Mechanism of carbamoyl-phosphate synthetase. Properties of the two binding sites for ATP.

Carbamoyl phosphate synthethase I synthesizes carbamoyl phosphate from ammonia, HCO3- and two molecules of ATP, one of which, ATPA, yields Pi while the other, ATPB, yields the phosphoryl group of carbamoyl phosphate. Pulse-chase experiments with [gamma-32P]ATP without added HCO3- demonstrate separate binding sites for ATPA and ATPB. Bound ATPA dissociates readily from its site (t1/2 approximately 1--2 s) and the Kd is 0.2--0.7 mM. For the ATPB binding site the t1/2 for dissociation is 5--12 s and the Kd approximately 10 mM. Kd for ATPA seems to increase with enzyme concentration whereas Kd for ATPB does not change. HClO4 releases the ATP unchanged from the enzyme . ATPB and enzyme . ATPB . ATPA complexes. In the presence of HCO3-, ATP and N-acetylglutamate, an enzyme . ATPB . HCO3- . ATPA complex is formed. Its formation by the addition of HCO3- to the enzyme . ATPB . ATPA complex appears to involve an initial bimolecular addition reaction followed by an isomerization. Treatment with HClO4 releases Pi from ATPA but ATPB is released unchanged. Spontaneous hydrolysis of ATPA is responsible for the ATPase activity of the enzyme. Thus, a covalent bond may form between HCO3- and ATPA. However, ATPA can dissociate rapidly (t1/2 less than 10 s). The Kd for ATPA is approximately 0.2 mM. ATPB appears unable to dissociate from the enzyme . ATPB . HCO3- . ATPA complex since the t1/2 for dissociation of ATPB from the enzyme is lengthened about five times in the presence of 19 mM HCO3- and at 1 mM ATP. ATPA may also hydrolyse in this complex and be replaced by another molecule of ATP in the absence of exchange of ATPB. However, the ATPA binding site must be occupied to prevent ATPB release. ATPB may be bound in a pocket which becomes inaccessible to the solution when HCO3- and ATPA also bind. In contrast, HCO3- does not inhibit the binding of ATPB to the enzyme. Various intermediate steps in the formation of the enzyme . ATPb . HCO3- . ATPA complex are discussed. Additional evidence is presented that the ATPB binding site is only periodically accessible to ATP in solution and that ATPB in the steady-state reaction binds when the products leave. Since greater than 1.3 mol ATPB and greater than 1.8 mol ATPA bind/mol enzyme dimer, the enzyme monomer may be an active species.     

Phenylalanyl-tRNA synthetase from E. coli MRE-600: analysis of the active site distribution on the enzyme subunits by affinity labelling

Affinity labelling has been employed to localize the substrate-binding sites on the enzyme subunits of phenylalanyl-tRNA synthetase (L-phenylalanine:tRNAPhe-ligase, EC 6.1.1.20) of Escherichia coli MRE-600 (alpha 2 beta 2-type). N-Chlorambucilylphenylalanyl-tRNA, N-bromoacetylphenylalanyl-tRNA, tRNAPhe containing an azido group at the eighth position of the molecule (S4U), tRNAPhe containing azido groups at different points of the molecule, p-azidoanilidate of phenylalanine, adenosine 5'-trimethaphosphate and N-bromoacetyl-L-phenylalaninyladenylate were used in experiments. It has been shown that tRNA-binding sites are formed on heavy beta-subunits of the enzyme. Phenylalanyl-tRNA is also localized on beta-subunits, while the aminoacyl moiety of aminoacyl-tRNA is localized near the contact region of subunits. The phenylalanine-binding site is located on light alpha-subunits of the enzyme. Adenosine 5'-trimethaphosphate and the analogue of phenylalanyladenylate modify both types of enzyme subunits. In our opinion, the catalytic center of tRNA aminoacylation is formed in the contact region of subunits, and the aminoacyl moiety is transferred into tRNA (from the alpha- into beta-subunit in the region of their contact).     

Direct evidence for separate binding sites for L-Glu and amino acid feedback inhibitors on unadenylylated glutamine synthetase from E. coli.

Glutamine synthetase from $\text{E. coli}$ is modulated by adenylylation of a tyrosine residue on each subunit of the dodecamer, as well as by feedback inhibition. With the stopped-flow fluorometric method, the binding constants for L-Glu, L-Ala, D-Val, and Gly to E_1.0—Mg, E⁷, in the absence or presence of ATP or ADP, and NH₃ were evaluated at pH 7.0, 15°. Strong synergistic effects between the amino acids and the nucleotide were observed. The fluorescence amplitude observed due to either simultaneous or sequential addition of 2 different amino acids to E or E·ATP indicate that L-Glu can bind to the enzyme simultaneously with L-Ala, Gly and D-Val; L-Ala can coexist with D-Val, Gly or D-Ala. NMR method also shows that L-Glu and L-Ala can bind simultaneously. Therefore, within our experimental conditions, the unadenylylated enzyme possesses allosteric site(s) for the amino acid inhibitors.     

