Non-linear kinetics of glutamyl-tRNA synthesis catalyzed by high molecular weight complexes from rat brain neuronal cells but not from glial cells

High molecular weight complexes of aminoacyl-tRNA synthetases isolated from rat brain catalyze the formation of glutamyl-tRNA with an initial lag time of the order of 1 min, as previously reported for the formation of glutamyl-tRNA and glutaminyl-tRNA catalyzed by similar complexes from bovine brain (Vadeboncoeur and Lapointe, Eur. J. Biochem., 109 (1980) 581-587). To determine the type(s) of brain cell(s) where this phenomenon occurs, we have studied the kinetics of glutamyl-tRNA formation catalyzed by high molecular weight complexes of aminoacyl-tRNA synthetases isolated from neuronal and from glial cells, either transformed (Neuro-2A and C6), or from primary cultures, or isolated from rat brain. The delay in the formation of glutamyl-tRNA was observed only in the case of neuronal cells isolated from rat brain, whereas a delay in the formation of glutaminyl-tRNA was also seen in these cells, as well as in neuronal cells in primary culture and in synaptosomes. The kinetics of formation of aspartyl-tRNA and valyl-tRNA catalyzed by high molecular weight complexes from all these cells was linear.

Tryptophanyl-tRNA synthetase is a major soluble protein species in bovine pancreas

Besides their central role in protein synthesis, aminoacyl-tRNA synthetases have been found or thought to be involved in other processes. We present here a study showing that tryptophanyl-tRNA synthetase has a surprising tissular distribution. Indeed, immunochemical determinations showed that in several bovine organs such as liver, kidney and heart, tryptophanyl-tRNA synthetase constitutes, as expected, about 0.02% of soluble proteins. In spleen, brain cortex, stomach, cerebellum or duodenum, this amount is about 10-times higher, and in pancreas it is 100-fold. There is no correlation between these amounts and the RNA content of the organs. Moreover, the concentration of another aminoacyl-tRNA synthetase (methionyl-tRNA synthetase) is higher in liver than in pancreas, while the amount of tRNATrp is not higher in pancreas than in liver as compared to other tRNAs. Among several interpretations, it is possible that tryptophanyl-tRNA synthetase is involved in a function other than tRNA aminoacylation. This unknown function would be specific to the differentiated organs, since fetal cerebellum and fetal pancreas contain the same amount of tryptophanyl-tRNA synthetase as adult liver.

Internal structural features of E. coli glycyl-tRNA synthetase examined by subunit polypeptide chain fusions

In contrast to most aminoacyl-tRNA synthetases which are monomers or oligomers of a single polypeptide, Escherichia coli glycyl-tRNA synthetase has an alpha-2, beta-2 structure. The enzyme requires both subunits for catalysis of either adenylate or aminoacyl-tRNA synthesis. The head-to-tail arrangement of the alpha- and beta-chain coding regions in the genome suggests that the two-subunit protein may be tantamount to a single chain. We fused the carboxyl terminus of the alpha-chain to the amino terminus of the beta-chain, through a short peptide linker. Five different amino acid substitutions were placed in the linker. In all instances, the fusion polypeptide is stable in maxicell extracts. In a glyS null strain, a gene encoding any of the fusion proteins substitutes for the wild-type gene. Assays confirm that, in vitro, the engineered polypeptide fusion is active to within 2- to 3-fold of the wild-type, unfused chains. Oligomers of the fusion protein are observed and may be required for activity. Because the creation and limited manipulation of the artificial peptide linker region does not destroy the activity, we also conclude that the C-terminal part of the alpha-chain and the amino-terminal part of the beta-chain are not important for activity.

tRNAfMet-induced conformational transition at the intersubunit domain of fluorescent-labeled methionyl-tRNA synthetase

