PLMItRNA, a database for tRNAs and tRNA genes in plant mitochondria: enlargement and updating

The current version of PLMItRNA has been realized to constitute a database for tRNA molecules and genes identified in the mitochondria of all green plants ( Viridiplantae ). It is the enlargement of a previous database originally restricted to seed plants [Ceci,L.R., Volpicella,M., Liuni,S., Volpetti,V., Licciulli,F. and Gallerani,R. (1999) Nucleic Acids Res., 27, 156-157]. PLMItRNA reports information and multialignments on 254 genes and 16 tRNA molecules detected in 25 higher plants (one bryophyta and 24 vascular plants) and seven green algae. PLMItRNA is accessible via the WWW at http://bio-WWW.ba.cnr.it:8000/srs6/     

PLMItRNA, a database for mitochondrial tRNA genes and tRNAs in photosynthetic eukaryotes

The PLMItRNA database for mitochondrial tRNA molecules and genes in VIRIDIPLANTAE: (green plants) [Volpetti,V., Gallerani,R., DeBenedetto,C., Liuni,S., Licciulli,F. and Ceci,L.R. (2000) Nucleic Acids Res., 28, 159-162] has been enlarged to include algae. The database now contains 436 genes and 16 tRNA entries relative to 25 higher plants, eight green algae, four red algae (RHODOPHYTAE:) and two STRAMENOPILES: The PLMItRNA database is accessible via the WWW at http://bio-www.ba.cnr.it:8000/PLMItRNA.     

PLMItRNA,a database on the heterogeneous genetic origin of mitochondrial tRNA genes and tRNAs in photosynthetic eukaryotes

The updated version of PLMItRNA reports information and multialignments on 609 genes and 34 tRNA molecules active in the mitochondria of Viridiplantae (27 Embryophyta and 10 Chlorophyta), and photosynthetic algae (one Cryptophyta, four Rhodophyta and two Stramenopiles). Colour-code based tables reporting the different genetic origin of identified genes allow hyper-textual link to single entries. Promoter sequences identified for tRNA genes in the mitochondrial genomes of Angiospermae are also reported. The PLMItRNA database is accessible at http://bighost.area.ba.cnr.it/PLMItRNA/.     

Structural analysis of Arabidopsis thaliana chromosome 3. I. Sequence features of the regions of 4,504,864 bp covered by sixty P1 and TAC clones.

Based on the physical map of Arabidopsis thaliana chromosome 3 previously constructed with CIC YAC, TAC, P1 and BAC clones (Sato, S. et al., DNA Res., 5, 163-168, 1998), a total of 60 P1 and TAC clones were sequenced, and the sequence features of the resulting 4,504,864 bp regions were analyzed by applying various computer programs for similarity search and gene modeling. As a result, a total of 1054 potential protein-coding genes were identified. The average density of the genes identified was 1 gene per 4066 bp. Introns were observed in 77% of the genes, and the average number per gene and the average length of the introns were 3.9 and 156 bp, respectively. These sequence features are essentially identical to those of chromosome 5 in our previous reports, but the gene density was slightly higher than that observed for chromosomes 2 and 4. The regions also contained 10 tRNA genes when searched by similarity to reported tRNA genes and the tRNA scan-SE program. The sequence data and information on the potential genes are available through the World Wide Web database KAOS (Kazusa Arabidopsis data Opening Site) at http://www.kazusa.or.jp/kaos/.     

The complete set of tRNA species in Nanoarchaeum equitans

The archaeal parasite Nanoarchaeum equitans was found to generate five tRNA species via a unique process requiring the assembly of seperate 5' and 3' tRNA halves [Randau, L., Munch, R., Hohn, M.J., Jahn, D. and Soll, D. (2005) Nanoarchaeum equitans creates functional tRNAs from separate genes for their 5'- and 3'-halves. Nature 433, 537-541]. Biochemical evidence was missing for one of the computationally-predicted, joined tRNAs designated as tRNA(Trp). Our RT-PCR and sequencing results identify this tRNA as tRNA(Lys) (CUU) joined at the alternative position between bases 30 and 31. We show that the intron-containing tRNA(Trp) was misidentified in the initial Nanoarchaeum equitans genome annotation [E. Waters et al. (2003) The genome of Nanoarchaeum equitans: insights into early archaeal evolution and derived parasitism. Proc. Natl. Acad. Sci. USA 100, 12984-12988]. Along with a previously unidentified joined tRNA(Gln) (UUG), Nanoarchaeum equitans exhibits 44 tRNAs and is enabled to read all 61 sense codons. Features unique to this set of tRNA molecules are discussed.     

tRNA nucleotide 47: an evolutionary enigma.