The topology of the glutamine and ATP binding sites of human asparagine synthetase.

Human asparagine synthetase was examined using a combination of chemical modifiers and specific monoclonal antibodies. The studies were designed to determine the topological relation between the nucleotide binding site and the glutamine binding site of the human asparagine synthetase. The purified recombinant enzyme was chemically modified at the glutamine binding site by 6-diazo-5-oxo-L-norleucine (DON), and at the ATP binding site by 8-azidoadenosine 5'-triphosphate (8-N3ATP). The effects of chemical modification with DON included a loss of glutamine-dependent reactions, but no effect on ATP binding as measured during ammonia-dependent asparagine synthesis. Similarly, modification with 8-N3ATP resulted in a loss of ammonia-dependent asparagine synthesis, but no effect on the glutaminase activity. A series of monoclonal antibodies was also examined in relation to their epitopes and the sites modified by the two covalent chemical modifiers. It was found that several antibodies were prevented from binding by specific chemical modification, and that the antibodies could be classified into groups correlating to their relative binding domains. These results are discussed in terms of relative positions of the glutamine and ATP binding sites on asparagine synthetase.     

Correlation between binding rate constants and individual information of E. coli Fis binding sites

Individual protein binding sites on DNA can be measured in bits of information. This information is related to the free energy of binding by the second law of thermodynamics, but binding kinetics appear to be inaccessible from sequence information since the relative contributions of the on- and off-rates to the binding constant, and hence the free energy, are unknown. However, the on-rate could be independent of the sequence since a protein is likely to bind once it is near a site. To test this, we used surface plasmon resonance and electromobility shift assays to determine the kinetics for binding of the Fis protein to a range of naturally occurring binding sites. We observed that the logarithm of the off-rate is indeed proportional to the individual information of the binding sites, as predicted. However, the on-rate is also related to the information, but to a lesser degree. We suggest that the on-rate is mostly determined by DNA bending, which in turn is determined by the sequence information. Finally, we observed a break in the binding curve around zero bits of information. The break is expected from information theory because it represents the coding demarcation between specific and nonspecific binding.     

Phenylalanyl-tRNA synthetase from E. coli MRE-600. Effect of chemical modification of lysine residues on the enzyme interaction with substrates

The effect of modification of Phe-RSase from E. coli MRE-600 by pyridoxal-5'-phosphate and 2', 3'-dialdehyde derivative of ATP and L-phenylalanynyl-5'-adenylate obtained by periodate oxidation on the enzyme interaction with substrates was investigated. It was shown that modification of Phe-RSase by pyridoxal-5'-phosphate and 2', 3'-dialdehyde derivative of ATP leads to a decrease of the aminoacylation rate without changing the rate of the ATP-[32P]-pyrophosphate exchange reaction. The substrate analogs L-phenylalanynol and L-phenyl-alanynyladenylate increase the degree of Phe-RSase inactivation in the aminoacylation reaction. tRNAphe strongly protects the enzyme against inactivation. ATP, both in the absence (in case of modification with pyridoxal-5'-phosphate) and in- the presence of Mg2+ and phenylalanine (in case of modification with o-ATP) exhibits a pronounced protective effect. L-Phe does not protect the enzyme against the inactivation by pyridoxal-5'-phosphate or o-ATP. The dissociation constant of the Phe-RSase[14C]-Phe-tRNAphe complex increases 2.5 -- 5-fold after the enzyme modification by pyridoxal-5'-phosphate, while the Km value for tRNAphe decreases approximately two times in the aminoacylation reaction. There are no changes in the Km values for amino acid and ATP and the Hill coefficients for all substrates tested. Modification of Phe-RSase by pyridoxal-5'-phosphate leads to a decrease of stability of the aminoacyladenylate -- enzyme complex. Oxidized L-phenylalanynyladenylate does not produce enzyme inactivation either by aminoacylation or in the isotropic ATP-PP iota exchange reaction. It is assumed that Phe-RSase from E. coli MRE-600 contains some lysine residues essential for binding and aminoacylation of tRNA, which do not occur in the ATP-binding subsite and aminoacyladenylate formation center.     

Palindromic units from E. coli as binding sites for a chromoid-associated protein

Several hundred copies of a highly conserved extragenic palindromic sequence, 20-40 nucleotides long, exist along the chromosome of E. coli and S. typhimurium. These have been defined as palindromic units (PU) or repetitive extragenic palindromes (REP). No general function for PUs has been identified. In the present work, we provide data showing that a protein associated with a chromoid extract of E. coli protects PU DNA against exonuclease III digestion. This provides the first experimental evidence that PU constitutes binding sites for a chromoid-associated protein. This result supports the hypothesis that PUs could play a role in the structure of the bacterial chromoid.     

