The contribution of adjacent subunits to the active sites of D-3-phosphoglycerate dehydrogenase

D-3-Phosphoglycerate dehydrogenase (PGDH) from Escherichia coli is allosterically inhibited by L-serine, the end product of its metabolic pathway. Previous results have shown that inhibition by serine has a large effect on Vmax and only a small or negligible effect on Km. PGDH is thus classified as a V-type allosteric enzyme. In this study, the active site of PGDH has been studied by site-directed mutagenesis to assess the role of certain residues in substrate binding and catalysis. These consist of a group of cationic residues (Arg-240, Arg-60, Arg-62, Lys-39, and Lys-141') that potentially form an electrostatic environment for the binding of the negatively charged substrate, as well as the only tryptophan residue found in PGDH and which fits into a hydrophobic pocket immediately adjacent to the active site histidine residue. Interestingly, Trp-139' and Lys-141' are part of the polypeptide chain of the subunit that is adjacent to the active site. The results of mutating these residues show that Arg-240, Arg-60, Arg-62, and Lys-141' play distinct roles in the binding of the substrate to the active site. Mutants of Trp-139' show that this residue may play a role in stabilizing the catalytic center of the enzyme. Furthermore, these mutants appear to have a significant effect on the cooperativity of serine inhibition and suggest a possible role for Trp-139' in the cooperative interactions between subunits.     

2'-Versus 3'-OH specificity in tRNA aminoacylation. Further support for the "secondary cognition" proposal.

Purified Escherichia coli tRNAAla and tRNALys were each converted to modified species terminating in 2'- and 3'-deoxyadenosine. The modified species were tested as substrates for activation by their cognate aminoacyl-tRNA synthetases and for misacylation with phenylalanine by yeast phenylalanyl-tRNA synthetase. E. coli alanyl- and lysyl-tRNA synthetases normally aminoacylate their cognate tRNA's exclusively on the 3'-OH group, while yeast phenylalanyl-tRNA synthetase utilizes only the 2' position on its own tRNA. Therefore, the finding that the phenylalanyl-tRNA synthetase activated only those modified tRNAAla and tRNALys species terminating in 3'-deoxyadenosine indicated that the position of aminoacylation in this case was specified entirely by the enzyme, an observation relevant to the more general problem of the reason(s) for using a particular site for aminoacylation and maintaining positional specificity during evolution. Initial velocity studies were carried out using E. coli tRNAAla and both alanyl- and phenylalanyl-tRNA synthetases. As noted in other cases, activation of the modified and unmodified tRNA's had essentially the same associated Km values, but in each case the Vmax determined for the modified tRNA was smaller.     

The importance of a critical protonation state and the fate of the catalytic steps in class A beta-lactamases and penicillin-binding proteins

Beta-lactamases and penicillin-binding proteins are bacterial enzymes involved in antibiotic resistance to beta-lactam antibiotics and biosynthetic assembly of cell wall, respectively. Members of these large families of enzymes all experience acylation by their respective substrates at an active site serine as the first step in their catalytic activities. A Ser-X-X-Lys sequence motif is seen in all these proteins, and crystal structures demonstrate that the side-chain functions of the serine and lysine are in contact with one another. Three independent methods were used in this report to address the question of the protonation state of this important lysine (Lys-73) in the TEM-1 beta-lactamase from Escherichia coli. These techniques included perturbation of the pK(a) of Lys-73 by the study of the gamma-thialysine-73 variant and the attendant kinetic analyses, investigation of the protonation state by titration of specifically labeled proteins by nuclear magnetic resonance, and by computational treatment using the thermodynamic integration method. All three methods indicated that the pK(a) of Lys-73 of this enzyme is attenuated to 8.0-8.5. It is argued herein that the unique ground-state ion pair of Glu-166 and Lys-73 of class A beta-lactamases has actually raised the pK(a) of the active site lysine to 8.0-8.5 from that of the parental penicillin-binding protein. Whereas we cannot rule out that Glu-166 might activate the active site water, which in turn promotes Ser-70 for the acylation event, such as proposed earlier, we would like to propose as a plausible alternative for the acylation step the possibility that the ion pair would reconfigure to the protonated Glu-166 and unprotonated Lys-73. As such, unprotonated Lys-73 could promote serine for acylation, a process that should be shared among all active-site serine beta-lactamases and penicillin-binding proteins.     