Conformational transition in methionyl-tRNA synthetase upon binding of tRNAfMet, whose binding shows strong negative cooporativity, was analyzed by fluorescence spectroscopy. The fluorescent probe N-[[(iodoacetyl)amino]ethyl]-5-naphthylamine-1-sulfonic acid (1,5-I-AEDANS) reacts with native methionyl-tRNA synthetase in a nearly stoichiometric amount (2 per dimer) without affecting enzyme activity. The probe is shown by controlled trypsinization to be located in a 130 amino acid fragment at the C-terminus joining the subunits. The emission and excitation spectra, rotational freedom, and solvent accessibility of the fluorophore in AEDANS-methionyl-tRNA synthetase are analyzed. The results suggest that the probe is localized in a nonpolar environment, nearly immobile relative to methionyl-tRNA synthetase yet fully accessible to the solvent. Upon binding of tRNAfMet, the fluorescence intensity in AEDANS-methionyl-tRNA synthetase was appreciably reduced without a shift in the emission or excitation spectra. Lifetime measurement shows that a static mechanism accounts for the observed quenching. Furthermore, the remaining emitting AEDANS becomes effectively shielded from solvent molecules. These results suggest an unsymmetric conformational transition at the intersubunit domains of the two subunits in methionyl-tRNA synthetase upon binding one molecule of tRNAfMet.

Changing the identity of a transfer RNA

A leucine transfer RNA has been transformed into a serine transfer RNA by changing 12 nucleotides. This result indicates that a limited set of residues determine tRNA identity.

Effects of liver regeneration on tRNA contents and aminoacyl-tRNA synthetase activities and sedimentation patterns

The tRNA content and aminoacyl-tRNA synthetases of regenerating liver in the phase of rapid growth were compared with those of livers from both intact and sham-operated rats. At 48 h after hepatectomy, the amount of active tRNA (called 'total acceptor capacity') is significantly higher in regenerating liver than in control livers, owing to a general, possibly not uniform, increase in the various tRNA families, which suggests that it may contribute to the increased protein synthesis and to decreased protein degradation as well. The activities of most, but not of all, aminoacyl-tRNA synthetases in cell sap of regenerating liver tend to be greater than normal. Increased activity of histidyl-tRNA synthetase fits in with the possibility that the mechanisms that control the rate of protein degradation through aminoacylation of tRNAHis in cultured cells [Scornik (1983) J. Biol. Chem. 258, 882-886] also operate in the liver and play a role in regeneration. Sedimentation analysis of cell sap in sucrose density gradients shows a shift of prolyl-tRNA synthetase activity toward the high-Mr form in regenerating liver. This change might be related to the positive protein balance and to growth in vivo, since it is also observed in the anaplastic Yoshida ascites hepatoma AH 130.

Regulation of polypeptide chain initiation and activity of initiation factor eIF-2 in Chinese-hamster-ovary cell mutants containing temperature-sensitive aminoacyl-tRNA synthetases

The regulation of polypeptide chain initiation has been investigated in extracts from a number of well-characterized Chinese hamster ovary (CHO) cell mutants containing different temperature-sensitive aminoacyl-tRNA synthetases. These cells exhibit a large decline in the rate of initiation when cultures are shifted from the permissive temperature of 34 degrees C to the non-permissive temperature of 39.5 degrees C. During a brief incubation with [35S]Met-tRNAMetf or [35S]methionine, formation of initiation complexes on native 40S ribosomal subunits and 80S ribosomes is severely impaired in extracts from the mutant cell lines exposed to 39.5 degrees C. Wild-type cells exposed to 39.5 degrees C do not show any inhibition of protein synthesis or initiation complex formation. Inhibition of formation of 40S initiation complexes in the extracts from mutant cells, incubated at the non-permissive temperature, is shown to be independent of possible changes in mRNA binding or the rate of polypeptide chain elongation and is not due to any decrease in the total amount of initiation factor eIF-2 present. However, assays of eIF-2 X GTP X Met-tRNAMetf ternary complex formation in postribosomal supernatants from the temperature-sensitive mutants reveal a marked defect in the activity of eIF-2 after exposure of the cells to 39.5 degrees C and addition of exogenous eIF-2 to cell-free protein-synthesizing systems from cells incubated at 34 degrees C and 39.5 degrees C eliminates the difference in activity between them. The activity of the initiation factor itself is not directly temperature-sensitive in the mutant CHO cells. The results suggest that the activity of aminoacyl-tRNA synthetases can affect the ability of eIF-2 to bind Met-tRNAMetf and form 40S initiation complexes in intact cells, indicating a regulatory link between polypeptide chain elongation and chain initiation.

