New aspects in tRNA biosynthesis

The evolving tRNA molecule

The study of tRNA molecular evolution is crucial to understanding the origin and establishment of the genetic code as well as the differentiation and refinement of the machinery of protein synthesis in prokaryotes, eukaryotes, organelles, and phage systems. The small size of the molecule and its critical involvement in a multiplicity of roles distinguish its study from classical protein molecular evolution with respect to goals and methods. Here, the authors assess available and missing data, existing and needed methodology, and the impact of tRNA studies on current theories both of genetic code evolution and of the evolution of species. They analyze mutational "hot spots", the role of base modification, synthetase recognition, codon-anticodon interactions and the status of organelle tRNA.

Studies on tRNA adaptation, tRNA turnover, precursor tRNA and tRNA gene distribution in Bombyx mori by using two-dimensional polyacrylamide gel electrophoresis

Eighteen out of twenty amino acids have been used for identifying tRNAs from the silkworm Bombyx mori L. fractionated on two-dimensional polyacrylamide gel electrophoresis. 43 spots out of 53 have been identified. This mapping confirms previous results and brings new answers to some questions on the regulation of tRNA biosynthesis. 1. In addition to quantitative adaptation of tRNAs to the composition of silk proteins (fibroin from the posterior silk gland, sericin from the middle part) and of iso-tRNAs from posterior silk gland to the major codons of fibroin mRNA, we also observe adaptation of tRNA from various tissues to the average amino acid content of proteins from fat body, gut, gonads and carcass of the silkworm. 2. In the silk gland, turnover rates of several tRNA species are similar. The selective accumulation of tRNAs needed for decoding fibroin and sericin mRNAs which takes place during the Vth larval instar, cannot be explained by the occurrence of a preferential degradation of some tRNA species. 3. Under given conditions for incubating silk glands, it is possible to obtain an accumulation of precursor tRNA species, which are enriched in pre-tRNAAla and pre-tRNAGly in the posterior silk gland and pre-tRNASer in the middle part. 4. The distribution of tRNA genes is not random. tRNA genes for glycine, alanine and serine are prominent. Selective transcription of batteries of iso-tRNA genes could explain our data.

Replacement of pseudouridine in transfer RNA by 5-fluorouridine does not affect the ability to stimulate the synthesis of guanosine 5'-triphosphate 3'-diphosphate

The requirement for ribothymidine and pseudouridine in the TpsiCG loop of tRNA for its activity in the ribosome and tRNA-stimulated synthesis of guanosine 5'-triphosphate 3'-diphosphate (pppGpp) by stringent factor has been tested by the use of a purified tRNAPhe (883 pmol of phenylalanine incorporated/A260 unit) in which 92% of the pseudouridine, 98% of the ribothymidine, 98% of the dihydrouridine, and 88% of the uridines were substituted by 5-fluorouridine. This tRNA was quantitatively as active as control tRNA in inducing pppGpp synthesis. With loose-couple ribosomes, the concentration of tRNA needed to give half-maximal reaction was 0.07 micrometer for both normal and fluorouridine-substituted tRNA, with vacant tight-couple ribosomes it was 0.05 micrometer, and with tight couples carrying poly(Phe)-tRNA at the P site the value was 0.02 micrometer. These results show that at the level of intact tRNA there is no special requirement for modified bases in the TpsiCG loop of tRNA in the synthesis of pppGpp.