Site-directed mutagenesis of lysine 58 in a putative ATP-binding domain of the calmodulin-sensitive adenylate cyclase from Bordetella pertussis abolishes catalytic activity

A 2.7-kb cya A gene fragment encoding the amino-terminal end of the calmodulin-sensitive adenylate cyclase from Bordetella pertussis has been placed under the control of the lac promoter for expression in Escherichia coli. Following induction with isopropyl beta-D-thiogalactoside, calmodulin-sensitive adenylate cyclase activity was detected in a cell extract from E. coli. The expression vector directed the synthesis of a 90-kDa polypeptide that was recognized by rabbit polyclonal antibodies raised against the catalytic subunit of B. pertussis adenylate cyclase. Inspection of the deduced amino acid sequence of the cya A gene product revealed a sequence with homology to consensus sequences for an ATP-binding domain found in many ATP-binding proteins. On the basis of the analysis of nucleotide binding proteins, a conserved lysine residue has been implicated in the binding of ATP. A putative ATP-binding domain in the B. pertussis adenylate cyclase possesses an analogous lysine residue at position 58. To test whether lysine 58 of the B. pertussis adenylate cyclase is a crucial residue for enzyme activity, it was replaced with methionine by oligonucleotide-directed mutagenesis. E. coli cells were transformed with the mutant cya A gene, and the expressed gene product was characterized. The mutant protein exhibited neither basal nor calmodulin-stimulated enzyme activity, indicating that lysine 58 plays a critical role in enzyme catalysis.     

Reconstruction by site-directed mutagenesis of the transition state for the activation of tyrosine by the tyrosyl-tRNA synthetase: a mobile loop envelopes the transition state in an induced-fit mechanism

Site-directed mutagenesis of the tyrosyl-tRNA synthetase followed by kinetic studies has shown that residues which are distant from the active site of the free enzyme are brought into play as the structure of the enzyme changes during catalysis. Positively charged side chains which are in mobile loops of the enzyme envelope the negatively charged pyrophosphate moiety during the transition state for the formation of tyrosyl adenylate in an induced-fit mechanism. Residues Lys-82 and Arg-86, which are on one side of the rim of the binding site pocket, and Lys-230 and Lys-233, which are on the other side, have been mutated to alanine residues and also to asparagine or glutamine. The resultant mutants still form 1 mol of tyrosyl adenylate/mol of dimer but with rate constants up to 8000 times lower. Construction of difference energy diagrams reveals that all the residues specifically interact with the transition state for the reaction and with pyrophosphate in the E.Tyr-AMP.PPi complex. Yet, the epsilon-NH3+ groups of Lys-230 and Lys-233 in the crystalline enzyme are at least 8 A too far away to interact with the pyrophosphate moiety in the transition state at the same time as do Lys-82 and Arg-86. Binding of substrates must, therefore, induce a conformational change in the enzyme that brings these residues into range. Consistent with this proposal is the observation that all four residues are in flexible regions of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure of the acceptor stem of Escherichia coli tRNA Ala: role of the G3.U70 base pair in synthetase recognition.

The fidelity of translation of the genetic code depends on accurate tRNA aminoacylation by cognate aminoacyl-tRNA synthetases. Thus, each tRNA has specificity not only for codon recognition, but also for amino acid identity; this aminoacylation specificity is referred to as tRNA identity. The primary determinant of the acceptor identity of Escherichia coli tRNAAlais a wobble G3.U70 pair within the acceptor stem. Despite extensive biochemical and genetic data, the mechanism by which the G3.U70 pair marks the acceptor end of tRNAAla for aminoacylation with alanine has not been clarified at the molecular level. The solution structure of a microhelix derived from the tRNAAla acceptor end has been determined at high precision using a very extensive set of experimental constraints (approximately 32 per nt) obtained by heteronuclear multidimensional NMR methods. The tRNAAla acceptor end is overall similar to A-form RNA, but important differences are observed. The G3.U70 wobble pair distorts the conformation of the phosphodiester backbone and presents the functional groups of U70 in an unusual spatial location. The discriminator base A73 has extensive stacking overlap with G1 within the G1.C72 base pair at the end of the double helical stem and the -CCA end is significantly less ordered than the rest of the molecule.     