Potential metal-binding domains in nucleic acid binding proteins

A systematic search for sequences that potentially could form metal-binding domains in proteins has been performed. Five classes of proteins involved in nucleic acid binding or gene regulation were found to contain such sequences. These observations suggest numerous experiments aimed at determining whether metal-binding domains are present in these proteins and, if present, what roles such domains play in the processes of nucleic acid binding and gene regulation.

Integrated function of a kinetic proofreading mechanism: double-stage proofreading by isoleucyl-tRNA synthetase

Experimental measurements for isoleucyl-tRNA synthetase proofreading valyl-tRNAIle in Escherichia coli previously have been incorporated into the conventional Michaelis-Menten model for this system. This model was augmented to include two stages of proofreading--the aminoacyl adenylate and aminoacyl-tRNA stages--and used to predict the values of four additional rate constants that have been determined experimentally. The results suggest that two stages of conventional kinetic proofreading with binding sites designed for isoleucine (the "correct" substrate) are inconsistent with the experimental data, that a double-stage mechanism in which one stage (the "double-sieve") involves a binding site designed for valine (the "incorrect" substrate) and the other involves a binding site designed for isoleucine is consistent with all the experimental data, and that the experimental data are not sufficiently accurate to distinguish the stage at which the double-sieve mechanism operates in vivo. Furthermore, analysis of the model suggests that four parameters have the most questionable values and that experimental refinement of their estimates will be needed to determine which of the two stages involves the double-sieve mechanism.

Use of binding energy in catalysis analyzed by mutagenesis of the tyrosyl-tRNA synthetase

The utilization of enzyme-substrate binding energy in catalysis has been investigated by experiments on mutant tyrosyl-tRNA synthetases that have been generated by site-directed mutagenesis. The mutants are poorer enzymes because they lack side chains that form hydrogen bonds with ATP and tyrosine during stages of the reaction. The hydrogen bonds are not directly involved in the chemical processes but are at some distance from the seat of reaction. The free energy profiles for the formation of enzyme-bound tyrosyl adenylate and the equilibria between the substrates and products were determined from a combination of pre-steady-state kinetics and equilibrium binding methods. By comparison of the profile of each mutant with wild-type enzyme, a picture is built up of how the course of reaction is affected by the influence of each side chain on the energies of the complexes of the enzyme with substrates, transition states, and intermediates (tyrosyl adenylate). As the activation reaction proceeds, the apparent binding energies of certain side chains with the tyrosine and nucleotide moieties increase, being weakest in the enzyme-substrate complex, stronger in the transition state, and strongest in the enzyme-intermediate complex. Most marked is the interaction of Cys-35 with the 3'-hydroxyl of the ribose. Removal of the side chain of Cys-35 leads to no change in the dissociation constant of ATP but causes a 10-fold lowering of the catalytic rate constant. It contributes no net apparent binding energy in the E X Tyr X ATP complex and stabilizes the transition state by 1.2 kcal/mol and the E X Tyr-AMP complex by 1.6 kcal/mol.(ABSTRACT TRUNCATED AT 250 WORDS)

Isoleucyl-tRNA synthetase from baker's yeast. Influence of substrate concentrations on aminoacylation pathways, discrimination between tRNAIle and tRNAVal, and between isoleucine and valine

