing or accumulation of elongator tRNA^Met, which also contains m¹A at position 58, suggesting a unique requirement for this base modification in initiator maturation.     

Two dimensional polyacrylamide gel electrophoresis analysis of Tetrahymena mitochondrial tRNA

Summary Two dimensional (2D) urea-polyacrylamide gel electrophoresis of tRNA isolated from Tetrahymena mitochondria separated at least 36 spots, while more than 45 major and minor spots were resolved with cytosolic tRNA. Co-electrophoresis of mitochondrial and cytosolic tRNAs revealed that many spots co-migrate. When radioactive mitochondrial tRNA was hybridized to mtDNA under various conditions and tRNA melted from the hybrid was analyzed by 2D gel electrophoresis, only 10 tRNA spots were found. Identified as mtDNA-encoded were 2 spots for tRNA^leu, 2 for tRNA^met, and 1 each for tRNA^phe, tRNAtrp and tRNA^tyr. The remaining three were unidentified. Mitochondrial tRNA spots that correspond to the tRNAs for arg, gly, ile, lys, ser, and val do not hybridize with mtDNA, and in gel positions they correspond to the cytoplasmic tRNA spots for the same respective amino acids. These mitochondrial tRNAs isolated from the gel can be acylated either by the mitochondrial or cytostolic enzymes. Mitochondrial tRNA isolated from a Tetrahymena cell homogenate which was pretreated with RNase A and Micrococcus nuclease exhibited the same 2D gel pattern as a nontreated control. Mitochondrial tRNAs from old and young cells showed generally similar tRNA spots in 2D gels, though more variable spots were seen with old cells. ³H-labeled whole-cell tRNA added to the cell homogenate prior to the mitochondrial isolation procedure did not remain associated with the final mitochondrial tRNA preparation. The present studies also showed mitochondrial tRNAs bound to the mitochondrial 80S monosome and polysome fractions. Radioactive tRNA added to the mitochondrial lysate does not adhere to the ribosomes, suggesting that the ribosome-bound tRNAs are not contaminating cytoplasmic tRNAs. These results are generally in good agreement with our previous data showing that only a small number of tRNAs are coded for by the mitochondrial DNA, while the others are a selected set of imported cytoplasmic tRNAs.     

Domains of initiator tRNA and initiation codon crucial for initiator tRNA selection by Escherichia coli IF3.

Initiation factors are used by Escherichia coli to select the initiator tRNA over elongator tRNAs during translation initiation. IF3 appears to "inspect" the anticodon end of the tRNA, probably along with the initiation codon. The anticodon stem and loop of the initiator tRNA, together with part of the initiation codon of the mRNA, can be thought of as a unit. Changes made in the anticodon stem, the anticodon loop, or the anticodon of an initiator tRNA fragment result in a loss of selection by IF3 in an in vitro assay for translation initiation. IF3 allows the selection of an initiator tRNA anticodon stem and loop fragment on GUG and UUG codons but does not select that tRNA fragment in response to AUU.     

Different mitochondrial gene orders among insects: exchanged tRNA gene positions in the COII/COIII region between an orthopteran and a dipteran species

Summary We have cloned and sequenced a 2.65 kb segment of the mtDNA molecule of the orthopteran insect Locusta migratoria. It harbors the genes for four mitochondrial tRNAs, for cytochrome c oxidase subunits II and III and for ATPase subunits 6 and 8. The order of the locust genes resembles that of Drosophila yakuba: in both insects the genes for C0II and ATPase 8 are separated from each other by the genes encoding tRNA^lys and tRNA^asp, but in the locust, the positions of the two tRNA genes are reversed. This leads to a different mitochondrial gene order in the two insects.     

