Aminoacylation of four tRNA species in lupin (Lupinus luteus) cotyledons

During germination of lupin seeds, the levels of in-vivo tRNA aminoacylation increase in different ways, depending on the species of tRNA. Column chromatography of tRNA on reverse-phase-chromatography (RPC-5) has shown the presence of 4 peaks of isoleucyl-tRNA, 5 of leucyl-tRNA, 5 of lysyl-tRNA, 2 of tyrosyl-tRNA, and 4 of valyl-tRNA. Cochromatography of periodate treated and control tRNA preparations, labeled with radioactive amino acids, indicates identical aminoacylation in vivo of isoaccepting tRNAs during plant development. One isoacceptor of isoleucine tRNA changes its elution profile after periodate treatment.Abbreviation RPC-5 reverse-phase-chromatography     

Relationships Among Deoxyribonucleic Acid, Ribonucleic Acid, and Specific Transfer Ribonucleic Acids in Escherichia coli 15T− at Various Growth Rates

The levels of macromolecules in Escherichia coli 15T(-) growing in broth, glucose, succinate, and acetate media were determined to compare relationships among deoxyribonucleic acid (DNA), ribosomal ribonucleic acid (rRNA), transfer RNA (tRNA), and protein in cells at different growth rates. DNA and protein increased in relative amounts with decreasing growth rate; relative amounts of rRNA and tRNA decreased, tRNA making up a slightly larger proportion of RNA. For several amino acid-specific tRNAs studied, acceptor capacities per unit of DNA increased with increasing growth rate. The syntheses of tRNA and rRNA are regulated by similar, yet different, mechanisms. Chromatographic examination on columns of benzoylated diethylaminoethyl-cellulose of isoaccepting tRNAs for arginine, leucine, lysine, methionine, phenylalanine, serine, and valine did not reveal differences in the isoaccepting profiles for rapidly (broth culture) and slowly growing (acetate culture) cells. Therefore, isoacceptors for individual amino acids appear to be regulated as a group. Lower efficiencies of ribosomal function in protein synthesis can be explained, in part, by a low ratio of tRNA to the number of ribosomes available and by a decreasing concentration of tRNA with decreasing growth rate. Data on the tRNAs specific for seven amino acids indicate that the decreasing concentration of tRNA is a general event rather than a severe limitation of any one tRNA or isoaccepting tRNA.     

Analysis of Isoaccepting Transfer Ribonucleic Acid Species of Bacillus subtilis: Changes in Chromatography of Transfer Ribonucleic Acids Associated with Stage of Development

Changes in chromatographic profiles of tyrosyl-, leucyl-, tryptophanyl-, and lysyl-transfer ribonucleic acids (tRNAs) are presented as a function of the growth stage in Bacillus subtilis. All of the tRNA groups investigated expressed different temporal patterns of change in isoaccepting species. Tyrosyl-tRNAs were the earliest to change and were followed by changes in leucyl- and then tryptophanyl-tRNAs. Lysyl-tRNAs were unique in having two times of change: one early and one very late. As an aid in understanding the temporal aspect of tRNA alterations during sporulation, the chromatographic profiles of aminoacyl tRNAs from an early blocked asporogenous mutant were studied. The asporogenous mutant used was blocked at the axial filament stage, stage 0 of sporulation. Nevertheless, those tRNAs which showed differences between the spore and cells in exponential growth exhibited similar changes in the asporogenous mutant after 24 h of growth. The data suggest that several tRNA changes occur during development in B. subtilis but that the events leading to these changes are either independent of, or occur before, stage 0 of sporulation, except in the case of lysyl-tRNA.     

Presence and Function of Sulfur-containing Transfer Ribonucleic Acid of Bacillus subtilis

Bacillus subtilis transfer ribonucleic acid (tRNA) was analyzed for the occurrence of thionucleotides by in vivo labeling with (35)S and fractionation by methylated albumin kieselguhr column chromatography. Alkaline hydrolysates of tRNA were also examined by column chromatography and paper electrophoresis, and the amino acid-accepting ability of thionucleotide-containing tRNA was tested after iodine oxidation. The results showed that B. subtilis tRNA contains 4-thiouridylate, a second nucleotide with properties similar to 2-thiopyrimidine, and a third unidentified thionucleotide. The amino acid-accepting ability for serine, tyrosine, lysine, and glutamic acid was markedly inhibited after oxidation of the tRNA with iodine, suggesting the presence of thionucleotides in these tRNA species. This inhibition could be reversed by thiosulfate reduction. The iodine treatment totally inactivated all lysine tRNA species, partially inactivated the serine tRNA species, and did not affect the accepting ability for valine. A comparison of tRNA from cells in the log and stationary phases and from spores revealed similar iodine inactivation patterns in all cases. The thionucleotide content in B. subtilis tRNA differed from that in Escherichia coli, both in extent and in distribution. A possible function of the thionucleotides in tRNA is discussed.     