The influence of substrate concentrations on aminoacylation pathways and substrate specificities was investigated in the acylation reaction catalyzed by isoleucyl-tRNA synthetase from yeast. For the cognate substrates isoleucine and tRNAIle two Km values each differing by a factor about five were determined; the higher values were observed at concentrations higher than 1 microM, the lower values below 1 microM isoleucine or tRNAIle, respectively. At substrate concentrations below 1 microM also kcat values of the isoleucylation reaction are lowered. With the noncognate substrates valine and tRNAVal such differences could not be detected. The substrate ATP did not show any change of its Km value as far as the reaction was measurable. Under six different new assay conditions orders of substrate addition and product release followed sixtimes a sequential ordered ter-ter steady-state mechanism with ATP as the first substrate to be added, isoleucine as the second, and tRNAIle as the third one; pyrophosphate is the first product to be released, isoleucyl-tRNA the second, and AMP the third one. In one case this mechanism was modified by a rapid equilibrium segment for addition of ATP and isoleucine. From kcat and Km values and from AMP formation rates discrimination factors for discrimination between tRNAIleII and tRNAValI as well as between isoleucine and valine were determined. In the first case discrimination factors can vary up to a factor of thirty by changes of tRNA or amino-acid concentrations, in the second case discrimination factors are practically invariant. The two different Km values are hypothetically explained by assumption of anticooperativity in a flip-flop mechanism. Two hypothetical catalytic cycles are postulated.

Tryptophanyl adenylate formation by tryptophanyl-tRNA synthetase from Escherichia coli

By gel filtration and titration on DEAE-cellulose filters we show that Escherichia coli tryptophanyl-tRNA synthetase forms tryptophanyl adenylate as an initial reaction product when the enzyme is mixed with ATP-Mg and tryptophan. This reaction precedes the synthesis of the tryptophanyl-ATP ester known to be formed by this enzyme. The stoichiometry of tryptophanyl adenylate synthesis is 2 mol per mole of dimeric enzyme. When this reaction is studied either by the stopped-flow method, by the fluorescence changes of the enzyme, or by radioactive ATP depletion, three successive chemical processes are identified. The first two processes correspond to the synthesis of the two adenylates, at very different rates. The rate constants of tryptophanyl adenylate synthesis are respectively 146 +/- 17 s-1 and 3.3 +/- 0.9 s-1. The third process is the synthesis of tryptophanyl-ATP, the rate constant of which is 0.025 s-1. The Michaelis constants for ATP and for tryptophan in the activation reaction are respectively 179 +/- 35 microM and 23.9 +/- 7.9 microM, for the fast site, and 116 +/- 45 microM and 3.7 +/- 2.2 microM, for the slow site. No synergy between ATP and tryptophan can be evidenced. The data are interpreted as showing positive cooperativity between the subunits associated with conformational changes evidenced by fluorometric methods. The pyrophosphorolysis of tryptophanyl adenylate presents a Michaelian behavior for both sites, and the rate constant of the reverse reaction is 360 +/- 10 s-1 with a binding constant of 196 +/- 12 microM for inorganic pyrophosphate (PPi).(ABSTRACT TRUNCATED AT 250 WORDS)

Construction of heterodimer tyrosyl-tRNA synthetase shows tRNATyr interacts with both subunits

The tyrosyl-tRNA synthetase (EC 6.1.1.1) from Bacillus stearothermophilus is a dimer of two identical subunits. The dimer shows "half-of-the-sites" reactivity in that only one molecule of tyrosyladenylate is formed and one molecule of tRNATyr binds per dimer. To identify whether the tRNATyr binds to a single subunit in the dimer, or to both subunits, heterodimers were constructed by mixing two variant dimers together in 8 M urea. As the unfolded protein is electrophoresed into a native polyacrylamide gel, it refolds and reassociates, and heterodimers can be purified from the parental dimers. Kinetic analysis of heterodimers formed between variant enzymes with defective tyrosine activation or tRNA aminoacylation shows that a molecule of tRNATyr interacts with the N-terminal region of one subunit and the C-terminal region of the other subunit in the dimer.

[Properties of phosphoprotein phosphatase from the rat liver]

Prosphoproteid phosphatase, an enzyme highly specific to lysyl-tRNA-synthetase and proteins of the high-molecular-multienzymic complex of aminoacyl-tRNA-synthetases, was isolated from the rat liver. The data of electrophoresis in 4-30% PAAG with the presence of DS-Na have shown that phosphoproteid phosphatase is homogeneous and its molecular mass is 56 kDa. The isolated phosphoproteid phosphatase is activated by 2.5 mM Mg2+, Mn2+ and is inhibited by ions of univalent metals ions--200 mM Na+, 5 mM K+ as well as by 1 mM ATP, ADP, AMP.