Characterization of ATP and calmodulin-binding properties of a truncated form of Bacillus anthracis adenylate cyclase

The Bacillus anthracis cya gene encodes a calmodulin-dependent adenylate cyclase. A deletion cya gene product obtained by removing 261 codons at the 5' end was expressed in a protease-deficient lon- E. coli strain and purified to homogeneity. This truncated enzyme (CYA 62) exhibits catalytic and calmodulin-binding properties similar to the properties of wild-type adenylate cyclase from B. anthracis culture supernatants, i.e., a kcat of 1100 s-1 at 30 degrees C and pH 8, an apparent Km for ATP of 0.25 mM, and a Kd for bovine brain calmodulin of 23 nM. The calmodulin-binding domain of the CYA 62 truncated enzyme was labeled with a cleavable radioactive photoaffinity cross-linker coupled to calmodulin. The labeled CYA 62 protein was then cleaved with cyanogen bromide and N-chlorosuccinimide. We show that the calmodulin-binding domain of B. anthracis adenylate cyclase is located within the last 150 amino acid residues of the protein. A further deletion at the 3' end of the CYA 62 coding sequence yielded an adenylate cyclase species (CYA 57) lacking 127 C-terminal amino residues. CYA 57, still sensitive to activation by high concentrations of calmodulin, exhibits less than 0.1% of the specific activity of CYA 62. Binding of 3'dATP (a competitive inhibitor) to CYA 62 was determined by equilibrium dialysis. In the absence of calmodulin, binding of the ATP analogue to this truncated protein was severely impaired, which explains, at least in part, the absolute requirement for calmodulin for the catalytic activity of B. anthracis adenylate cyclase.     

Analysis of core sequences in the D-Phe activating domain of the multifunctional peptide synthetase TycA by site-directed mutagenesis.

The D-phenylalanine-activating enzyme tyrocidine synthetase I (TycA) from Bacillus brevis ATCC 8185 was overexpressed in Escherichia coli, purified to homogeneity, and assayed for ATP-PPi exchange and covalent binding of phenylalanine by the thiotemplate mechanism. Amino acid exchanges in four different cores of TycA created by site-directed mutagenesis revealed the amino acid residues involved in aminoacyladenylate formation and in covalent thioester formation. Mutations in the putative ATP-binding site SGTTGKPKG caused a decreased phenylalanine-dependent ATP-PPi exchange activity to 10% of the wild-type level for a Lys-186-to-Arg substitution and an almost complete loss of activity (< 1%) for a Lys-186-to-Thr exchange. Alteration of Asp-401 to Asn in the ATPase motif TGDL of TycA decreased the phenylalanine-dependent ATP-PPi exchange activity to 75% of wild type, while an Asp-401-to-Ser mutation decreased the activity to 10% of the wild-type level. Replacement of Ser-562 in the putative thioester-binding motif LGGDSI to Ala or Gly caused a reduction in trichloroacetic acid-precipitable TycA-[14C]phenylalanine complex to one-third of the wild-type level. However, no cleavable [14C]phenylalanine could be detected after treatment with performic acid, indicating that the resulting mutant was unable to form thioester with phenylalanine. In E. coli, TycA was labeled with beta-[3H]alanine, a precursor of 4'-phosphopantetheine, indicating that TycA is modified with a beta-alanine-containing cofactor.     

Lysine 356 is a critical residue for binding the C-6 phospho group of fructose 2,6-bisphosphate to the fructose-2,6-bisphosphatase domain of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase.

Lysine 356 has been implicated by protein modification studies as a fructose-2,6-bisphosphate binding site residue in the 6-phosphofructo-2-kinase domain of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (Kitajima, S., Thomas, H., and Uyeda, K. (1985) J. Biol. Chem. 260, 13995-14002). However, Lys-356 is found in the fructose-2,6-bisphosphatase domain (Bazan, F., Fletterick, R., and Pilkis, S. J. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9642-9646). In order to ascertain whether Lys-356 is involved in fructose-2,6-bisphosphatase catalysis and/or domain/domain interactions of the bifunctional enzyme, Lys-356 was mutated to Ala, expressed in Escherichia coli, and then purified to homogeneity. Circular dichroism experiments indicated that the secondary structure of the Lys-356-Ala mutant was not significantly different from that of the wild-type enzyme. The Km for fructose 2,6-bisphosphate and the Ki for the noncompetitive inhibitor, fructose 6-phosphate, for the fructose-2,6-bisphosphatase of the Lys-356-Ala mutant were 2700- and 2200-fold higher, respectively, than those of the wild-type enzyme. However, the maximal velocity and the Ki for the competitive product inhibitor, inorganic phosphate, were unchanged compared to the corresponding values of the wild-type enzyme. Furthermore, in contrast to the wild-type enzyme, which exhibits substrate inhibition, there was no inhibition by substrate of the Lys-356-Ala mutant. In the presence of saturating substrate, inorganic phosphate, which acts by relieving fructose-6-phosphate and substrate inhibition, is an activator of the bisphosphatase. The Ka for inorganic phosphate of the Lys-356-Ala mutant was 1300-fold higher than that of the wild-type enzyme. The kinetic properties of the 6-phosphofructo-2-kinase of the Lys-356-Ala mutant were essentially identical with that of the wild-type enzyme. The results demonstrate that: 1) Lys-356 is a critical residue in fructose-2,6-bisphosphatase for binding the 6-phospho group of fructose 6-phosphate/fructose 2,6-bisphosphate; 2) the fructose 6-phosphate binding site is responsible for substrate inhibition; 3) Inorganic phosphate activates fructose-2,6-bisphosphatase by competing with fructose 6-phosphate for the same site; and 4) Lys-356 is not involved in 6-phosphofructo-2-kinase substrate/product binding or catalysis.     

