Coding origin of isoaccepting tRNA in yeast mitochondria

Valyl-, leucyl- and tyrosyl-tRNA of yeast mitochondria were fractionated by reversed phase chromatography. Each of the tRNA contained multiple isofunctional species. Some of them specifically hybridized to mitochondrial DNA from (see article) strain. These species were absent in a petite colonie mutant lacking mitochondrial DNA. Three valyl-, one leucyl- and one tyrosyl tRNA were found to be products of mitochondrial genes.

[Affinity modification of phenylalanyl-tRNA-synthetase in the presence of ligands]

The kinetics of the affinity modification of phenylalanyl-tRNA synthetase from E. coli MRE-600 with chb-tRNA was used for investigation of copling between the binding sites of tRNA and other ligands. It was shown that ATP, phenylalanine and their mixture do not change the efficiency of complex formation but decrease specifically the rate of enzyme alkylation. L-Tyrosine and L-valine do not influence the enzyme alkylation. ATP is more effective protector than L-phenylalanine. In the presence of both ATP and phenylalanine the enzyme alkylation is excluded. The possibilities of this method for studying the coupling between binding sites are discussed.

Binding of Met-tRNAf to native 40 S ribosomal subunits in Ehrlich ascites tumor cells

Two forms of native 40 S ribosomal subunits, distinguishable by their buoyant densities, are recovered from Ehrlich ascites cells. In this communication, we describe experiments designed to test whether Met-tRNAf is associated with either form. Our results indicate that (a) in the cell, Met-tRNAf is bound to the native 40 S subunit, and in particular, to the subunit of density 1.40 g x cm-3; (b) under the growth conditions used, less than 10% of the low density native subunits have bound Met-tRNAf; (c) the majority of the Met-tRNAf containing native 40 S subunits, isolated from sucrose gradient analyses of cell extracts, join with 60 S subunits in vitro to form 80 S monosomes only if additional ribosomal wash factors are provided; and (d) the 80 S monosomes so formed are completed initiation complexes that can form peptide bonds. These results support the hypothesis that various forms of the native 40 S subunit represent different stages in the formation of a complete initiation complex.

Structure-activity relationships in tryptophanyl transfer ribonucleic acid synthetase from beef pancreas. Influence of the alkylation of the sulfhydryl groups on the dimer-monomer equilibrium

Upon reaction with N-ethylmaleimide, tryptophanyl-tRNA synthetase from beef pancreas dissociates into subunits. At pH7, the rate of the dissociation is close to both the reaction rate of the buried--SH groups and the rate of inactivation (Iborra, F., Mourgeon, G., Labouesse B., and Labouesse, J. (1973) Eur. J. Biochem. 39, 547-556). The pH and enzyme concnetration dependences of the reaction rate of the 16 cysteinyl residues of the enzyme as well as that of its inactivation support the idea that inactivation by alkylation of the--SH groups is due essentially to the dissociation of the protein into inactive subunits and not to the chemical blocking of a catalytic residue. This is confirmed by the independence on N-ethylmaleimide concentration of the reaction of the buried--SH groups and of the inactivation of the enzyme at high N-ethylmaleimide concentration. The dissociation becomes in this case the rate-limiting step of the chemical reaction. The monomeric structure is stabilized by the blocking of the--SH groups exposed during the dissociation. The dissociation constant of the dimeric enzyme is progressively increased during the alkylation. The tightness of the associated structure depends on the protonation of groups titrating between pH 7 and pH 9.

Molecular aspects of the inactivation of tryptophanyl transfer ribonucleic acid synthetase by N-ethylmaleimide

The tryptic maps of tryptophanyl-tRNA synthetase from beef pancreas show that the 8 cysteinyl residues of the enzyme subunit are located, 2 by 2, on four different peptides. The kinetics of the incorporation of radioactivity from N-[ethyl-14C]ethylmaleimide into these peptides are compared in this paper with the kinetics of the changes of the catalytic properties of the enzyme occurring during alkylation. This comparison allows the identification of (a) the peptide carrying the cysteinyl residues located on the surface of the molecule, (b) the peptide carrying the deeply buried residues unmasked by the dissociation of the subunits, and (c) the peptide carrying the --SH group located in the vicinity of the binding site of tryptophan. The fourth peptide is shown to have a great sensitivity to pH with respect to the reactivity of its cysteinyl residues toward N-ethylmaleimide. The same unusual pH dependence is found for the rate of quenching of the intrinsic fluorescence of the protein during the alkylation, suggesting a strong sensitivity of the conformation of tryptophanyl-tRNA synthetase to pH in the range of 7 to 9.