A previous analysis of tRNA sequences suggested a correlation between the absence of a nucleotide at position 47 (nt 47) in the extra loop and the presence of a U13:G22 base pair in the D-stem. We have evaluated the significance of this correlation by determining the in vivo activity of tRNAs containing either a C13:G22 or a U13:G22 pair in tRNA molecules with or without nt 47. Although this correlation might reflect some malfunction of tRNAs lacking nt 47, but containing the C13:G22, assays of the in vivo suppressor activity showed that this tRNA is actually more active than the tRNA with the features found in the database, i.e., a U13:G22 base pair and no nt 47. Moreover, analogous constructs with a GGC anticodon permitted the growth of an Escherichia coli strain deleted for tRNA(Ala)GGC genes equally well. On the other hand, long-term growth experiments with competing E. coli strains harboring the tRNA lacking nt 47, either with the C13:G22 or the U13:G22 base pair demonstrated that the U13:G22 tRNA overtook the C13:G22 strain even when the starting proportion of strains favored the C13:G22 strain. Thus, the preference for the U13:G22 tRNA lacking nt 47 in the sequence database is most likely due to factors that come into play during extended growth or latency rather than to the ability of the tRNA to engage in protein synthesis.     

Complete structure of the chloroplast genome of a legume, Lotus japonicus.

The nucleotide sequence of the entire chloroplast genome (150,519 bp) of a legume, Lotus japonicus, has been determined. The circular double-stranded DNA contains a pair of inverted repeats of 25,156 bp which are separated by a small and a large single copy region of 18,271 bp and 81,936 bp, respectively. A total of 84 predicted protein-coding genes including 7 genes duplicated in the inverted repeat regions, 4 ribosomal RNA genes and 37 tRNA genes (30 gene species) representing 20 amino acids species were assigned on the genome based on similarity to genes previously identified in other chloroplasts. All the predicted genes were conserved among dicot plants except that rpl22, a gene encoding chloroplast ribosomal protein CL22, was missing in L. japonicus. Inversion of a 51-kb segment spanning rbcL to rpsl6 (positions 5161-56,176) in the large single copy region was observed in the chloroplast genome of L. japonicus. The sequence data and gene information are available on our World Wide Web database at http://www.kazusa.or.jp/en/plant/database.html.     

Plant dicistronic tRNA-snoRNA genes: a new mode of expression of the small nucleolar RNAs processed by RNase Z

Small nucleolar RNAs (snoRNAs) guiding modifications of ribosomal RNAs and other RNAs display diverse modes of gene organization and expression depending on the eukaryotic system: in animals most are intron encoded, in yeast many are monocistronic genes and in plants most are polycistronic (independent or intronic) genes. Here we report an unprecedented organization: plant dicistronic tRNA-snoRNA genes. In Arabidopsis thaliana we identified a gene family encoding 12 novel box C/D snoRNAs (snoR43) located just downstream from tRNA(Gly) genes. We confirmed that they are transcribed, probably from the tRNA gene promoter, producing dicistronic tRNA(Gly)-snoR43 precursors. Using transgenic lines expressing a tagged tRNA-snoR43.1 gene we show that the dicistronic precursor is accurately processed to both snoR43.1 and tRNA(Gly). In addition, we show that a recombinant RNase Z, the plant tRNA 3' processing enzyme, efficiently cleaves the dicistronic precursor in vitro releasing the snoR43.1 from the tRNA(Gly). Finally, we describe a similar case in rice implicating a tRNA(Met-e) expressed in fusion with a novel C/D snoRNA, showing that this mode of snoRNA expression is found in distant plant species.     

Euglena gracilis chloroplast transfer RNA transcription units. Nucleotide sequence analysis of a tRNAThr-tRNAGly-tRNAMet-tRNASer-tRNAGln gene cluster