Presence of a chloroplast-like elongator tRNAMet gene in the mitochondrial genomes of soybean and Arabidopsis thaliana

Summary The nucleotide sequence of elongator tRNA^Met genes from soybean chloroplast and mitochondria and Arabidopsis thaliana mitochondria have been determined. The mitochondrial tRNA^Met genes from soybean and A. thaliana are identical, and they differ from the soybean chloroplast tRNA^Met gene by only four nucleotides. Analysis of the flanking regions indicates that the mitochondrial tRNA^Met gene is not present on a large chloroplast DNA insertion in the mitochondrial genome, but it suggests that they have a common origin. Comparison of the three genes and the evolutionary implications are discussed.     

Efficient translation of the UAG termination codon in Candida species

Summary Clinical isolates of the dimorphic fungus Candida albicans encode a tRNA that, in a cell-free translation system prepared from the yeast Saccharomyces cerevisiae, efficiently translates the amber (UAG) termination codon. Unusually, the efficiency of this UAG read-through in the heterologous cell-free system is not further enhanced by polyamines. The suppressor tRNA is also able to efficiently translate the UAG codon in the rabbit reticulocyte cell-free system and with efficiencies approaching 100% in a homologous (C. albicans) cell-free system. That the suppressor tRNA is nuclear-encoded is demonstrated by the lack of activity in purified C. albicans mitochondrial tRNAs. Finally, UAG suppressor tRNA activity is also demonstrated in three other pathogenic Candida species, C. parapsilosis, C. guillermondii and C. tropicalis. These results suggest that some, but not all, Candida species have evolved an unusual nuclear genetic code in which UAG is used as a sense codon.     

MboI,ThaI and HinfI endonuclease cleavage maps of the yeast mitochondrial DNA

Summary MboI, HinfI and ThaI cleavage maps have been constructed for the region of the mitochondrial DNA from S. cerevisiae where transfer RNA genes are principally located. About 40 cleavage sites have been localized between the C and P genetic markers. The MboI map covers about 50% of the total mitochondrial genome. For constructing maps we have used a series of rho^– deletion mutants whose mitochondrial DNAs have a typical single deletion structure as judged by previous genetic and physical analyses. The mutant DNAs carry known transfer RNA genes and genetic markers and, therefore, the comparison between genetic and restriction maps has allowed us to localize individual transfer RNA genes within defined physical segments.Abbreviations bp base pairs - mtDNA mitochondrial DNA - tRNA transfer RNA - rRNA ribosomal RNA - ThaI formerly TacI     

Phenylalanine and tyrosine transfer RNAs encoded by Tetrahymena pyriformis mitochondrial DNA: primary sequence,post-transcriptional modifications,and gene localization

We have isolated Phe and Tyr tRNAs from Tetrahymena pyriformis mitochondria and have determined that these are "native" species, encoded by the mtDNA. A single gene for the tRNA(Phe) has been positioned 12-14 kbp from the left end of the linear Tetrahymena mtDNA, while duplicate tRNA(Tyr) genes have been localized within the inverted terminal repeats of this genome. Primary sequence analysis demonstrates that the tRNA(Tyr) has all of the characteristic primary and secondary structural features of a normal tRNA; however, the tRNA(Phe) displays several atypical features, including (i) replacement of the usual T psi sequence by UC, (ii) a U.U pair in the T psi C stem, and (iii) an extra 5'-nucleotide (U).     

Identification of an aspartate transfer RNA gene in maize mitochondrial DNA

Summary A gene for a transfer RNA (tRNA) specific for aspartic acid was identified in maize mitochondrial DNA. The nucleotide sequence and predicted secondary structure of this tRNA more closely resemble eubacterial and chloroplast aspartate tRNA genes than other mitocondrial aspartate tRNA genes. This gene is located on a 3,123 base pair EcoRl DNA fragment that also contains an elongator methionine tRNA gene. These two tRNA genes are separated by 726 nucleotides and are located on opposite strands of DNA.Paper No. 9755 of the Journal series of the North Carolina Agricultural Research Service, Raleigh     

A new gene encoding tRNAPro (GGG) is present in the chloroplast genome of black pine: a compilation of 32 tRNA genes from black pine chloroplasts

