Yeast Asparagine (Asn) tRNA without Q Base Promotes Eukaryotic Frameshifting More Efficiently than Mammalian Asn tRNAs with or without Q Base

In this study, we compare the efficiency of Asn tRNA from mammalian sources with and without the highly modified queuosine (Q) base in the wobble position of its anticodon and Asn tRNA from yeast, which naturally lacks Q base, to promote frameshifting. Interestingly, no differences in the ability of the two mammalian Asn tRNAs to promote frameshifting were observed, while yeast tRNA^Asn_–Q promoted frameshifting more efficiently than its mammalian counterparts in both rabbit reticulocyte lysates and wheat germ extracts. The shiftability of yeast Asn tRNA is therefore not due, or at least not completely, to the lack of Q base and most likely the shiftiness resides in structural differences elsewhere in the molecule. However, we cannot absolutely rule out a role of Q base in frameshifting as wheat germ extracts and a lysate depleted of most of its tRNA and supplemented with calf liver tRNA contain both Asn tRNA with or without Q base.     

Nucleotide sequences of transfer RNA genes in the Pisum sativum chloroplast DNA

Summary Eight transfer RNA (tRNA) genes which were previously mapped to five regions of the Pisum sativum (pea) chloroplast DNA (ctDNA) have been sequenced. They have been identified as tRNA^Val(GAC), tRNA^Asn(GUU), tRNA^Arg(ACG), tRNA^Leu(CAA), tRNA^Tyr(GUA), tRNA^Glu(UUC), tRNA^His(GUG), and tRNA^Arg(UCU) by their anticodons and by their similarity to other previously identified tRNA genes from the chloroplast DNAs of higher plants or from E. gracilis. In addition,two other tRNA genes, tRNA^Gly (UCC) and tRNA^Ile(GAU), have been partially sequenced. The tRNA genes are compared to other known chloroplast tRNA genes from higher plants and are found to be 90–100% homologous. In addition there are similarities in the overall arrangement of the individual genes between different plants. The 5 flanking regions and the internal sequences of tRNA genes have been studied for conserved regions and consensus sequences. Two unusual features have been found: there is an apparent intron in the D-loop of the tRNA^Gly(UCC), and the tRNA^Glu(UUC) contains GATTC in its T-loop.     

The localization of tRNA 5 Asn,tRNAHis, and tRNAAla genes from Drosophila melanogaster by in situ hybridization to polytene salivary gland chromosomes

Transfer RNA _5; ^Asn , tRNA _; ^His , and tRNA^Ala were isolated from Drosophila melanogaster by means of Sepharose 4B chromatography and 2-dimensional polyacrylamide gel electrophoresis. The tRNAs were iodinated in vitro with Na¹²⁵I and hybridized in situ to salivary gland chromosomes from Drosophila. Subsequent autoradiography allowed the localization of the genes for tRNA _5; ^Asn in the regions 42A, 59F, 60C, and 84F; for tRNA^His in the regions 48F and 56E; and for tRNA^Ala in the regions 63A and 90C. From these and our previous results it can be concluded that the genes for the Q-base containing tRNAs (tRNA^Asn, tRNA^Asp, and tRNA^His, are not clustered in the Drosophila melanogaster genome.     

Anticodon-binding domain swapping in a nondiscriminating aspartyl-tRNA synthetase reveals contributions to tRNA specificity and catalytic activity

The nondiscriminating aspartyl-tRNA synthetase (ND-AspRS), found in many archaea and bacteria, covalently attaches aspartic acid to tRNA^Asp and tRNA^Asn generating a correctly charged Asp-tRNA^Asp and an erroneous Asp-tRNA^Asn. This relaxed tRNA specificity is governed by interactions between the tRNA and the enzyme. In an effort to assess the contributions of the anticodon-binding domain to tRNA specificity, we constructed two chimeric enzymes, Chimera-D and Chimera-N, by replacing the native anticodon-binding domain in the Helicobacter pylori ND-AspRS with that of a discriminating AspRS (Chimera-D) and an asparaginyl-tRNA synthetase (AsnRS, Chimera-N), both from Escherichia coli. Both chimeric enzymes showed similar secondary structure compared to wild-type (WT) ND-AspRS and maintained the ability to form dimeric complexes in solution. Although less catalytically active than WT, Chimera-D was more discriminating as it aspartylated tRNA^Asp over tRNA^Asn with a specificity ratio of 7.0 compared to 2.9 for the WT enzyme. In contrast, Chimera-N exhibited low catalytic activity toward tRNA^Asp and was unable to aspartylate tRNA^Asn. The observed catalytic activities for the two chimeras correlate with their heterologous toxicity when expressed in E. coli. Molecular dynamics simulations show a reduced hydrogen bond network at the interface between the anticodon-binding domain and the catalytic domain in Chimera-N compared to Chimera-D or WT, explaining its lower stability and catalytic activity.     