Transfer RNATyr of melanoma tissues and cells: relevance to melanin synthesis?

The tRNA present in swine melanoma tumor tissue and normal gray skin tissue were compared by aminoacylation of the unfractionated tRNA preparations. Of the seventeen amino acids studied, seven showed differences in rate of acceptance to tRNAs from normal and tumor tissues; the tRNAs of two amino acids, tyrosine and glycine, showed dramatic three fold increases in melanoma tumor. As melanin biosynthesis proceeds from tyrosine oxidation the investigations focused on the increase in tyrosine tRNA. Kinetic analysis of tyrosine aminoacylation to normal and melanoma tRNAs revealed no differences. Analysis of the isoaccepting species of tRNATyr from normal skin and melanoma tumor tissues identified three isoacceptors; tRNATyr, represented the predominant species in normal gray skin, while tRNA2Tyr predominated in melanoma tumor tissue. The tyrosine acceptances by tRNAs from three human melanoma cell lines were analyzed and found to be variable, but isoaccepting species analysis of the tRNATyr of these three cell lines still showed a correlation between the preponderance of tRNA2Tyr and extent of tyrosine acceptance. Additionally the enzymatic activity for the oxidation of tyrosine was found to be related to tyrosine acceptance and tRNA2Tyr predominance..     

Transfer ribonucleic acid synthesis during sporulation and spore outgrowth in Bacillus subtilis studied by two-dimensional polyacrylamide gel electrophoresis.

The synthesis of transfer ribonucleic acid (tRNA) was examined during spore formation and spore outgrowth in Bacillus subtilis by two-dimensional polyacrylamide gel electrophoresis of in vivo 32P-labeled RNA. The two-dimensional gel system separated the B. subtilis tRNA's into 32 well-resolved spots, with the relative abundances ranging from 0.9 to 17% of the total. There were several spots (five to six) resolved which were not quantitated due to their low abundance. All of the tRNA species resolved by this gel system were synthesized at every stage examined, including vegetative growth, different stages of sporulation, and different stages of outgrowth. Quantitation of the separated tRNA's showed that in general the tRNA species were present in approximately the same relative abundances at the different developmental periods. tRNA turnover and compartmentation occurring during sporulation were examined by labeling during vegetative growth followed by the addition of excess phosphate to block further 32P incorporation. The two-dimensional gels of these samples showed the same tRNA's seen during vegetative growth, and they were in approximately the same relative abundances, indicating minimal differences in the rates of turnover of individual tRNA's. Vegetatively labeled samples, chased with excess phosphate into mature spores, also showed all of the tRNA species seen during vegetative growth, but an additional five to six minor spots were also observed. These are hypothesized to arise from the loss of 3'-terminal residues from preexisting tRNA's.     

Function of Modified Nucleosides 7-Methylguanosine, Ribothymidine, and 2-Thiomethyl-N6-(Isopentenyl)adenosine in Procaryotic Transfer Ribonucleic Acid

To elucidate subtle functions of transfer ribonucleic acid (tRNA) modifications in protein synthesis, pairs of tRNA's that differ in modifications at specific positions were prepared from Bacillus subtilis. The tRNA's differ in modifications in the anticodon loop, the extra arm, and the TUC loop. The functional properties of these species were compared in aminoacylation, as well as in initiation and peptide bond formation, at programmed ribosomes. These experiments demonstrated the following. (i) In tRNA(f) (Met) the methylation of guanosine 46 in the extra arm to 7-methylguanosine by the 7-methylguanosine-forming enzyme from Escherichia coli changes the aminoacylation kinetics for the B. subtilis methionyl-tRNA synthetase. In repeated experiments the V(max) value is decreased by one-half. (ii) tRNA(f) (Met) species with ribothymidine at position 54 (rT54) or uridine at position 54 (U54) were obtained from untreated or trimethoprim-treated B. subtilis. The formylated fMet-tRNA(f) (Met) species with U54 and rT54, respectively, function equally well in an in vitro initiation system containing AUG, initiation factors, and 70s ribosomes. The unformylated Met-tRNA(t) (Met) species, however, differ from each other: "Met-tRNA(f) (Met) rT" is inactive, whereas the U54 counter-upart effectively forms the initiation complex. (iii) Two isoacceptors, tRNA(1) (Phe) and tRNA(2) (Phe), were obtained from B. subtilis. tRNA(1) (Phe) accumulates only under special growth conditions and is an incompletely modified precursor oftRNA(2) (Phe): in the first position of the anticodon, guanosine replaces Gm, and next to the 3' end of the anticodon (isopentenyl)adenosine replaces 2-thiomethyl-N(6)-(isopentenyl)adenosine. Both tRNA's behave identically in aminoacylation kinetics. In the factor-dependent AUGU(3)-directed formation of fMet-Phe, the undermodified tRNA(1) (Phe) is always less efficient at Mg(2+) concentrations between 5 and 15 mM than its mature counterpart.     