The chloroplast genome of black pine (Pinus thumbergii), a gymnosperm, contains 32 different tRNA genes, 30 of which correspond to those previously identified in tobacco and rice chloroplast genomes. Two additional genes encode tRNA^Pro (GGG) and tRNA^Arg (CCG); the former is newly identified while the latter is present in liverwort, Physcomitrella patens and Angiopteris lygodiifolia, chloroplast genomes. Moreover, a partial copy of the split tRNA^Gly (UCC) gene and full copies of tRNA^His (GUG), tRNA^Thr (GGU) and tRNA^Ser (GCU) genes are present in the large single-copy region of the genome, suggesting extensive rearrangements of the chloroplast genome during evolutio. No tRNA genes whose tRNA products can recognize codons CUU/C (Leu) and GCU/C (Ala) have been found. We propose that the 32 tRNAs are sufficient to read all the 61 sense codons in the black pine system using the two-out-of-three and the U:N wobble mechanisms.     

Codon usage,genetic code and phylogeny of Dictyostelium discoideum mitochondrial DNA as deduced from a 7.3-kb region

We have sequenced a region (7 376-bp) of the mitochondrial (mt) DNA (54 kb) of the cellular slime mold, Dictyostelium discoideum. From the DNA and amino-acid sequence comparisons with known sequences, genes for ATPase subunit 9 (ATP), cytochrome b (CYTB), NADH dehydrogenase subunits 1, 3 and 6 (ND1, ND3 and ND6), small subunit rRNA (SSU rRNA) and seven tRNAs (Arg, Asn, Cys, Lys, f-Met, Met and Pro) have been identified. The sequenced region of the mtDNA has a high average A+T-content (70.8%). The A+T-content of protein-genes (73.6%) is considerably higher than that of RNA genes (61.3%). Even with the strong AT-bias, the genetic code employed is most probably the universal one. All seven tRNAs are able to form typical clover leaf structures. The molecular phylogenetic trees of CYTB and SSU rRNA suggest that D. discoideum is closer to green plants than to animals and fungi.     

Fractionation and identification of Euglena gracilis cytoplasmic and chloroplastic tRNAs and mapping of tRNA genes on chloroplast DNA

Summary The cytoplasmic and chloroplast tRNAs of Euglena gracilis Z strain were fractionated by two-dimensional gel electrophoresis and identified by aminoacylation. Purified chloroplast tRNAs, labeled in vitro with |³²P|, were hybridized to endonuclease restriction fragments of chloroplast DNA, allowing the corresponding tRNA genes to be localized on the physical map of Euglena chloroplast DNA.     

Comparative analysis of the mitochondrial genomes of Chlamydomonas eugametos and Chlamydomonas moewusii

Summary We report the cloning and physical mapping of the mitochondrial genome of Chlamydomonas eugametos together with a comparison of the overall sequence structure of this DNA with the mitochondrial genome of Chlamydomonas moewusii, its closely related and interfertile relative. The C. eugametos mitochondrial DNA (mtDNA) has a 24 kb circular map and is thus 2 kb larger than the 22 kb circular mitochondrial genome of C. moewusii. Restriction mapping and heterologous fragment hybridization experiments indicate that the C. eugametos and C. moewusii mtDNAs are colinear. Nine cross-hybridizing restriction fragments common to the C. eugametos and C. moewusii mtDNAs, and spanning the entirety of these genomes, show length differences between homologous fragments which vary from 0.1 to 2.3 kb. A 600 bp subfragment of C. moewusii mtDNA, within one of these conserved fragments, showed no hybridization with the C. eugametos mtDNA. Of the 73 restriction sites identified in the C. eugametos and C. moewusii mtDNAs, five are specific to C. moewusii, eight are specific to C. eugametos and 30 are common to both species. Hybridization experiments with gene probes derived from protein-coding and ribosomal RNA-coding regions of wheat and Chlamydomonas reinhardtii mtDNAs support the view that the small and large subunit ribosomal RNA-coding regions of the C. eugametos and C. moewusii mtDNAs are interrupted and interspersed with each other and with protein-coding regions, as are the ribosomal RNA-coding regions of C. reinhardtii mtDNA; however, the specific arrangement of these coding elements in the C. eugametos and C. moewusii mtDNAs appears different from that of C. reinhardtii mtDNA.     