Purification and properties of 2-aminoadipate: 2-oxoglutarate aminotransferase from bovine kidney.

Escherichia coli endonuclease IV hydrolyses the C(3')-O-P bond 5' to a 3'-terminal base-free deoxyribose. It also hydrolyses the C(3')-O-P bond 5' to a 3'-terminal base-free 2',3'-unsaturated sugar produced by nicking 3' to an AP (apurinic or apyrimidinic) site by beta-elimination; this explains why the unproductive end produced by beta-elimination is converted by the enzyme into a 3'-OH end able to prime DNA synthesis. The action of E. coli endonuclease IV on an internal AP site is more complex: in a first step the C(3')-O-P bond 5' to the AP site is hydrolysed, but in a second step the 5'-terminal base-free deoxyribose 5'-phosphate is lost. This loss is due to a spontaneous beta-elimination reaction in which the enzyme plays no role. The extreme lability of the C(3')-O-P bond 3' to a 5'-terminal AP site contrasts with the relative stability of the same bond 3' to an internal AP site; in the absence of beta-elimination catalysts, at 37 degrees C the half-life of the former is about 2 h and that of the latter 200 h. The extreme lability of a 5'-terminal AP site means that, after nicking 5' to an AP site with an AP endonuclease, in principle no 5'----3' exonuclease is needed to excise the AP site: it falls off spontaneously. We have repaired DNA containing AP sites with an AP endonuclease (E. coli endonuclease IV or the chromatin AP endonuclease from rat liver), a DNA polymerase devoid of 5'----3' exonuclease activity (Klenow polymerase or rat liver DNA polymerase beta) and a DNA ligase. Catalysts of beta-elimination, such as spermine, can drastically shorten the already brief half-life of a 5'-terminal AP site; it is what very probably happens in the chromatin of eukaryotic cells. E. coli endonuclease IV also probably participates in the repair of strand breaks produced by ionizing radiations: as E. coli endonuclease VI/exonuclease III, it is a 3'-phosphoglycollatase and also a 3'-phosphatase. The 3'-phosphatase activity of E. coli endonuclease VI/exonuclease III and E. coli endonuclease IV can also be useful when the AP site has been excised by a beta delta-elimination reaction.     

Chemical modification by pyridoxal 5''-phosphate and cyclohexane-1,2-dione indicates that Lys-7 and Arg-10 are involved in the p2 phosphate-binding subsite of bovine pancreatic ribonuclease A.

Steric and chemical evidence had previously shown that residues Lys-7 and/or Arg-10 of bovine pancreatic RNAase A could belong to the p2 phosphate-binding subsite, adjacent to the 3' side of the main site p1. In the present work chemical modification of the enzyme with pyridoxal 5'-phosphate and cyclohexane-1,2-dione was carried out in order to identify these residues positively as part of the p2 site. The reaction with pyridoxal 5'-phosphate yields three monosubstituted derivatives, at Lys-1, Lys-7 and Lys-41. A strong decrease in the yield of derivatives at Lys-7 and Lys-41 was observed when either p1 or p2 was specifically blocked by 5'-AMP or 3'-AMP respectively. These experiments indicate that both sites are needed for the reaction of pyridoxal 5'-phosphate with RNAase A to take place. The positive charge in one of the sites interacts with the phosphate group of pyridoxal 5'-phosphate, giving the proper orientation to the carbonyl group, which then reacts with the lysine residue present in the other site. The absence of reaction between pyridoxal 5'-phosphate and an RNAase derivative that has the p2 site blocked supports this hypothesis. Labelling of Lys-7 with pyridoxal 5'-phosphate has a more pronounced effect on the kinetics with RNA than with the smaller substrate 2',3'-cyclic CMP. In addition, when the phosphate moiety of the 5'-phosphopyridoxyl group was removed with alkaline phosphatase the kinetic constants with 2',3'-cyclic CMP returned to values very similar to those of the native enzyme, whereas a higher Km and lower Vmax. were still observed for RNA. This indicates that this new derivative has recovered a free p1 site and, hence, the capability to act on 2',3'-cyclic CMP, but the presence of the pyridoxyl group bound to Lys-7 is still blocking a secondary phosphate-binding site, namely p2. Finally, reaction of cyclohexane-1,2-dione at Arg-10 is suppressed in the presence of 3'-AMP but only a 19% decrease is observed with 5'-AMP, suggesting that Arg-10 is also close to the p2 phosphate-binding subsite.     