Changes in Transfer Ribonucleic Acids Accompanying Encystment in Acanthamoeba castellanii

Transfer ribonucleic acid (tRNA) from exponentially growing cells (trophozoites) and from precysts of Acanthamoeba castellanii were examined by reversed-phase column (RPC-2) chromatography. This system gave excellent resolution of isoaccepting species of tRNA. The tRNAs for 12 amino acids were studied. A comparison of trophozoite and precyst tRNA elution profiles revealed no apparent differences in the number of isoaccepting species of alanyl-, arginyl-, asparaginyl-, glycyl-, leucyl-, lysyl-, methionyl-, phenylalanyl-, tryptophanyl-, or valyl-tRNAs. Seryl-tRNAs from trophozoites were eluted as three components, whereas precyst seryl-tRNAs were eluted as only two components. Precharged trophozoite and precyst isoleucyl-tRNAs were both eluted as single components; however, post-chromatography charging of trophozoite tRNA resulted in three components of activity for tRNA(Ile) and only one component for precyst tRNA(Ile). None of the observed changes could be attributed to differences in synthetases or to the presence of altered tRNA lacking the CCA terminus or partially degraded by nucleases. The possible significance of these observations is discussed.     

The effects of hyperphenylalaninaemia on the concentrations of aminoacyl-transfer ribonucleic acid in vivo. A mechanism for the inhibition of neural protein synthesis by phenylalanine.

An acute administration of phenylalanine to neonatal animals has been reported to result in large decreases in the intracellular concentrations of several essential amino acids in neural tissue, as well as an inhibition of neural protein synthesis. The present report evaluates the effects of the loss of amino acids on the concentrations of aminoacyl-tRNA in vivo, with the view that an alteration in the concentrations of specific aminoacyl-tRNA molecules could be the rate-limiting step in brain protein metabolism during hyperphenylalaninaemia. tRNA was isolated from saline- and phenylalanine-injected mice 30-45 min after injection, by using a procedure designed to maintain the concentrations of aminoacyl-tRNA present in vivo. Periodate oxidation of the non-acylated tRNA and aminoacylation with radioactively labelled amino acids was used to determine the proportion of tRNA that was present in vivo as aminoacyl-tRNA. Although decreases in the intracellular concentrations of alanine, lysine and leucine were observed after phenylalanine administration, the concentrations of alanyl-tRNA, lysyl-tRNA and leucyl-tRNA actually increased by 15%. Although tryptophan has been suggested to be rate-limiting during hyperphenylalaninaemia, the proportion of tryptophan tRNA that was acylated was maximal in both normal and hyperphenylalaninaemic animals. This unexpected increase in aminoacyl-tRNA concentration is discussed as perhaps a secondary effect resulting from the phenylalanine-induced inhibition of protein synthesis. In contrast, the proportion of methionine tRNA that was acylated in vivo after phenylalanine administration was demonstrated to be decreased by approx. 17%. When the isoaccepting species of methionine tRNA were separated by reverse-phase column chromatography, three species were separated, one of which was demonstrated to be the initiator species, tRNAfMet, by the selective aminoacylation and formylation with Escherichia coli enzymes. After the administration of phenylalanine, the acylation of each of the three methionine tRNA species was decreased, with the initiator species being lowered by 10%. This effect on aminoacylation of tRNAfMet may be the primary step by which phenylalanine affects neural protein synthesis, and this is consistent with previous reports that re-initiation may be inhibited during hyperphenylalaninaemia.     