Aminoacylation of rat liver transfer RNA with homologous and heterologous enzyme systems during aging

Total tRNA extracted from livers of young (7 +/- 1 weeks), adult (40 +/- 1 weeks) and old (80 +/- 1 weeks) rats showed quantitative variation with age, being maximal in adults. Young and old animals yielded almost the same level of tRNAs. Quantitative changes in tRNAs were also observed from the study of amino acid acceptor activity using homologous enzyme i.e., aminoacyl-tRNA synthetase preparations from rat liver of the same age group. Quantitative variation followed the trend of qualitative variation. When tRNA was amino-acylated with a heterologous enzyme system, i.e., synthetase preparation from rat liver of another age group, age-related variation in aminoacyl-tRNA did not follow a pattern similar to that in the case of the homologous enzyme system. Young and adult synthetase enzymes showed maximum affinity for their homologous tRNAs but synthetases from old rat liver did not show any specific affinity for "old" tRNAs. This shows that apart from tRNAs, enzyme activity also changes with age.

Methionyl-tRNA synthetase induced 3'-terminal and delocalized conformational transition in tRNAfMet: steady-state fluorescence of tRNA with a single fluorophore

Five species of tRNAfMet labeled with a single fluorophore are prepared to analyze the conformational changes at the 3'-end, at dihydrouridine, and at thiouridine in tRNAfMet upon binding of methionyl-tRNA synthetase. The emission and excitation spectra, anisotropy, and solvent accessibility of the fluorophore in each of the modified tRNAfMet's are determined in the absence and presence of methionyl-tRNA synthetase. The results are consistent with the following. The probes at the 3'-end are in a nonpolar environment, mobile relative to the tRNA molecule, and fully exposed to the solvent. The probes at dihydrouridine are partially stacked over the neighboring bases, nearly immobile, and relatively inaccessible. The S8-C13 cross-linked product is rigid. Upon binding of methionyl-tRNA synthetase, the probes at the 3'-terminus become localized in a less polar environment, highly immobilized, and effectively shielded against solvent access, while the probes at dihydrouridine appear to be partially unstacked from the neighboring base and become slightly more accessible for solvent. Singlet-singlet energy transfer between the intrinsic protein fluorescence and the fluorophores in modified tRNA's was observed by sensitized emission for tRNAfMet modified at the 3'-end and for S8-C13 but not for tRNAfMet's modified at dihydrouridine. These results suggest that dihydrouridine in tRNAfMet is oriented away from methionyl-tRNA synthetase in the tRNA-enzyme complex.

Escherichia coli tyrosyl- and methionyl-tRNA synthetases display sequence similarity at the binding site for the 3'-end of tRNA

Covalent modification of Escherichia coli tyrosyl-tRNA synthetase (TyrRS) by the 2',3'-dialdehyde derivative of tRNATyr (tRNAox) resulted in a time-dependent inactivation of both ATP-PPi exchange and tRNA aminoacylation activities of the enzyme. In parallel with the inactivation, covalent incorporation of approximately 1 mol of [14C]tRNATyrox/mol of the dimeric synthetase occurred. Intact tRNATyr protected the enzyme against inactivation by the tRNA dialdehyde. Treatment of the TyrRS-[14C]tRNATyr covalent complex with alpha-chymotrypsin produced two labeled peptides (A and B) that were isolated and identified by sequence analysis. Peptides A and B are adjacent and together span residues 227-244 in the primary structure of the enzyme. The three lysine residues in this sequence (lysines-229, -234, and -237) are labeled in a mutually exclusive fashion, with lysine-234 being the most reactive. By analogy with the known three-dimensional structure of the homologous tyrosyl-tRNA synthetase from Bacillus stearothermophilus, these lysines should be part of the C-terminal domain which is presumed to bind the cognate tRNA. Interestingly, the labeled TyrRS structure showed significant similarities to the structure around the lysine residue of E. coli methionyl-tRNA synthetase which is the most reactive toward tRNAMetf(ox) (lysine-335) [Hountondji, C., Blanquet, S., & Lederer, F. (1985) Biochemistry 24, 1175-1180].