Guanylate cyclase activity in Escherichia coli mutants defective in adenylate cyclase.

Guanylate cyclase, which catalyzes the synthesis of guanosine 3',5'-monophosphate, has been assayed in several strains of Escherichia coli. They include wild-type cells and mutants defective in adenylate cyclase, which is responsible for the synthesis of adenosine 3',5'-phosphate. Our results demonstrate that adenylate cyclase and guanylate cyclase are two different enzymes in E. coli and suggest that the gene that encodes adenylate cyclase also plays a regulatory role in the synthesis of guanylate cyclase.     

Conformational changes of yeast plasma membrane H(+)-ATPase during activation by glucose: role of threonine-912 in the carboxy-terminal tail

Yeast Pma1 H(+)-ATPase, which belongs to the P-type family of cation-transporting ATPases, is activated up to 10-fold by growth on glucose, and indirect evidence has linked the activation to Ser/Thr phosphorylation within the C-terminal tail. We have now used limited trypsinolysis to map glucose-induced conformational changes throughout the 100 kDa ATPase. In the wild-type enzyme, trypsin cleaves first at Lys-28 and Arg-73 in the extended N-terminal segment (sites T1 and T2); subsequent cleavages occur at Arg-271 between the A domain and M3 (site T3) and at Lys-749 or Lys-754 in the M6-M7 cytoplasmic loop (site T4). Activation by glucose leads to a striking increase in trypsin sensitivity. At the C-terminal end of the protein, the Arg- and Lys-rich tail is shielded from trypsin in membranes from glucose-starved cells (GS) but becomes accessible in membranes from glucose-metabolizing cells (GM). In the presence of orthovanadate, Lys-174 at the boundary between M2 and the A domain also becomes open to cleavage in GM but not GS samples (site T5). Significantly, this global conformational change can be suppressed by mutations at Thr-912, a consensus phosphorylation site near the C-terminus. Substitution by Ala at position 912 leads to a GS-like (trypsin-resistant) state, while substitution by Asp leads to a GM-like (trypsin-sensitive) state. Thus, the present results help to dissect the intramolecular movements that result in glucose activation.     

Movement of the biotin carboxylase B-domain as a result of ATP binding

Acetyl-CoA carboxylase catalyzes the first committed step in fatty acid synthesis. In Escherichia coli, the enzyme is composed of three distinct protein components: biotin carboxylase, biotin carboxyl carrier protein, and carboxyltransferase. The biotin carboxylase component has served for many years as a paradigm for mechanistic studies devoted toward understanding more complicated biotin-dependent carboxylases. The three-dimensional x-ray structure of an unliganded form of E. coli biotin carboxylase was originally solved in 1994 to 2.4-A resolution. This study revealed the architecture of the enzyme and demonstrated that the protein belongs to the ATP-grasp superfamily. Here we describe the three-dimensional structure of the E. coli biotin carboxylase complexed with ATP and determined to 2.5-A resolution. The major conformational change that occurs upon nucleotide binding is a rotation of approximately 45(o) of one domain relative to the other domains thereby closing off the active site pocket. Key residues involved in binding the nucleotide to the protein include Lys-116, His-236, and Glu-201. The backbone amide groups of Gly-165 and Gly-166 participate in hydrogen bonding interactions with the phosphoryl oxygens of the nucleotide. A comparison of this closed form of biotin carboxylase with carbamoyl-phosphate synthetase is presented.     

Insertional mutagenesis of Bordetella pertussis adenylate cyclase.

