Evidence for a tRNA/rRNA interaction site within the peptidyltransferase center of the Escherichia coli ribosome

A nine-base oligodeoxyribonucleotide complementary to bases 2497-2505 of 23S rRNA was hybridized to both 50S subunits and 70S ribosomes. The binding of the probe to the ribosome or ribosomal subunits was assayed by nitrocellulose filtration and by sucrose gradient centrifugation techniques. The location of the hybridization site was determined by digestion of the rRNA/cDNA heteroduplex with ribonuclease H and gel electrophoresis of the digestion products, followed by the isolation and sequencing of the smaller digestion fragment. The cDNA probe was found to interact specifically with its rRNA target site. The effects on probe hybridization to both 50S and 70S ribosomes as a result of binding deacylated tRNA(Phe) were investigated. The binding of deacylated tRNA(Phe), either with or without the addition of poly(uridylic acid), caused attenuation of probe binding to both 50S and 70S ribosomes. Probe hybridization to 23S rRNA was decreased by about 75% in both 50S subunits and 70S ribosomes. These results suggest that bases within the 2497-2505 site may participate in a deacylated tRNA/rRNA interaction.     

Opal suppressor phosphoserine tRNA gene and pseudogene are located on human chromosomes 19 and 22, respectively

An opal suppressor phosphoserine tRNA gene and pseudogene have been isolated from a human DNA library and sequenced (O'Neill, V., Eden, F., Pratt, K., and Hatfield, D. (1985) J. Biol. Chem. 260, 2501-2508). Southern hybridization of human genomic DNA with an opal suppressor tRNA probe suggested that the gene and pseudogene are present in single copy. In this study, we have determined the chromosome location of the human gene and pseudogene by utilizing a 193-base pair fragment encoding the opal suppressor phosphoserine tRNA gene as probe to examine DNAs isolated from human-rodent somatic cell hybrids that have segregated human chromosomes. These studies show that the probe hybridized with two regions in the human genome; one is located on chromosome 19 and the second on chromosome 22. By comparing the restriction sites within these two regions to those previously determined for the human opal suppressor phosphoserine tRNA gene and pseudogene, we tentatively assigned the gene to chromosome 19 and the pseudogene to chromosome 22. These assignments were confirmed by utilizing a 350-base pair fragment which was isolated from the 5'-flanking region of the human gene as probe. This fragment hybridized only to chromosome 19, demonstrating unequivocally that the opal suppressor phosphoserine tRNA gene is located on chromosome 19. The flanking probe hybridized to a single homologous band in hamster and in mouse DNA to which the gene probe also hybridized, demonstrating that the 5'-flanking region of the opal suppressor tRNA gene is conserved in mammals. Restriction analysis of DNAs obtained from the white blood cells of 10 separate individuals demonstrates that the gene is polymorphic. This study provides two additional markers for the human genome and constitutes only the second set of two tRNA genes assigned to human chromosomes.     

Effect of the higher-order structure of tRNAs on the stability of hybrids with oligodeoxyribonucleotides: separation of tRNA by an efficient solution hybridization.

In the course of developing a method to purify a single tRNA species efficiently, we have examined hybridization efficiencies between some tRNAs and short oligodeoxyribonucleotide probes both by the filter and solution hybridization methods without denaturants. The hybridization efficiencies varied considerably among probes which are complementary to different regions of the tRNAs, although there was little efficiency variation in the probes toward DNA substrates including the same nucleotide sequence. This efficiency variation was shown to be due to tRNA-specific higher-order structures as well as a hypermodified nucleotide in the anticodon loop. Characterization of the tRNA-probe hybrids by both nondenaturing gel electrophoresis and chemical modification showed the existence of two stable hybridizing states as a function of ionic strength. Our results indicate that RNA molecules with a number of intramolecular base pairings are able to form stable hybrids with complementary sequences under nondenaturing conditions. On the basis of these data, an appropriate probe was designed to successfully purify yeast tRNA(Phe) by making a tRNA(Phe)-probe hybrid, which has a longer retention time in hydroxyapatite high performance liquid chromatography than the tRNA(Phe) itself.     

Isolation, characterization, and chromosomal location of the tRNA(Met) genes in Atlantic salmon (Salmo salar) and brown trout (Salmo trutta).

This work describes the isolation, characterization, and physical location of the methionine tRNA in the genome of Atlantic salmon (Salmo salar L.) and brown trout (Salmo trutta L.). An Atlantic salmon genomic library was screened using a tRNA(Met) probe from Xenopus laevis. Two cosmid clones containing the Atlantic salmon tRNA(Met) gene were isolated, subcloned and sequenced. The tRNA(Met) was mapped to metaphase chromosomes by fluorescence in situ hybridization (FISH). Chromosomal data indicated that the tDNA of methionine is tandemly repeated in a single locus in both species. Analysis of genomic DNA by Southern hybridization confirmed the tandem organization of this gene.     