[Effect of ionizing radiation on methylation of lysyl tRNA synthetase from rat liver]

X-irradiation of animals with an absolutely lethal dose of 0.21 C/kg increases the incorporation of a methyl group into aminoacyl-tRNA-synthetases the radioactive label being traced in lysine, arginine, and histidine. The isolated protein methyltransferase methylated total preparations of aminoacyl-tRNA-synthetases and lysyl-tRNA-synthetase of rat liver in the in vitro experiments with the use of S-adenosylmethionine-14CH3 as a donor of methyl groups: the radioactive label was traced in arginine, lysine, histidine, aspartic and glutamic acids.

Alteration of aminoacyl tRNA synthetases with age: accumulation of heat-labile enzyme molecules in rat liver, kidney and brain

Age-related changes of aminoacyl tRNA synthetases were investigated in tissues from 3- to 24-month-old rats. The proportions of heat-labile enzymes in the liver, kidney and brain were 0-20% in young animals, but 15-40% in old animals. The proportions of heat-labile enzymes increase from about 15 months of age when the probability of death also increases greatly. These findings suggest that decrease in functional activities of various tissues in old animals is in some way related to the accumulation of these altered proteins.

Transition-state stabilization in the mechanism of tyrosyl-tRNA synthetase revealed by protein engineering

The principal catalytic factor in the activation of tyrosine by the tyrosyl-tRNA synthetase is found to be improved binding of ATP in the transition state. The activation reaction involves the attack of the tyrosyl carboxylate on the alpha-phosphate group of ATP to generate a pentacoordinate transition state. Model building of this complex located a binding site for the gamma-phosphate group of ATP, consisting of hydrogen bonds with the side chains of Thr-40 and His-45. Removal of these groups by protein engineering shows that they contribute no binding energy with unreacted ATP but put all of their binding energy into stabilizing the [tyrosine-ATP] transition state [the mutant tyrosyl-tRNA synthetase (Thr-40----Ala-40; His-45----Gly-45) has the rate of formation of tyrosyl adenylate lowered by 3.2 X 10(5) but KS for ATP is lowered by only a factor of 5]. The side chains of these residues also provide a binding site for pyrophosphate in the reverse reaction. Thus, catalysis is accomplished by stabilization of the transition state by improved binding of a group on the substrate that is distant from the seat of reaction.

Isoleucyl-tRNA synthetase from bakers' yeast: multistep proofreading in discrimination between isoleucine and valine with modulated accuracy, a scheme for molecular recognition by energy dissipation

For discrimination between isoleucine and valine by isoleucyl-tRNA synthetase from yeast, a multistep sequence is established. The initial discrimination of the substrates is followed by a pretransfer and a posttransfer hydrolytic proofreading process. The overall discrimination factor D was determined from kcat and Km values observed in aminoacylation of tRNAIle-C-C-A with isoleucine and valine. From aminoacylation of the modified tRNA species tRNAIle-C-C-3'dA and tRNAIle-C-C-A (3'NH2), the initial discrimination factor I (valid for the reversible substrate binding) and the proofreading factor P1 (valid for the aminoacyl adenylate formation) could be determined. Factor I was computed from ATP consumption and D1, the overall discrimination factor for this partial reaction which can be obtained from kinetic constants, and P1 was calculated from AMP formation rates. Proofreading factor P2 (valid for aminoacyl transfer reaction) was determined from AMP formation rates observed in aminoacylation of tRNAIle-C-C-A and tRNAIle-C-C-3'dA. From the initial discrimination factor I and the AMP formation rates, discrimination factor DAMP in aminoacylation of tRNAIle-C-C-A can be calculated. These values deviate by a factor II from factor D obtained by kinetics which may be due to the fact that for acylation of tRNAIle-C-C-A an initial discrimination factor I' = III is valid. The observed overall discrimination varies up to a factor of 16 according to conditions. Under optimal conditions, 38 000 correct aminoacyl-tRNAs are produced per 1 error while the energy of 5.5 ATPs is dissipated. With the determined energetic and molecular flows for the various steps of the enzymatic reaction, a coherent picture of this new type of "far away from equilibrium enzyme" emerges.