The arrangement and the nucleotide sequence of the tRNA genes in the 2.0-kilobase-pair EcoRI restriction fragment EcoQ of Euglena gracilis Klebs, strain Z Pringsheim chloroplast DNA have been determined. This fragment, cloned in pBR325 to form the plasmid pEZC300, contains five tRNA genes. The DNA insert of this plasmid, a known tRNA gene locus (Orozco, E.M., Jr., and Hallick, R.B. (1982) J. Biol. Chem. 257, 3258-3264) has been mapped by Southern gel analysis using a 32P-labeled oligodeoxynucleotide tRNA gene probe. The DNA sequence of 870 base pairs (bp) from EcoQ containing the entire tRNA gene locus was determined. The organization of this tRNA gene cluster on the E. gracilis chloroplast chromosome is tRNAUUGGln-14-BP spacer-RNAGCUSer-175-bp spacer-tRNACAUMet-12-bp spacer-tRNAGCCGly-5-bp spacer-tRNAUGUThr. The tRNAUUGGln and tRNAGCUSer gene sequences are of the opposite polarity as the other three gene sequences, but of the same polarity as the rRNA genes. The tRNAMet gene is a putative initiator tRNA. The five tRNA genes are separated and flanked by A-T-rich spacer sequences. This gene arrangement is consistent with the model that E. gracilis chloroplast tRNA genes are transcribed into multicistronic tRNA precursors. The DNA sequences have been used to deduce the primary and secondary structures of the tRNAs.     

Structural analysis of Arabidopsis thaliana chromosome 3. II. Sequence features of the 4,251,695 bp regions covered by 90 P1, TAC and BAC clones.

To deduce the entire sequence of the top arm of the Arabidopsis thaliana chromosome 3, the sequence determination was performed on a total of 90 P1, TAC and BAC clones chosen according to our sequencing strategy. Sequence features of the resulting 4,251,695 bp regions were analyzed with various computer programs for similarity search and gene modeling. As a result, a total of 941 potential protein-coding genes were identified. The average density of the genes identified was 1 gene per 4210 bp. Introns were observed in 73% of the genes, and the average number per gene and the average length of the introns were 3.6 and 159 bp, respectively. These sequence features are essentially identical to those of chromosomes 3 and 5 in our previous reports. The regions also contained 14 tRNA genes when searched by similarity to reported tRNA genes and the tRNA scan-SE program. The sequence data and information on the potential genes are available through the World Wide Web database KAOS (Kazusa Arabidopsis data Opening Site) at http://www.kazusa.or.jp/kaos/.     

Genes for tRNALys5 from Drosophila melanogaster.

The sequences of two cloned genes from Drosophila which hybridize with tRNALys5 are reported. One gene, in plasmid pDt39, has a sequence which corresponds to the sequence of tRNA. The other gene, in pDt59R, differs in three nucleotides pairs. Both plasmids are transcribed in vitro with extracts of Drosophila Kc cells to give full-sized tRNA precursors with four additional nucleotides at the 5'-end as well as truncated molecules containing 35 nucleotides. This premature termination occurs in a block of four T residues within the mature coding region. Sequences flanking the tRNA genes show little in common except for the blocks of five or more T-residues beyond the 3'-end of the gene. pDt39 hybridizes to 84AB on the polytene chromosomes of Drosophila and pDt59R hybridizes to 29A.     

Sequence Variation in the tRNA Genes of Human Mitochondrial DNA

Recent analyses have shown that nonsynonymous variation in human mitochondrial DNA (mtDNA) contains nonneutral variants, suggesting the presence of mildly deleterious mutations. Many of the disease-causing mutations in mtDNA occur in the genes encoding the tRNAs. Nucleotide sequence variation in these genes has not been studied in human populations, nor have the structural consequences of nucleotide substitutions in tRNA molecules been examined. We therefore determined the nucleotide sequences of the 22 tRNA genes in the mtDNA of 477 Finns and, also, obtained 435 European sequences from the MitoKor database. No differences in population polymorphism indices were found between the two data sets. We assessed selective constraints against various tRNA domains by comparing allele frequencies between these domains and the synonymous and nonsynonymous sites, respectively. All tRNA domains except the variable loop were more conserved than synonymous sites, and T stem and D stem were more conserved than the respective loops. We also analyzed the energetic consequences of the 96 polymorphisms recovered in the two data sets or in the Mitomap database. The minimum free energy (ΔG) was calculated using the free energy rules as implemented in mfold version 3.1. The ΔG’s were normally distributed among the 22 wild-type tRNA genes, whereas the 96 polymorphic tRNAs departed significantly from a normal distribution. The largest differences in ΔG between the wild-type and the polymorphic tRNAs in the Finnish population tended to be in the polymorphisms that were present at low frequencies. Allele frequency distributions and minimum free energy calculations both suggested that some polymorphisms in tRNA genes are nonneutral.Reviewing Editor: Dr. Rüdiger Cerff     