Specific ribonucleases involved in processing of tRNA precursors of Escherichia coli. Partial purification and some properties

Ribonucleases O and Q, the two putative nucleolytic activities which we detected previously in the crude extract from a thermosensitive ribonuclease P mutant (TS241) of Escherichia coli and which were shown to function in the processing of tRNA precursors in vitro, were partially purified from the 1000000 x g supernatant fraction of E. coli Q13. In the course of purification of these enzymes, the total RNAs synthesized in the thermosensitive mutant at the restrictive temperature were used as the substrates and the activities were identified from disappearance or alteration of specific tRNA precursor molecules in polyacrylamide gel electrophoresis. The purified ribonuclease O preparation cleaved specifically the multimeric tRNA precursors at the spacer regions. The purified ribonuclease Q preparation removed, in accordance with the definition of this enzyme, extra nucleotides from the 3'-terminal ends of monomeric tRNA precursors. Some properties of these two nucleases were investigated. In addition to these nucleases, another exonuclease (tentatively designated ribonuclease Y) and ribonuclease P, a well-characterized endonuclease, were also purified. The sequential mode of the processing of tRNA precursors, originally observed in the cleavage reactions with the crude extracts in vitro, was supported by studies with the purified enzyme preparations.

7-Methylguanine specific tRNA-methyltransferase from Escherichia coli

A 7-methylguanine (m7G) specific tRNA methyltransferase from E. coli MRE 600 was purified about 1000 fold by affinity chromatography on Sepharose bound with normal E. coli tRNA. The purified enzyme catalyzes exclusively the formation of m7G in submethylated bulk tRNA of E. coli K12 met- rel-. The purified enzyme transfers the methyl group from S-adenosyl-methionine to initiator tRNA of B. subtilis and 0.8 moles m7G residues are formed per mole tRNA. It is suggested that the enzyme specifically recognizes the extra arm unpaired guanylate residue.

The methylation of tRNA

The methylation of tRNA is a post-transcriptional modification which is achieved by specific enzymes, the tRNA methylases, with S adenosylmethionine as a methyl donor. The level and pattern of methylation are characteristic of the tRNA species and origin. Abnormally methylated tRNAs have been obtained, in vivo and in vitro, by a variety of methods, and their properties have been studied. The tRNA methylases are found in all cells and tissues. Their activity varies with the differentiation state of the cells, and under the influence of many internal and external factors ; it is especially elevated in embryonic and cancerous tissues. These enzymes are very unstable, and none of them has been purified to homogeneity. We present here their known properties and we propose a theory concerning their specificity. Finally, after reviewing the few available experimental data, we discuss the current hypotheses and speculations about the roles and functions of tRNA methylation.

A mutant of escherichia coli defective in removing 3' terminal nucleotides from some transfer RNA precursor molecules

The conversion of precursor RNA into bacteriophage T4 proline and serine transfer RNAs includes two steps for the enzymatic removal of nucleotides from the 3' ends of RNA chains. Neither of these steps occur following infection of a mutant of Escherichia coli that was previously shown to block the suppressor function of T4 serine transfer RNA. Cell-free extracts of this mutant are furthermore deficient in a wild type enzyme activity that removes nucleotides from the 3' ends of one of the RNA chains described above. The relation of this enzyme to other 3' ribonucleases is not known. We subsequently examined the mutant for its ability to support the biosynthesis of other bacteriophage transfer RNAs. In one instance that is analogous to the proline-serine precursor RNA, maturation of the precursor RNA was blocked during infection of mutant cells. In another instance, precursor RNA maturation was normal, even though this involved the removal of 3'nucleotides. These observations point to the possible existence of at least two 3' ribonucleases for the biosynthesis of transfer RNAs.

Isolation and partial characterization of three Escherichia coli mutants with altered transfer ribonucleic acid methylases

Seven transfer ribonucleic acid (tRNA) methylase mutants were isolated from Escherichia coli K-12 by examining the ability of RNA prepared from clones of unselected mutagenized cells to accept methyl groups from S-adenosylmethionine catalyzed by crude enzymes from wild-type cells. Five of the mutants had an altered uracil-tRNA methylase; consequently their tRNA's lacked ribothymidine. One mutant had tRNA deficient in 7-methylguanosine, and one mutant contained tRNA lacking 2-thio-5-methylaminomethyluridine. The genetic loci of the three tRNA methylase mutants were distributed over the E. coli genome. The mutant strain deficient in 7-methylguanosine biosynthesis showed a reduced efficiency in the suppression of amber mutations carried by T4 or lambda phages.