We developed an improved method of linker insertion mutagenesis for introducing 2 or 16 codons into the Bordetella pertussis cyaA gene which encodes a calmodulin-dependent adenylate cyclase. A recombinant kanamycin resistance cassette, containing oligonucleotide linkers, was cloned in plasmids which carried a truncated cyaA gene, fused at its 3' end to the 5' end of the Escherichia coli lacZ gene, specifying the alpha-peptide. This construction permitted a double selection for in-frame insertions by using screening for kanamycin resistance and for lactose-positive phenotype, resulting from alpha-complementation. We showed that most of the two-amino acid insertions within the N-terminal moiety of the catalytic domain of adenylate cyclase abolished enzymatic activity and/or altered the stability of the protein. All two-amino acid insertions within the C-terminal part of adenylate cyclase resulted in fully stable and active enzymes. These results confirm the modular structure of the catalytic domain of adenylate cyclase, previously proposed on the basis of proteolytic studies. Two-amino acid insertions between residues 247-248 and 335-336 were shown to affect the calmodulin responsiveness of adenylate cyclase, suggesting that the corresponding region in the enzyme is involved in the binding of calmodulin or in the process of calmodulin activation. In addition, we have identified within the primary structure of adenylate cyclase several permissive sites which tolerate 16-amino acid insertions without interfering with the catalytic activity or calmodulin binding. By inserting foreign antigenic determinants into these permissive sites the resulting recombinant adenylate cyclase toxin could be used to deliver specific epitopes into antigen-presenting cells.     

Evolutionary conservation of a functionally important backbone phosphate group critical for aminoacylation of histidine tRNAs

All histidine tRNA molecules have an extra nucleotide, G-1, at the 5' end of the acceptor stem. In bacteria, archaea, and eukaryotic organelles, G-1 base pairs with C73, while in eukaryotic cytoplasmic tRNAHis, G-1 is opposite A73. Previous studies of Escherichia coli histidyl-tRNA synthetase (HisRS) have demonstrated the importance of the G-1:C73 base pair to tRNAHis identity. Specifically, the 5'-monophosphate of G-1 and the major groove amine of C73 are recognized by E. coli HisRS; these individual atomic groups each contribute approximately 4 kcal/mol to transition state stabilization. In this study, two chemically synthesized 24-nucleotide RNA microhelices, each of which recapitulates the acceptor stem of either E. coli or Saccharomyces cervisiae tRNAHis, were used to facilitate an atomic group "mutagenesis" study of the -1:73 base pair recognition by S. cerevisiae HisRS. Compared with E. coli HisRS, microhelixHis is a much poorer substrate relative to full-length tRNAHis for the yeast enzyme. However, the data presented here suggest that, similar to the E. coli system, the 5' monophosphate of yeast tRNA(His) is critical for aminoacylation by yeast HisRS and contributes approximately 3 kcal/mol to transition state stability. The primary role of the unique -1:73 base pair of yeast tRNAHis appears to be to properly position the critical 5' monophosphate for interaction with the yeast enzyme. Our data also suggest that the eukaryotic HisRS/tRNAHis interaction has coevolved to rely less on specific major groove interactions with base atomic groups than the bacterial system.     

Inhibition of adenylate cyclase by the 2',3'-dialdehyde of adenosine triphosphate

The periodate-oxidized analog of ATP, 2',3'-dialATP, competitively inhibited bovine brain and rat liver adenylate cyclase. The apparent Ki for inhibition of brain adenylate cyclase by 2',3'-dialATP was 196 microM in the presence of Mg2+ and 37 microM in the presence of Mn2+. The Ki values for inhibition of rat liver adenylate cyclase by 2',3'-dialATP were 48 and 30 microM in the presence of Mg2+; and Mn2+, respectively. Adenylate cyclase activity was irreversibly inactivated by 2'3'-dialATP in the presence of NaCNBH3 and the kinetics for loss in enzyme activity were pseudo-first order. Both ATP and Tris protected adenylate cyclase from irreversible inhibition by 2',3'-dialATP and NaCNBH3. It is proposed that 2',3'-dialATP forms a Schiff's base with an amino group at the active site of the enzyme and that Na-CNBH3 reduction of this Schiff's base causes irreversible modification of the catalytic subunit. The Km for 2',3'-dialATP inactivation, the maximal rate constant of inactivation, and protection of the enzyme by ATP were not affected by the presence or absence of free Mg2+. These data indicate that a divalent cation is not required for binding of 2',3'-dialATP to the active site of adenylate cyclase.     

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.