The biosynthesis of transfer RNA in insects. I. Increase of amino acid acceptor activity of specific tRNA's utilized for silk protein biosynthesis in the silk gland of Bombyx mori

1) To detect the quantitative changes of amino acid acceptor activity of tRNA's from the posterior and middle silk glands of Bombyx mori at various ages, a relatively simple and rapid method was established using a mixture of radioactive amino acids in Chlorella hydrolysate. 2) The acceptor activities of silk gland tRNA for 15 amino acids tested seemed to be almost on the same level at the end of the 4th moult stage. During the 5th instar, however, characteristic increases were observed in glycine, alanine, and serine acceptor activities in both silk glands. 3) In the posterior silk gland, which produces fibroin, the acceptor activities for glycine and alanine increased more than that for serine. In the middle silk gland, which produces sericine, the acceptor activity for serine increased more than those for glycine and alanine. 4) In the light of observations on the increase of corresponding aminoacyl-tRNA synthetase activities in the silk glands, a functional adaptation of tRNA synthesis in the tissue is discussed.

Tyrosyl-tRNA synthetase from Escherichia coli. Stoichiometry of ligand binding and half-of-the-sites reactivity in aminoacylation

The tyrosyl-tRNA synthetase from Escherichia coli binds only 1 mol of tRNA, tyrosine, and tyrosyl adenylate per mol of enzyme dimer. However, like the enzyme from Bacillus stearothermophilus, once one active site is occupied by tyrosyl adenylate the other becomes accessible to bind a further molecule each of tyrosine and ATP. Both bacterial enzymes show biphasic kinetics with respect to tyrosine in the aminoacylation of tRNA. Equilibrium dialysis experiments show that this is due to 2 mol of tyrosine binding in the presence of ATP and tRNA. A method is given for a correction for the effects of hydrolysis of the charged tRNA on the aminoacylation kinetics.

Preparation of polyribosome aminoacyl-transfer ribonucleic acid from the muscle of chick embryos

A procedure for preparing polyribosome aminoacyl-tRNA free from contamination by supernatant aminoacyl-tRNA and free amino acids is described. Important features of the procedure are the use of acidic buffers to help protect the amino acid-tRNA linkage and the inclusion of sodium dodecyl sulphate, to inhibit ribonuclease activity. The specific radioactivity of polyribosome aminoacyl-tRNA is high within 30s and reaches a maximum in 2 1/2 min, well ahead of polyribosome peptides which, as described by Herrmann et al. (1971), attain maximum specific radioactivity in about 10 min.

Modification of phenylalanyl-tRNA synthetase from baker's yeast by proteolytic cleavage and properties of the trypsin-modified enzyme

Earlier studies have shown that native phenylalanyl-tRNA synthetase from baker's yeast contains two different kinds of subunits, alpha of molecular weight 73000 and beta of molecular weight 63000. The enzyme is an asymmetric tetramer alpha-2beta-2, which binds two moles of each ligand per mole. Incubation of the purified enzyme with trypsin results in an irreversible conversion: the alpha-subunit remains apparently unchanged but beta is rapidly degraded and yields a lighter species beta of molecular weight 41000. The trypsin-modified enzyme is an alpha-2beta-2 molecule which can still activate phenylalanine but cannot transfer it to tRNA-Phe; furthermore it does not bind tRNA-Phe but its kinetic parameters are identical to those of the native enzyme with respect to ATP and phenylalanine. Therefore the two beta subunits play a critical part in tRNA binding. Isolated alpha or beta subunits exhibit no significant activity and both types of subunit seem to be required for phenylalanine activation.

Two enzymically active forms of glycyl-tRNA synthetase from Bacillus brevis. Purification and properties

Using sucrose density centrifugation and gel filtration of a 105000 X g supernatant of Bacillus brevis two enzymic activities of glycyl-tRNA synthetase were separated. Enzyme catalyzing the aminoacylation of tRNA (E1) elutes in a high-molecular-weight region. Enzyme active in glycylhydroxamate formation (E2) elutes from a Sephadex gel column and sediments in sucrose density gradient in a region of relatively low molecular weight. The presence of two enzymic activities does not depend on the method of cell disruption; their proportion does not change when protease inhibitor (diisopropylphosphorofluoridate) is added to the extraction buffer. Both E1 and E2 were purified to a nearly homogeneous state. Sedimentation coefficients (sw,20) were found to be 8.6 S and 3.6 S and molecular weights 226000 and 66000 for E1 and E2, respectively. During storage, E1 dissociates into two components, one of which has electrophoretic mobility identical to E2. The molecular weight of the other component is about 1600000. Electrophoresis of E1 in the presence of sodium dodecylsulfate reveals two bands corresponding to molecular weights of 81000 and 30000. Under these conditions, E2 dissociates into a polypeptide with a molecular weight of 30000. Valine was found to be the N-terminal amino acid for E2 and both valine and glutamic acid were N-terminal amino acids for E1. It is concluded that E1 is a tetrameric protein consisting of two large and two small subunits (alpha2beta2). E2 is a component of E1 with a structural formula alpha2.