Control of Arginine Biosynthesis in Escherichia coli: Characterization of Arginyl-Transfer Ribonucleic Acid Synthetase Mutants

The arginyl-transfer ribonucleic acid (Arg-tRNA) synthetase (EC 6.1.1.13, arginine: RNA ligase adenosine monophosphate) mutants, exhibiting nonrepressible synthesis of arginine by exogenous arginine, were employed in studies of several biochemical properties. Two of these mutants possessed Arg-tRNA synthetases with a reduced affinity for arginine, and this enzyme of another mutant had a reduced affinity for arginine-tRNA (tRNA^arg). The mutant possessing an Arg-tRNA synthetase with an altered K_m for tRNA^arg was found to have reduced in vivo aminoacylation of two of the five isoaccepting species of tRNA^arg and complete absence of aminoacylation of one of the isoaccepting species.     

Analysis of Isoaccepting Transfer Ribonucleic Acid Species of Bacillus subtilis: Chromatographic Differences Between Transfer Ribonucleic Acids from Spores and Cells in Exponential Growth

Differences between the transfer ribonucleic acid (tRNA) of spores and exponentially growing cells of Bacillus subtilis 168 were compared by co-chromatography on reversed-phase column RPC-5. This system gave excellent resolution of isoaccepting species in 1 to 2 hr using a 200-ml gradient. Two methods were used to extract spore tRNAs, a procedure using a Braun homogenizer and a pretreatment with dithiothreitol followed by lysis with lysozyme. Where changes were observed, column elution profiles of spore tRNAs were independent of the extraction method used. Three kinds of changes between the profiles of vegetative cell tRNA and spore tRNA were observed: (i) no change; phe-, val-, ala-, asp-, ileu-, pro-, met-, fmet-, and his-tRNAs, (ii) a change in the ratio of existing peaks; gly-, tyr-, leu-, ser-, thr-, aspn-, and arg-tRNAs, and (iii) the appearance or disappearance of unique peaks; lys-, glu-, and trp-tRNAs.     

Thyroid Ribonucleic Acid-Iodopeptides. Comparison of Tyrosyl-Complex II and Tyrosyl-tRNA.

It has previously been shown that mammalian RNA-peptidyl complexes are found in close association with tRNA, but can be separated from the bulk of the tRNA by benzoylated diethylaminoethylcellulose chromatography (Kull, F.J., and Soodak, M. (1971), Biochim. Biophys. Acta 246, l; Gadski, R.A., and Kull, F.J. (1973), Biochemistry 12, 1907). These studies also showed that under aminoacylation conditions the complex fractions were able to act as acceptors for certain amino acids and that the formation of porcine thyroid tyrosyl-complex II was particularly high. Because of this high acceptor function, and because of the importance of tyrosine to thyroid metabolism, further studies were conducted comparing some of the properties of porcine thyroid tyrosyl-complex II with those of porcine thyroid tyrosyl-tRNA. Porcine thyroid tyrosyl-tRNA synthetase was purified in excess of 200-fold and characterized. It was found that maximal aminoacylation was achieved at pH 8.1 in the presence of 150 mM KCl. The Km for tyrosine was determined to be 3.0 X 10(-6) M. The purified thyroid tyrosyl-tRNA synthetase was used under aminoacylation conditions to prepare radioactively labeled porcine thyroid tyrosyl-tRNA and tyrosyl-complex II. Comparisons made using reversed-phase column chromatography (RPC-5) showed distinct differences between the two aminoacylated species and revealed, in addition, a number of isoaccepting forms of tyrosine tRNA. Tyrosyl-complex II was also found to differ from tyrosyl-tRNA in that it is more stable to deacylation at pH 7.0 and at pH 4.4 and to degradation by ribonuclease A. In addition, tyrosyl-complex II, unlike tyrosyl-tRNA, is degraded by trypsin. Ribosomal binding studies showed that tyrosyl-complex II did not respond to the codons for tyrosine, UpApU and UpApC, whereas tyrosyl-tRNA responded to both. It is suggested that thyroid tyrosine complex II is representative of a group of related complexes that constitute the complex II fraction and that, although the complexes resemble tRNA in many respects, they have distinctly different characteristics than conventional tRNA.     

Modeling with in vitro kinetic parameters for the elaboration of transfer RNA identity in vivo

A tRNA with "double identity" was created, and this tRNA was demonstrated in vitro to aminoacylate quantitatively with either of two amino acids. In contrast, acceptance of only one of these amino acids was observed in vivo, and a simple manipulation determined which one was accepted. Kinetic parameters were obtained for aminoacylation with each amino acid of the tRNA with double identity and of related tRNAs. Modeling with these parameters largely explains which amino acid specificity is observed in vivo. The results delineate some of the kinetic boundaries for the design and accommodation of tRNA sequence variations in the elaboration of identity in vivo.     