Physical mapping of the mitochondrial genome of the cultivated mushroom Agaricus brunnescens (= A. bisporus)

Summary Mitochondrial (mt) DNA from the commercial mushroom Agaricus brunnescens Peck [= A. bisporus (Lange) Imbach] was purified by cesium chloride/bisbenzimide gradient centrifugation. A physical map of the mtDNA fragments produced by BamHI, EcoRl, and PvuII digestion was generated by filter hybridizations with radiolabelled BamHI mtDNA probes. The A. brunnescens mtDNA was a circular molecule 136 kilo-basepairs (kbp) in length and contained an inverted repeat between 4.6 and 9.2 kbp in size. Orientational isomers of the mitochondrial genome were not detected. The positions of six genes were located on the A. brunnescens mtDNA map by heterologous hybridization. No coding function has yet been ascribed to the inverted repeat. The large rRNA gene was located on the smaller single copy region. The genes for cytochrome b, cytochrome oxidase (subunit III), ATPase (subunits 8 and 6) and the small rRNA were located on different regions of the larger single copy region.     

Regulatory elements in eIF1A control the fidelity of start codon selection by modulating tRNAiMet binding to the ribosome

eIF1A is the eukaryotic ortholog of bacterial translation initiation factor IF1, but contains a helical domain and long unstructured N-terminal tail (NTT) and C-terminal tail (CTT) absent in IF1. Here, we identify elements in these accessory regions of eIF1A with dual functions in binding methionyl initiator tRNA (Met-tRNA_i^Met) to the ribosome and in selecting AUG codons. A pair of repeats in the eIF1A CTT, dubbed Scanning Enhancer 1 (SE₁) and SE₂, was found to stimulate recruitment of Met-tRNA_i^Met in the ternary complex (TC) with eIF2·GTP and also to block initiation at UUG codons. In contrast, the NTT and segments of the helical domain are required for the elevated UUG initiation occurring in SE mutants, and both regions also impede TC recruitment. Remarkably, mutations in these latter elements, dubbed scanning inhibitors SI₁ and SI₂, reverse the defects in TC loading and UUG initiation conferred by SE substitutions, showing that the dual functions of SE elements in TC binding and UUG suppression are mechanistically linked. It appears that SE elements enhance TC binding in a conformation conducive to scanning but incompatible with initiation, whereas SI elements destabilize this conformation to enable full accommodation of Met-tRNA_i^Met in the P site for AUG selection.     

Assembly of the mitochondrial membrane system. Organization of yeast mitochondrial DNA in the Oli1 region

Summary The mitochondrial DNA (mtDNA) of a cytoplasmic petite mutant (DS401) of Saccharomyces cerevisiae genetically marked for the ATPase proteolipid, serine tRNA and varl genes has been characterized by restriction endonuclease analysis and DNA sequencing. The DS401 mtDNA segment is 5.3 kb long spanning the region between 79.1 and 86.8 units of the wild type genome. Most of the DS401 mtDNA consists of A+T rich sequences. In addition, however, there are ten short sequences with a high content of G+C and two sequences that have been identified as the ATPase proteolipid and the serine tRNA genes. The two genes map at 81 and 83 units and are transcribed from the same DNA strand. Even though there are other possible coding sequences in the DNA segment, none are sufficiently long to code for a gene product of the size of the varl protein. Based on the relative organization of the G+C rich clusters and genes, a model has been proposed for the processing of mitochondria) RNA. This model postulates the existence of mitochondrial double strand specific RNases that cleave the RNA at the G+C clusters.     