The anticodon and the D-domain sequences are essential determinants for plant cytosolic tRNA(Val) import into mitochondria

In higher plants, one-third to one-half of the mitochondrial tRNAs are encoded in the nucleus and are imported into mitochondria. This process appears to be highly specific for some tRNAs, but the factors that interact with tRNAs before and/or during import, as well as the signals present on the tRNAs, still need to be identified. The rare experiments performed so far suggest that, besides the probable implication of aminoacyl-tRNA synthetases, at least one additional import factor and/or structural features shared by imported tRNAs must be involved in plant mitochondrial tRNA import. To look for determinants that direct tRNA import into higher plant mitochondria, we have transformed BY2 tobacco cells with Arabidopsis thaliana cytosolic tRNA(Val)(AAC) carrying various mutations. The nucleotide replacements introduced in this naturally imported tRNA correspond to the anticodon and/or D-domain of the non-imported cytosolic tRNA(Met-e). Unlike the wild-type tRNA(Val)(AAC), a mutant tRNA(Val) carrying a methionine CAU anticodon that switches the aminoacylation of this tRNA from valine to methionine is not present in the mitochondrial fraction. Furthermore, mutant tRNAs(Val) carrying the D-domain of the tRNA(Met-e), although still efficiently recognized by the valyl-tRNA synthetase, are not imported any more into mitochondria. These data demonstrate that in plants, besides identity elements required for the recognition by the cognate aminoacyl-tRNA synthetase, tRNA molecules contain other determinants that are essential for mitochondrial import selectivity. Indeed, this suggests that the tRNA import mechanism occurring in plant mitochondria may be different from what has been described so far in yeast or in protozoa.     

Mamit-tRNA, a database of mammalian mitochondrial tRNA primary and secondary structures

Mamit-tRNA (http://mamit-tRNA.u-strasbg.fr), a database for mammalian mitochondrial genomes, has been developed for deciphering structural features of mammalian mitochondrial tRNAs and as a helpful tool in the frame of human diseases linked to point mutations in mitochondrial tRNA genes. To accommodate the rapid growing availability of fully sequenced mammalian mitochondrial genomes, Mamit-tRNA has implemented a relational database, and all annotated tRNA genes have been curated and aligned manually. System administrative tools have been integrated to improve efficiency and to allow real-time update (from GenBank Database at NCBI) of available mammalian mitochondrial genomes. More than 3000 tRNA gene sequences from 150 organisms are classified into 22 families according to the amino acid specificity as defined by the anticodon triplets and organized according to phylogeny. Each sequence is displayed linearly with color codes indicating secondary structural domains and can be converted into a printable two-dimensional (2D) cloverleaf structure. Consensus and typical 2D structures can be extracted for any combination of primary sequences within a given tRNA specificity on the basis of phylogenetic relationships or on the basis of structural peculiarities. Mamit-tRNA further displays static individual 2D structures of human mitochondrial tRNA genes with location of polymorphisms and pathology-related point mutations. The site offers also a table allowing for an easy conversion of human mitochondrial genome nucleotide numbering into conventional tRNA numbering. The database is expected to facilitate exploration of structure/function relationships of mitochondrial tRNAs and to assist clinicians in the frame of pathology-related mutation assignments.     

PLANT-PIs: a database for plant protease inhibitors and their genes

PLANT-PIs is a database developed to facilitate retrieval of information on plant protease inhibitors (PIs) and related genes. For each PI, links to sequence databases are reported together with a summary of the functional properties of the molecule (and its mutants) as deduced from literature. PLANT-PIs contains information for 351 plant PIs, plus several isoinhibitors. The database is accessible at http://bighost.area.ba.cnr.it/PLANT-PIs.     

tRNA genes of Streptomyces lividans: new sequences and comparison of structure and organization with those of other bacteria.

Three closely linked Streptomyces lividans tRNA genes encoding two tRNA(Lys)s and a tRNA(Gly) were cloned and sequences. The structure of tRNA(Gly) is unusual for eubacterial tRNAs. Including those in previous reports (R. Sedlmeier and H. Schmieger, Nucleic Acids Res. 18:4027, 1990, and R. Sedlmeier, G. Linti, K. Gregor, and H. Schmieger, Gene 132:125-130, 1993), 18 S. lividans tRNA genes were physically mapped on the chromosome of the closely related strain Streptomyces coelicolor A3(2). The structure and organization of tRNA genes of S. lividans and S. coelicolor are compared with those of Escherichia coli and Bacillus subtilis.