Determination of the degree of in vivo tRNA aminoacylation in yeast cells

A method is described to harvest yeast cells, extract tRNAs having a good biological activity, and measure the degree of in vivo tRNA aminoacylation. This measuremet is based on a determination of the percentage of tRNA which is resistant to periodate oxidation; control experiments have been performed to check that this treatment inactivates uncharged tRNA molecules, but does not affect aminoacylated ones, and allows therefore an accurate determination of the percentage of aminoacylated tRNA molecules.     

Methyl-Deficient Transfer Ribonucleic Acid in Saccharomyces cerevisiae

Methyl-deficient transfer ribonucleic acid (tRNA) is found in certain methionine auxotrophs of Saccharomyces cerevisiae during logarithmic growth (at one generation time before the late growth phase) and during residual growth in the absence of exogenous methionine. The former effect seems to be accounted for by the general increase in RNA synthesis that occurs at the time; there is no specific synthesis of tRNA in the absence of ribosomal RNA synthesis, nor is the methyl group deficiency limited to a single tRNA species. During methionine starvation, all species of tRNA are methyl-deficient, but this occurs only in strains with certain blocks in the methionine pathway. The kinetics of disappearance of the methyl group donor, S-adenosylmethionine, during starvation of D73 (which accumulates methyl-deficient tRNA), do not differ from other strains, but D73 loses the methylase inhibitor, S-adenosylhomocysteine, much more slowly.     

Response of specific transfer-ribonucleic-acid levels to amino-acid deprivation in Friend leukemia cells.

In eukaryotes, the levels of specific tRNAs are closely correlated with the demands for their cognate amino acids in protein synthesis. To account for this phenomenon, we have proposed that the extent of aminoacylation of a given tRNA species in vivo controls the relative rate of synthesis or turnover of that species. Previously, we reported that Friend leukemia cells respond to histidine deprivation by increasing their relative level of tRNAHis by as much as two-fold, with no change in the relative level of tRNALeu. In this paper, we show that deprivation of leucine or tryptophan also causes a specific increase in the relative level of tRNAs cognate to the deprived amino acid. At least in the case of tRNATrp, the increases in relative tRNA levels are preceded by extensive declines in the steady-state extent of aminoacylation of the tRNA in vitro. We also find that different isoacceptors may respond differently to amino acid deprivation. These results suggest that decreased extents of aminoacylation of a given tRNA species in vivo cause increases in the relative rate of synthesis or decreases in the relative rate of degradation of that species.     

Preferential usage of tRNA isoaccepting species in collagen synthesis.

A new double label technique is described for determining the usage of individual isoaccepting tRNA species by in vitro protein-synthesizing systems. Employing this method we show that of four major species of glycyl-tRNA one which is cognate to GGU and GGC is used predominantly in collagen synthesis by polysomes isolated from embryonic chick calvaria. A similar preferential usage was found for one of two alanyl-tRNA species. No preference for any particular isoaccepting tRNA species was observed in the synthesis of noncollagenous proteins by either calvaria or liver polysomes except for the disproportionate usage of one lysyl-tRNA species. Whether such preferential usage permits translational control of collagen synthesis in vivo remains to be determined.     

Chromatographic Analyses of Isoaccepting tRNAs from Avian Myeloblastosis Virus

Avian myeloblastosis virus (AMV) 4S RNA was tested for amino acid acceptor activity for 18 of the 20 amino acids. A nonrandom distribution of viral tRNAs was found compared with tRNA from normal liver or from AMV-infected leukemic myeloblasts, confirming previous reports. Methionine and proline tRNAs were considerably enriched, whereas glutamic acid, glutamine, serine, tyrosine, and valine tRNAs were markedly depleted in AMV relative to homologous cellular tRNAs. The seven AMV tRNAs with the greatest amino acid acceptance capacities, which were in order methionine, proline, lysine, arginine, histidine, isoleucine, and threonine tRNAs, were compared with homologous tRNAs from leukemic myeloblasts and liver by reversed-phase 5 chromatography. Of the 25 isoaccepting chromatographic fractions identified, no tRNA species unique to AMV was detected. Only methionyl-tRNA showed a substantial quantitative variation in isoaccepting species compared with the host cell. Thus, viral selectivity for amino acid-specific tRNAs is not, generally, paralleled by selectivity for individual isoaccepting tRNA species. Qualitative differences in arginyl- and histidyl-tRNA isoaccepting species were discovered in virus and leukemic myeloblasts compared with liver. This indicates the existence of structural differences in these tRNA species which could be related to virus replication or expression.