Nucleotide sequence and evolution of coding and noncoding regions of a quail mitochondrial genome

Summary Segments of the Japanese quail mito-chondrial genome encompassing many tRNA and protein genes, the small and part of the large rRNA genes, and the control region have been cloned and sequenced. Analysis of the relative position of these genes confirmed that the tRNA^Glu and ND6 genes in galliform mitochondrial DNA are located immediately adjacent to the control region of the molecule instead of between the cytochrome b and ND5 genes as in other vertebrates. Japanese quail and chicken display another distinctive characteristic, that is, they both lack an equivalent to the light-strand replication origin found between the tRNA^Cys and tRNA^Asn genes in all vertebrate mitochondrial genomes sequenced thus far. Comparison of the protein-encoding genes revealed that a great proportion of the substitutions are silent and involve mainly transitions. This bias toward transitions also occurs in the tRNA and rRNA genes but is not observed in the control region where transversions account for many of the substitutions. Sequence alignment indicated that the two avian control regions evolve mainly through base substitutions but are also characterized by the occurrence of a 57-bp deletion/addition event at their 5′ end. The overall sequence divergence between the two gallinaceous birds suggests that avian mitochondrial genomes evolve at a similar rate to other vertebrate mitochondrial DNAs.     

Mitochondrial tRNA gene clusters in Aspergillus nidulans: Organization and nucleotide sequence

The organization of tRNA genes on the circular 32 kb mitochondrial genome of the ascomycete Aspergillus nidulans has been studied by gel transfer hybridization and by DNA sequencing. Most of the tRNA genes are tightly clustered within two regions (1 kb each) flanking the split gene for the large ribosomal subunit RNA. The upstream cluster contains nine genes, the downstream cluster eleven genes. The twenty tRNA genes are on the same strand as the two rRNA genes and are separated from each other by AT-rich spacer sequences, usually consisting of only a few nucleotides. Two tRNA genes (leul and ala) are joined end to end. The occurrence of two tRNA^Gty genes is the first exception to the observation that in mitochondria all four-codon families are read by a single tRNA. Both genes are adjacent and show extensive sequence homology, suggesting relatively recent origin by gene duplication. The product of glyl has a U in the wobble position as do all other tRNA gene products specific for four-codon families, whereas the gly2 product, which has a rare A in the same position, should read only the codon GGU. The products of metl and thr have an A and G in positions 18 and 55, respectively, like the mitochondrial tRNA^fMet and tRNA^Thr of Neurospora crassa. Other unusual features are the replacement of the invariant G-C pair at positions 53 and 61 by A-T in met2, glyl and gly2, the replacement of the invariant T at position 8 by A in phe and G in pro and the deletion of a nucleotide at position 9 in ser2.     

Nucleotide sequence of Rattus norvegiens mitochondrial DNA that includes the genes for tRNAile, tRNAgln and tRNAf-met

The nucleotide sequence of a segment of mtDNA from Rattus norvegiens (rat) which contains the genes for tRNA^ile, tRNA^gl and tRNA^f-met has been determined. A detailed comparison has been made between this sequence and the corresponding sequences of mouse, human and bovine mtDNAs with regard to the primary and secondary structure of the tRNA genes, the regions connecting the tRNA genes, and the regions flanking the tRNA genes which code for the carboxyl terminus of URF-1 and the amino terminus of URF-2. No differences were found in the nucleotide sequences of the genes for tRNA^ile, tRNA^gln and tRNA^f-met in mtDNAs from three different female lines of rats (SASCO-1, SASCO-2 and Wild-UT) that differ by substitutions of 0.8% to 1.8% of their total nucleotides.     

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.