The mitochondrial tRNAs of Trypanosoma brucei are nuclear encoded

The mitochondrial DNA of Trypanosoma brucei is organized as a catenated network of maxicircles and minicircles. The maxicircles are equivalent to the typical mitochondrial genome except that the genes for the mitochondrial tRNAs have not been identified by sequence analysis of the maxicircle DNA. The apparent absence of tRNA genes in the maxicircle DNA suggests that the mitochondrial tRNAs are encoded by either the minicircle or the nuclear DNA. In order to determine their genomic origin, we isolated and identified the mitochondrial tRNAs of T. brucei. We show that these mitochondrial tRNAs are truly mitochondrially located in vivo and that they are free from detectable contamination by cytosolic RNAs. By hybridization analysis, using mitochondrial tRNAs as the probe, we determined that the mitochondrial tRNAs are encoded by nuclear DNA. This implies that RNAs, like proteins, are imported into the mitochondria. We investigated the relationship between the cytosolic and the mitochondrial tRNA genes and show that there are unique cytosolic tRNA genes, unique mitochondrial tRNA genes, and tRNA genes which appear to be shared and whose products are therefore targeted to both the cytosol and the mitochondrion.     

Characterization of the yeast tRNA Ser genomic organization and DNA sequence.

Purified, isolated yeast tRNA Ser2 was used as a hybridization probe to estimate the number of tRNA Ser2 genes in the yeast genome. Molecular clones of several of the genes were obtained. Three examples were studied in detail with respect to their genomic organization, and DNA sequences were determined for them. There appear to be eleven tRNA Ser2 genes in the yeast genome. They are neither tandemly repeated, nor clustered with other tRNA genes. They contain no intervening sequences.     

Molecular cloning and characterization of a nuclear gene encoding a putative subunit of tRNA splicing endonuclease from Arabidopsis thaliana.

tRNA splicing endonuclease is required to produce mature tRNAs from intron-containing tRNA precursors. To characterize the structural features of plant endonuclease, we have isolated a cDNA and a corresponding genomic DNA clone from libraries of Arabidopsis thaliana which encode a putative subunit of the endonuclease. The gene product has an apparent mass of 27 kDa and contains a homologous domain of approximately 130 amino acids at the C-terminal region commonly found in other eucaryal and archaeal counterparts. Southern hybridization analysis of Arabidopsis genomic DNA utilizing the cDNA clone as probe indicates the presence of at least two related genes.     

Study on rRNA genes in Mycobacterium smegmatis

The number of rRNA genes in Mycobacterium smegmatis was examined by hybridization of BamHI and SalI digests of chromosomal DNA with 3'-end-labeled 5S, 16S, 23S rRNA and tRNA. Each RNA probe gave two hybridization bands. The PstI fragments of 6.6 kilobases were cloned to pBR322. The cloned DNA was characterized by restriction endonuclease mapping, DNA-RNA hybridization, and the R-loop technique.     

Higher-order structure of bovine mitochondrial tRNA(Phe) lacking the 'conserved' GG and T psi CG sequences as inferred by enzymatic and chemical probing.

Bovine mitochondrial (mt) phenylalanine tRNA (tRNA(Phe)), which lacks the 'conserved' GG and T psi YCG sequences, was efficiently purified by the selective hybridization method using a solid phase DNA probe. The entire nucleotide sequence of the tRNA, including modified nucleotides, was determined and its higher-order structure was investigated using RNaseT2 and chemical reagents as structural probes. The D and T loop regions as well as the anticodon loop region were accessible to RNaseT2, and the N-3 positions of cytidines present in the D and T loops were easily modified under the native conditions in the presence of 10mM Mg2+. On the other hand, the nucleotides present in the extra loop were protected from the chemical modification under the native conditions. From the results of these probing analyses and a comparison of the sequences of mitochondrial tRNA(Phe) genes from various organisms, it was inferred that bovine mt tRNA(Phe) lacks the D loop/T loop tertiary interactions, but does have the canonical extra loop/D stem interactions, which seem to be the main factor for bovine mt tRNA(Phe) to preserve its L-shaped higher-order structure.     

A cognate tRNA specific conformational change in glutaminyl-tRNA synthetase and its implication for specificity.

Conformational changes that occur upon substrate binding are known to play crucial roles in the recognition and specific aminoacylation of cognate tRNA by glutaminyl-tRNA synthetase. In a previous study we had shown that glutaminyl-tRNA synthetase labeled selectively in a nonessential sulfhydryl residue by an environment sensitive probe, acrylodan, monitors many of the conformational changes that occur upon substrate binding. In this article we have shown that the conformational change that occurs upon tRNA(Gln) binding to glnRS/ATP complex is absent in a noncognate tRNA tRNA(Glu)-glnRS/ATP complex. CD spectroscopy indicates that this cognate tRNA(Gln)-induced conformational change may involve only a small change in secondary structure. The Van't Hoff plot of cognate and noncognate tRNA binding in the presence of ATP is similar, suggesting similar modes of interaction. It was concluded that the cognate tRNA induces a local conformational change in the synthetase that may be one of the critical elements that causes enhanced aminoacylation of the cognate tRNA over the noncognate ones.     