Interacting binding sites of isoleucyl-tRNA synthetase from Escherichia coli studied by equilibrium partition.

The binding of tRNAIIe to isoleucyl-tRNA synthetase in the presence of isoleucine or ATP was investigated using the equilibrium partition method. Isoleucine decreased the affinity of tRNAIIe for the enzyme by a factor of about 5. For the free standard energy of interaction a value of about 1 kcal/mol (4.2 kJ/mol) was calculated. ATP exhibits qualitatively the same effect as isoleucine. A binding of two molecules isoleucine per molecule of enzyme could not be demonstrated even in the presence of ATP and pyrophosphatase.     

Affinity chromatography on agarose-hexyl-adenosine-5'-phosphate of methionyl-tRNA synthetase from Escherichia coli. Application of the couplings between the methionine and ATP sites.

Recent studies by us [Biochemistry (1977) 16, 2570-2579] have shown that L-methioninol, a methionine analog lacking the carboxylate negative charge, enhances the affinity of AMP for methionyl-tRNA synthetase while L-methionine antagonizes the nucleotide binding. Such couplings between ligands of the enzyme have now been applied to affinity chromatography of methionyl-tRNA synthetase on an agarose-hexyl-adenosine-5'-phosphate gel (the spacer is attached to AMP at the adenine C-8 position). Retention of the enzyme on this gel column was shown to be dependent on the presence of appropriate concentrations of magnesium and of L-methioninol in the equilibration buffer. The enzyme was then specifically recovered from the column by omitting the amino alcohol or by adding an excess of L-methionine which antagonizes the cooperative effect of L-methioninol. This approach has provided the basis for a new purification procedure of methionyl-tRNA synthetase which leads to a 200-fold purification in a single chromatographic step. In this manner, after 30-50% ammonium sulfate fractionation of extracts of Escherichia coli EM 20031 (carrying the F32 episome), 0.25 mg X methionyl-tRNA synthetase was obtained at 90% purity per ml of agarose-hexyl-adenosine-5'-phosphate gel.     

Misacylation and editing by Escherichia coli valyl-tRNA synthetase: evidence for two tRNA binding sites.

Valyl-tRNA synthetase (ValRS) has difficulty discriminating between its cognate amino acid, valine, and structurally similar amino acids. To minimize translational errors, the enzyme catalyzes a tRNA-dependent editing reaction that prevents accumulation of misacylated tRNA(Val). Editing occurs with threonine, alanine, serine, and cysteine, as well as with several nonprotein amino acids. The 3'-end of tRNA plays a vital role in promoting the tRNA-dependent editing reaction. Valine tRNA having the universally conserved 3'-terminal adenosine replaced by any other nucleoside does not stimulate the editing activity of ValRS. As a result 3'-end tRNA(Val) mutants, particularly those with 3'-terminal pyrimidines, are stably misacylated with threonine, alanine, serine, and cysteine. Valyl-tRNA synthetase is unable to hydrolytically deacylate misacylated tRNA(Val) terminating in 3'-pyrimidines but does deacylate mischarged tRNA(Val) terminating in adenosine or guanosine. Evidently, a purine at position 76 of tRNA(Val) is essential for translational editing by ValRS. We also observe misacylation of wild-type and 3'-end mutants of tRNA(Val) with isoleucine. Valyl-tRNA synthetase does not edit wild-type tRNA(Val)(A76) mischarged with isoleucine, presumably because isoleucine is only poorly accommodated at the editing site of the enzyme. Misacylated mutant tRNAs as well as 3'-end-truncated tRNA(Val) are mixed noncompetitive inhibitors of the aminoacylation reaction, suggesting that ValRS, a monomeric enzyme, may bind more than one tRNA(Val) molecule. Gel-mobility-shift experiments to characterize the interaction of tRNA(Val) with the enzyme provide evidence for two tRNA binding sites on ValRS.     

19F NMR evidence for interactions between the c-AMP binding sites on the c-AMP receptor protein from E. coli.

The 19F NMR spectra of 3-fluorotyrosine containing c-AMP receptor protein (CRP) from E. coli have been recorded in the presence of increasing amounts of c-AMP. One of the signals (from Tyr B) shifts upfield by 0.6 ppm in the presence of excess c-AMP and shows both slow and fast exchange behaviour during the titration. This is evidence for interactions between the two c-AMP binding sites on the CRP dimer leading to different dissociation rate constants (less than or equal to 75 s-1; greater than or equal to 350 s-1) for complexes containing one and two c-AMP molecules.     