Kinetic studies of Escherichia coli elongation factor Tu-guanosine 5'-triphosphate-aminoacyl-tRNA complexes

A new method for measuring the dissociation rate of the Escherichia coli elongation factor Tu-GTP--aminoacyl-tRNA complex has been developed and applied to the determination of the dissociation rates of ternary complexes formed between E. coli EF-Tu-GTP and a set of E. coli aminoacyl-tRNAs. The set of aminoacyl-tRNAs includes at least one tRNA coding for each of the 20 amino acids as well as purified isoacceptor tRNA species for arginine, glycine, leucine, lysine, and tyrosine. The results reveal that the dissociation rates vary for each ternary complex. Tu-GTP-Gln-tRNA dissociates the slowest and Tu-GTP-Val-tRNA the fastest of all noninitiator ternary complexes at 4 degrees C, pH 7.4. The equilibrium dissociation constant for Tu-GTP-Thr-tRNA has been determined to be 1.3 (0.4) X 10(-9) M under identical reaction conditions, and the absolute value of the equilibrium dissociation constant has been calculated for 28 ternary complexes from the relative equilibrium dissociation constant ratios previously measured [Louie, A., Ribeiro, N. S., Reid, B. R., & Jurnak, F. (1984) J. Biol. Chem. 259, 5010-5016]. The association rate of each ternary complex has been estimated from the ratio of the dissociation rate relative to the equilibrium dissociation constant. Tu-GTP-His-tRNA associates the fastest and Tu-GTP-Leu-tRNA1Leu the slowest. By inclusion of Tu-GTP-Met-tRNAfMet in the studies, evidence has been obtained that suggests that the initiator ternary complex does not function in the elongation cycle because the dissociation rate of the complex is very fast.

Influence of supramolecular structure on the enzyme mechanisms of rat liver lysyl-tRNA synthetase-catalyzed reactions. Synthesis of P1,P4-bis(5'-adenosyl)tetraphosphate

Lysyl-tRNA synthetase, dissociated from the multienzyme complexes of aminoacyl-tRNA synthetases from rat liver, was previously found to be 6-fold more active than the synthetase complex in the enzymatic synthesis of P1,P4-bis(5'-adenosyl)tetraphosphate. The bi-substrate and product inhibition kinetics of the reaction are analyzed. Free lysyl-tRNA synthetase exhibits distinctly different kinetic patterns from those of an 18 S synthetase complex containing lysyl-tRNA synthetase. The 18 S synthetase complex shows kinetic patterns which are consistent with an ordered Bi Uni Uni Bi ping-pong mechanism. Free lysyl-tRNA synthetase shows kinetic patterns consistent with a random mechanism. The differences in the enzymatic properties are attributed to the organization of the supramolecular structure of the synthetase complex. The results suggest that association of the synthetases may affect the mechanisms of the synthesis of AppppA.

Reversible dissociation of dimeric tyrosyl-tRNA synthetase by mutagenesis at the subunit interface

Dimeric tyrosyl-tRNA synthetase from Bacillus stearothermophilus exhibits half-of-the-sites reactivity and negative cooperativity in binding of tyrosine. Protein engineering has been applied to the enzyme to determine whether it can be reversibly dissociated into monomers and if the monomers are active. The target for mutation is the residue Phe-164. The side chain of Phe-164 in one subunit interacts with its symmetry-related partner in the other. Mutation of Phe-164----Asp-164 gives a mutant [TyrTS(Asp-164)] that undergoes dissociation at high pH when the aspartate residues are ionized. The monomer is inactive and does not bind tyrosine. Dissociation is enhanced at low concentrations of enzyme by a mass action effect. Kinetic and binding measurements on TyrTS(Asp-164) with tyrosine and tyrosyl adenylate show that the monomer has very weak affinity for these ligands. Accordingly, dimerization is favored by high concentrations of tyrosine and ATP since the dimeric form has a high affinity for the ligands. The presence of tRNA does not encourage dimer formation, and so it must bind to the monomer. TyrTS(Asp-164) is fully active at pH 6 where dimerization is favored but has low activity at pH 7.8 where dissociation is favored. It should now prove possible to engineer heterodimers that may be used to investigate the subunit interactions further.