Yeast amber suppressors corresponding to tRNA3Leu genes

Amber suppressors previously isolated from the yeast Saccharomyces cerevisiae and belonging to the same phenotypic class (Liebman et al., 1976) were assigned to nine different linkage groups named SUP52 through SUP60. One of these suppressors, SUP52, had been shown to cause the insertion of leucine and had been genetically mapped (Liebman et al., 1977). The following additional amber suppressors were mapped: SUP53 maps near the centromere of chromosome III closely linked to leu2; SUP54 maps on chromosome VII, 6 cM distal to trp5; SUP56 maps on chromosome I, 5.4 cM distal to ade1; SUP57 maps on chromosome VI, closely linked to met10; and SUP58 maps on the left arm of chromosome XI, loosely linked to met14. We show by protein analysis that like SUP52, the suppressors SUP53 through SUP56 are leucine-inserters. Furthermore, by hybridization with a cloned tRNA3Leu probe we demonstrate that at least SUP53, SUP54, SUP55 and SUP56 contain mutations in redundant tRNA3Leu genes because they each generate a new XbaI site in a DNA fragment encompassing a tRNA3Leu gene. These new XbaI sites are predicted by the known sequences of tRNA3Leu genes if the CAA anticodon mutates to the amber suppressing anticodon CTA. It is likely that each of the nine suppressors in this phenotypic class contain similar mutations in different tRNA3Leu genes since we find that there are approximately nine unlinked redundant copies of tRNA3Leu genes in haploid strains.     

Optimization of the hybridization-based method for purification of thermostable tRNAs in the presence of tetraalkylammonium salts

We found that both tetramethylammonium chloride (TMA-Cl) and tetra-ethylammonium chloride (TEA-Cl), which are used as monovalent cations for northern hybridization, drastically destabilized the tertiary structures of tRNAs and enhanced the formation of tRNA•oligoDNA hybrids. These effects are of great advantage for the hybridization-based method for purification of specific tRNAs from unfractionated tRNA mixtures through the use of an immobilized oligoDNA complementary to the target tRNA. Replacement of NaCl by TMA-Cl or TEA-Cl in the hybridization buffer greatly improved the recovery of a specific tRNA, even from unfractionated tRNAs derived from a thermophile. Since TEA-Cl destabilized tRNAs more strongly than TMA-Cl, it was necessary to lower the hybridization temperature at the sacrifice of the purity of the recovered tRNA when using TEA-Cl. Therefore, we propose two alternative protocols, depending on the desired properties of the tRNA to be purified. When the total recovery of the tRNA is important, hybridization should be carried out in the presence of TEA-Cl. However, if the purity of the recovered tRNA is important, TMA-Cl should be used for the hybridization. In principle, this procedure for tRNA purification should be applicable to any small-size RNA whose gene sequence is already known.     

Isolation and characterization of recombinant DNA plasmids carrying Drosophila tRNA genes.

Recombinant plasmids carrying Drosophila melanogaster tRNA genes were constructed by ligation of HindIII-cleaved Drosophila DNA to HindIII cut pBR322 DNA. 90 clones were isolated that contained genes for one or more of eleven tRNAs. 43 of the plasmids were characterized by a number of methods: restriction nuclease digestion; agarose gel electrophoresis; hybridization with individual, purified, 125I-labelled Drosophila tRNA molecules and in situ hybridization to Drosophila chromosomes. The results show that several different tRNA genes have been isolated which code for single, specific isoacceptors. The DNAs from 8 plasmids each hybridize to single sites on Drosophila polytene chromosomes. In addition, the data show examples of two different plasmids hybridizing to different loci coding for the same tRNA; this means that we have isolated representatives of tRNA genes which map at widely separated points on the Drosophila genome.     

Chromosomal assignment of a large tRNA gene cluster (tRNALeu,tRNAGln, tRNALys,tRNAArg, tRNAGly) to 17p13.1

Summary A cluster of tRNA genes (tRNA _UAG ^Leu , tRNA _CUG ^Gln , tRNA _UUU ^Lys , tRNA _UCU ^Arg ) and an adjacent tRNA _GCC ^Gly have been assigned to human chromosome 17p12–p13.1 by in situ hybridization using a 4.2 kb human DNA fragment for tRNA^Leu, tRNA^Gln, tRNA^Lys, tRNA^Arg, and, for tRNA^Gly, 1.3 kb and 0.58 kb human DNA fragments containing these genes as probes. This localization was confirmed and refined to 17p13.100–p13.105 using a somatic cell hybrid mapping panel. Preliminary experiments with the biotiny lated tRNA Leu, Gln, Lys, Arg probe and metaphase spreads from other great apes suggest the presence of a hybridization site on the long arm of gorilla (Gorilla gorilla) chromosome 19 and the short arm of orangutan (Pongo pygmaeus) chromosome 19 providing further support for homology between HSA17, GGO19 and PPY19.