Dual binding sites for translocation catalysis by Escherichia coli glutathionylspermidine synthetase

Most organisms use glutathione to regulate intracellular thiol redox balance and protect against oxidative stress; protozoa, however, utilize trypanothione for this purpose. Trypanothione biosynthesis requires ATP-dependent conjugation of glutathione (GSH) to the two terminal amino groups of spermidine by glutathionylspermidine synthetase (GspS) and trypanothione synthetase (TryS), which are considered as drug targets. GspS catalyzes the penultimate step of the biosynthesis-amide bond formation between spermidine and the glycine carboxylate of GSH. We report herein five crystal structures of Escherichia coli GspS in complex with substrate, product or inhibitor. The C-terminal of GspS belongs to the ATP-grasp superfamily with a similar fold to the human glutathione synthetase. GSH is likely phosphorylated at one of two GSH-binding sites to form an acylphosphate intermediate that then translocates to the other site for subsequent nucleophilic addition of spermidine. We also identify essential amino acids involved in the catalysis. Our results constitute the first structural information on the biochemical features of parasite homologs (including TryS) that underlie their broad specificity for polyamines.     

Quantitative analysis of ribosome binding sites in E.coli.

185 clones with randomized ribosome binding sites, from position -11 to 0 preceding the coding region of beta-galactosidase, were selected and sequenced. The translational yield of each clone was determined; they varied by more than 3000-fold. Multiple linear regression analysis was used to determine the contribution to translation initiation activity of each base at each position. Features known to be important for translation initiation, such as the initiation codon, the Shine/Dalgarno sequence, the identity of the base at position -3 and the occurrence of alternative ATGs, are all found to be important quantitatively for activity. No other features are found to be of general significance, although the effects of secondary structure can be seen as outliers. A comparison to a large number of natural E.coli translation initiation sites shows the information profile to be qualitatively similar although differing quantitatively. This is probably due to the selection for good translation initiation sites in the natural set compared to the low average activity of the randomized set.     

ATP binding to noncatalytic sites of chloroplast coupling factor CF1

A kinetic analysis of ATP binding to noncatalytic sites of chloroplast coupling factor CF₁ was made. The ATP binding proved to be unaffected by reduction of the disulfide bridge of the CF₁ -subunit. The first-order equation describing nucleotide binding to noncatalytic sites allowed for two vacant nucleotide binding sites different in their kinetics. As suggested by nucleotide concentration dependence of the rate of nucleotide binding, the tight binding was preceded by rapid reversible binding of nucleotides. Preincubation of CF₁ with Mg²⁺ resulted in a decreased rate of ATP binding. ATP dissociation from noncatalytic sites was described by the first order equation for similar sites with a dissociation rate constant k _d (ATP) 10^–3 min^–1. Noncatalytic sites of CF₁ were shown to be not homogeneous. One of them retained the major part of endogenous ADP after precipitation of CF₁ with ammonium sulfate. Its two other sites differed in kinetic parameters and affinity for ATP. Anions of phosphate, sulfite, and especially, pyrophosphate inhibited the interaction between ATP and the noncatalytic sites.     

Functional group recognition at the aminoacylation and editing sites of E. coli valyl-tRNA synthetase

To correct misactivation and misacylation errors, Escherichia coli valyl-tRNA synthetase (ValRS) catalyzes a tRNA(Val)-dependent editing reaction at a site distinct from its aminoacylation site. Here we examined the effects of replacing the conserved 3'-adenosine of tRNA(Val) with nucleoside analogs, to identify structural elements of the 3'-terminal nucleoside necessary for tRNA function at the aminoacylation and editing sites of ValRS. The results show that the exocyclic amino group (N6) is not essential: purine riboside-substituted tRNA(Val) is active in aminoacylation and in stimulating editing. Presence of an O6 substituent (guanosine, inosine, xanthosine) interferes with aminoacylation as well as posttransfer and total editing (pre- plus posttransfer editing). Because ValRS does not recognize substituents at the 6-position, these results suggest that an unprotonated N1, capable of acting as an H-bond acceptor, is an essential determinant for both the aminoacylation and editing reactions. Substituents at the 2-position of the purine ring, either a 2-amino group (2-aminopurine, 2,6-diaminopurine, guanosine, and 7-deazaguanosine) or a 2-keto group (xanthosine, isoguanosine), strongly inhibit both aminoacylation and editing. Although aminoacylation by ValRS is at the 2'-OH, substitution of the 3'-terminal adenosine of tRNA(Val) with 3'-deoxyadenosine reduces the efficiency of valine acceptance and of posttransfer editing, demonstrating that the 3'-terminal hydroxyl group contributes to tRNA recognition at both the aminoacylation and editing sites. Our results show a strong correlation between the amino acid accepting activity of tRNA and its ability to stimulate editing, suggesting misacylated tRNA is a transient intermediate in the editing reaction, and editing by ValRS requires a posttransfer step.