Chloroplast RNA polymerase genes of Chlamydomonas reinhardtii exhibit an unusual structure and arrangement

Summary Nucleotide sequence analysis of a 17043 basepair (bp) region of the Chlamydomonas reinhardtii plastome indicates the presence of three open reading frames (ORFs) similar to RNA polymerase subunit genes. Two, termed rpoB1 and rpoB2, are homologous to the 5-and 3-halves of the Escherichia coli beta subunit gene, respectively. A third, termed rpoC2, is similar to the 3-half of the bacterial beta' subunit gene. These genes exhibit several unusual features: (1) all three represent chimeric structures in which RNA polymerase gene sequences are juxtaposed in-frame with long sequences of unknown identity; (2) unlike their counterparts in plants and eubacteria, rpoB1 and rpoB2 are separated from rpoC2 by a long (7 kilobase-pair, kbp) region containing genes unrelated to RNA polymerase; (3) DNA homologous to the 5 half of rpoC (termed rpoC1 in other species) is not present at the 5 end of rpoC2 and could not be detected in C. reinhardtii chloroplast DNA. RNA expression could not be detected for any of the RNA polymerase genes, suggesting that they are pseudogenes or genes expressed at stages of the C. reinhardtii life-cycle not investigated. The three genes are flanked by GC-rich repeat elements. We suggest that repeat DNA-mediated chloroplast recombination events may have contributed to their unusual arrangement.     

The complete DNA sequence of the mitochondrial genome of the dermatophyte fungus Epidermophyton floccosum

We report here the complete nucleotide sequence of the 30.9-kb mitochondrial genome of the dermatophyte fungus Epidermophyton floccosum. All genes are encoded on the same DNA strand and include seven subunits of the reduced nicotinamide adenine dinucleotide ubiquinone oxireductase (nad1, nad2, nad3, nad4, nad4L, nad5, and nad6), three subunits of cytochrome oxidase (cox1, cox2, and cox3), apocytochrome b (cob), three subunits of ATP synthase (atp6, atp8, and atp9), the small and large ribosomal RNAs (rns and rnl), and 25 tRNAs. A ribosomal protein gene (rps5) is present as an intronic ORF in the large ribosomal subunit. The genes coding for cob and cox1 carry one intron and nad5 carries two introns with ORFs. The mtDNA of E. floccosum has the same gene order as Trichophyton rubrum mtDNA, with the exception of some tRNA genes. Maximum likelihood phylogenetic analysis confirms T. rubrum as a close relative of E. floccosum. This is the first complete mitochondrial sequence of a species of the order Onygenales. This sequence is available under GenBank accession number AY916130.     

Activities of Ligatin and MCT-1/DENR in eukaryotic translation initiation and ribosomal recycling

Eukaryotic translation initiation begins with ribosomal recruitment of aminoacylated initiator tRNA (Met-tRNA^Met_i) by eukaryotic initiation factor eIF2. In cooperation with eIF3, eIF1, and eIF1A, Met-tRNA^Met_i/eIF2/GTP binds to 40S subunits yielding 43S preinitiation complexes that attach to the 5′-terminal region of mRNAs and then scan to the initiation codon to form 48S initiation complexes with established codon–anticodon base-pairing. Stress-activated phosphorylation of eIF2α reduces the level of active eIF2, globally inhibiting translation. However, translation of several viral mRNAs, including Sindbis virus (SV) 26S mRNA and mRNAs containing hepatitis C virus (HCV)-like IRESs, is wholly or partially resistant to inhibition by eIF2 phosphorylation, despite requiring Met-tRNA^Met_i. Here we report the identification of related proteins that individually (Ligatin) or together (the oncogene MCT-1 and DENR, which are homologous to N-terminal and C-terminal regions of Ligatin, respectively) promote efficient eIF2-independent recruitment of Met-tRNA^Met_i to 40S/mRNA complexes, if attachment of 40S subunits to the mRNA places the initiation codon directly in the P site, as on HCV-like IRESs and, as we show here, SV 26S mRNA. In addition to their role in initiation, Ligatin and MCT-1/DENR can promote release of deacylated tRNA and mRNA from recycled 40S subunits after ABCE1-mediated dissociation of post-termination ribosomes.