The effect of hypermethylation on the functional properties of transfer ribonucleic acid. Ribosome-binding and polypeptide synthesis

1. Phenylalanyl-tRNA formed after chemical hypermethylation of Escherichia coli B tRNA was able to bind to ribosomes with the same efficiency as normal phenylalanyl-tRNA. 2. Under incubation conditions used in the ribosome-binding assay, hypermethylation of tRNA did not measurably decrease the stability of either inter-nucleotide phosphodiester bonds or the covalent bond between amino acid and tRNA in phenylalanyl-tRNA. 3. The ability of hypermethylated tRNA to take part in polyphenylalanine synthesis was inhibited progressively as the degree of hypermethylation increased. 4. Hypermethylation of tRNA affected polyphenylalanine synthesis at the stage of amino acid recognition and at a further point in the synthesis but not at the level of codon-anticodon recognition. 5. The formation of polylysine was more seriously affected by hypermethylation of tRNA than would be accounted for by inhibition of amino acid acceptance alone. 6. Polyproline formation was completely inhibited by the presence of 7mol% excess of methyl groups in tRNA. 7. The possibility of a link between amino acid acceptance and ribosome-binding was suggested for phenylalanyl-tRNA, but not for lysyl- or prolyl-tRNA.     

The postnatal methylation of transfer ribonucleic acid in brain. Evidence for the methylation of precursor transfer ribonucleic acid.

Incubation of 3-day-old rat brain with L-[methyl-3H]methionine resulted in the rapid labeling of low-molecular-weight cytoplasmic RNA. Electrophoresis in 15% polyacrylamide gels provided evidence for the methylation of precursor tRNA molecules, and high-performance liquid chromatography demonstrated N2-methylguanine to be the predominant methylated base formed during the first 2 min of labelling.     

Possible inhibitory effect of teichoic acid on Bacillus subtilis transfer ribonucleic acid

1. tRNA of Bacillus subtilis was found to be variably contaminated with membrane teichoic acid. 2. Samples with high contents of teichoic acid showed no accepting activity for tRNA(Phe) and tRNA(Tyr). 3. Removal of teichoic acid restored accepting activity and fractions containing teichoic acid, separated on Sephadex G-150, inhibited the charging of tRNA(Tyr). 4. The presence of teichoic acid did not inhibit the charging of tRNA(His).     

Effects of estradiol on uterine ribonucleic acid metabolism. Assessment of transfer ribonucleic acid methylation.

Immature rats treated with estradiol for selected periods of time demonstrated both increased methylation of uterine transfer ribonucleic acid (tRNA) and methylase activities. Whereas the former parameter was assessed by incubating whole uteri with [methyl-14C]methionine and measuring the incorporation of isotope into the tRNA, methylase activity was obtained by measuring the rate of incorporation of methyl groups from S-adenosyl[methyl-14C]methionine into heterologous tRNA (Escherichia coli B) in the presence of uterine cytosol preparations (100,000g supernatants). Although increased methylation of tRNA during the estrogen response was demonstrated, additional studies indicated that these results were largely attributable to an increased rate of synthesis of tRNA rather than gross changes in either the type or amount of methylated constituents present. Evidence in this regard included the inability of estrogen treatment of alter significantly the (a) resulting patterns of methyl-14C-methylated constituents of uterine tRNA, (b) the extent ot which [2-14C]guanine residues, incorporated into tRNA, become methylated, (c) the extent of methylation of precursor tRNA in the absence of tRNA synthesis, and (d) the types of methylase activities expressed in vitro.