The infrastructure of valyl-transfer Ribonucleic Acid synthetase from yeast

Valyl-tRNA synthetase from yeast is shown to contain a significant proportion of repeated sequence, similar to the enzyme from bacterial sources.

Phenylalanyl-tRNA synthetase from baker's yeast: role of 3'-terminal adenosine of tRNA-Phe in enzyme-substrate interaction studied with 3'-modified tRNA-Phe species

TRNA-Phe species from baker's yeast modified at the 3'-terminus in many cases are phenylalanylatable substrates. Out of several tRNA-Phe species possessing a modified 3'-end that cannot be phenylalanylated, only two, tRNA-Phe-C-C-2'dA and the tRNA-Phe-C-C-formycin-oxi-red, are strong competitive inhibitors for tRNA-Phe-C-C-A during phenylalanylation. In the ATP/PPi exchange, both these inhibitors reduce Vmax to about 25%; but whereas tRNA-Phe-C-C-2dA has no influence on KmATP and Km Phe during ATP/PPi exchange, tRNA-Phe-C-C-formycin-oxi-red reduces KmATP from 1430 muM, found in the absence of tRNA-Phe, to 230 muM, and Km-Phe, from 38 to 14 muM. The values found in the presence of tRNA-Phe-C-C-formycin-oxi-red during ATP/PPi exchange are identical with those determined in the phenylalanylation of tRNA-Phe-C-C-A. All other tRNA-Phe species carrying a modified 3'end that cannot be phenylalanylated exhibit a mixed competitive-noncompetitive inhibition in the phenylalanylation reaction. In the ATP/PPi exchange, they do not influence KmATP and KmPHE and only weakly, if at all, Vmax. The results show that the 3'adenosine of tRNA-Phe cannot solely be a passive acceptor for phenylalanine, but must in addition play an active role during enzyme-substrate interaction. The data can be consistently explained by the hypothesis that the 3'-adenosine of tRNA-Phe triggers a conformational change of the enzyme.

Transfer of serine into polypeptides and myosin by chromatographic species of seryl-transfer ribonucleic acid

The efficiencies of two chromatographic species of [3-H]seryl-tRNA, namely peaks I and II, in cell-free amino acid incorporation were investigated. The maximum yield of polypeptide seems to be the same for the reaction mixtures containing either peak I or peak II, suggesting that the efficiency of both peaks in total protein synthesis is the same. The efficiency of transfer of serine into myosin heavy subunit (myosin H) by peaks I and II was also investigated. Peak II of [3-H]seryl-tRNA transfers three times as much serine into myosin H as peak I.

The structural basis for the resistance of Escherichia coli formylmethionyl transfer ribonucleic acid to cleavage by Escherichia coli peptidyl transfer ribonucleic acid hydrolase

Escherichia coli formylmethionly-tRNA-tMet is unique among N-acylaminoacyl-tRNAs in its resistance to cleavage by peptidyl-tRNA hydrolase. Chemical modification of tRNA-fMet with sodium bisulfite converts fMet-tRNA-fMet into a good substrate for the hydrolase. The products of the enzymatic cleavage are free tRNA-fMet and formylmethionine. Bisulfite treatment produces cytidine to uridine base changes at several sites in the tRNA structure. One of these modifications results in formation of a new hydrogen-bonded base pair at the end of the acceptor stem of tRNA-fMet. We have shown that this modification is responsible for the observed change in biological activity. Enzymatic cleavage appears to be facilitated by the presence of a 5-terminal phosphate at the end of a fully base-paired acceptor stem, because removal of the 5-phosphate group from N-acetylphenylalanyl-tRNA-Phe or bisulfite-modified fMet-tRNA-FMet reduced the rate of hydrolysis of these substrates. The unpaired base at the 5 terminus of unmodified fMet-tRNA-fMet appears to reduce susceptibility of the tRNA to hydrolytic attack both by positioning the 5-phosphate in an unfavorable orientation and by directly interfering with enzymatic binding. The unusual structure of the acceptor stem of this E. coli tRNA thus plays a critical role in maintaining the viability of the organism by preventing enzymatic cleavage of the fMet group from the bacterial initiator tRNA.