Functional evaluation of serine/threonine residues in the P-Loop of Rhodobacter sphaeroides phosphoribulokinase.

The N-terminal region of phosphoribulokinase (PRK) has been proposed to contain a "P-loop" or "Walker A" motif. In Rhodobacter sphaeroides PRK, four alcohol side chains, contributed by S14, T18, S19, and T20, map within the P loop and represent potential Mg-ATP ligands. Each of these has been individually replaced with an alanine and the impact of these substitutions on enzyme-ATP interactions and overall catalytic efficiency evaluated. Each mutant PRK retains the ability to tightly bind the positive effector, NADH (0.7-0.9 per site), and exhibits allosteric activation, suggesting that the proteins retain a high degree of structural integrity. Similarly, each mutant PRK retains the ability to stoichiometrically (0.7-1.2 per site) bind the alternative substrate trinitrophenyl-ATP. Despite the large size of the PRK oligomer (8 x 32 kDa), (31)P NMR can be used to detect stoichiometrically bound Mg-ATP substrate, which produces markedly broadened peaks in comparison with signals from unbound Mg-ATP. Elimination of alcohol substituents in mutants T18A, S19A, or T20A produces enzymes which retain the ability to form stable PRKMg-ATP complexes. Each mutant complex is characterized by (31)P resonances for alpha- and gamma-phosphoryls of bound Mg-ATP which are narrower than measured for wild-type PRKMg-ATP; signals for the beta-phosphoryl are poorly detectable for mutant PRKMg-ATP complexes. Kinetic characterization indicates that these mutants differ markedly with respect to catalytic activity. T20A exhibits V(m) comparable to wild-type PRK, while V(m) is diminished by 8-fold for T18A and by 40-fold for S14A. In contrast to these modest effects, S19A exhibits decreases in V(m) and V(m)/K(Ru5P) of 500-fold and >15000-fold, respectively. S19A and T18A exhibit only modest (6-7-fold) increases in S(1/2) for ATP but larger (30-45-fold) increases in K(m) for Ru5P. K(I) values for the competitive inhibitor, 6-phosphogluconate, do not significantly change upon mutation of T18 or S19, suggesting that these residues are not crucial to Ru5P binding. A role for the alcohol group of S19, the eighth residue in P-loop motif, as a ligand to the Mg-ATP substrate seems compatible with the characterization data; adjacent alcohols do not efficiently function as surrogates. Such a proposed function for S19 is compatible with its proximity to E131, the acidic residue in a putative Walker B motif and probable second Mg-ATP ligand in PRK's active site.

Identification of the allosteric regulatory site in bacterial phosphoribulokinase.

Bacterial phosphoribulokinases (PRKs) are octameric members of the adenylate kinase family of enzymes. The enzyme is allosterically activated by NADH and allosterically inhibited by AMP. We have determined the crystal structure of PRK from Rhodobacter sphaeroides bound to the ATP analogue AMP-PCP to a resolution of 2.6 A. The structure reveals that the ATP analogue does not bind to the canonical ATP site found in adenylate kinase family members. Rather, the AMP-PCP binds in two different orientations at the interface of three of the monomers in the octamer. This interface was previously characterized as having an unusually large number of arginine residues. Of the five arginine residues that are near the bound nucleotide, one (Arg 221) is highly conserved in both prokaryotic and eukaryotic (nonallosterically regulated) PRKs, two (Arg 234 and Arg 257) are on a second subunit and conserved in only prokaryotic PRKs, and two (Arg 30 and Arg 31) are on a third subunit with only one of them (Arg 31) conserved in prokaryotic PRKs. Each of these arginine residues was converted by site-directed mutagenesis to alanine. Fluorescence binding data suggest that none of these arginines are involved in active site ATP binding and that Arg 234 and Arg 257 on the second subunit are directly involved in NADH binding, while the other arginines have a minimal effect on NADH binding. While the wild-type enzyme exhibits low maximal activity and hyperbolic kinetics with respect to ATP in the absence of NADH and high maximal activity and sigmoidal kinetics in the presence of NADH, the R31A mutant exhibits identical hyperbolic kinetics with respect to ATP in the presence or absence of NADH. Thus, the transmission of allosteric information from one subunit to another is conducted through a single path that includes NADH and Arg 31.

Rhodobacter sphaeroides phosphoribulokinase: identification of lysine-165 as a catalytic residue and evaluation of the contributions of invariant basic amino acids to ribulose 5-phosphate binding.

Rhodobacter sphaeroides phosphoribulokinase (PRK) is inactivated upon exposure to pyridoxal phosphate/sodium borohydride, suggesting a reactive lysine residue. Protection is afforded by a combination of the substrate ATP and the allosteric activator NADH, suggesting that the targeted lysine maps within the active site. PRK contains two invariant lysines, K53 and K165. PRK-K53M retains sensitivity to pyridoxal phosphate, implicating K165 as the target of this reagent. PRK-K165M retains wild-type structure, as judged by titration with effector NADH and the tight-binding alternative substrate trinitrophenyl-ATP. The catalytic activity of K165M and K165C mutants is depressed by >10(3)-fold. Residual activity of K165M is insensitive to pyridoxal phosphate, confirming K165 as the target of this reagent. The decreased catalytic efficiency of K165 mutants approaches the effect measured for a mutant of D169, which forms a salt-bridge to K165. K165M exhibits a 10-fold increase in S()1(/)()2 (ATP) and a 10(2)-fold increase in K(m) (Ru5P). To evaluate the contribution to Ru5P binding of K165 in comparison with this substrate's interaction with invariant H45, R49, R168, and R173, PRKs mutated at these positions have been used to determine relative K(i) values for 6-phosphogluconate, a competitive inhibitor with respect to Ru5P. Elimination of the basic side chain of K165, R49, and H45 results in increases in K(m) (Ru5P) which correlate well with the magnitude of increases in K(i) (phosphogluconate). In contrast, while mutations eliminating charge from R168 and R173 result in enzymes with substantial increases in K(m) (Ru5P), such mutant enzymes exhibit only small increases in K(i) (phosphogluconate). These observations suggest that K165, R49, and H45 are major contributors to Ru5P binding.

The crystal structure of phosphoribulokinase from Rhodobacter sphaeroides reveals a fold similar to that of adenylate kinase.

The essential photosynthetic enzyme phosphoribulokinase (PRK) is responsible for the conversion of ribulose 5-phosphate (Ru5P) to ribulose 1,5-bisphosphate, the substrate for the CO2 fixing enzyme ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco). We have determined the structure of the octameric bacterial form of PRK to a resolution of 2.5 A. The protein is folded into a seven-member mixed beta-sheet surrounded by alpha-helices, giving the overall appearance of the nucleotide monophosphate family of kinases. Homology with the nucleotide monophosphate kinases suggests a number of amino acid residues that are likely to be important in catalysis and suggests the roles of some amino acid residues that have been mutated prior to the determination of the structure. Further, sequence identity across eukaryotic and prokaryotic species and a calculation of the buried surface area suggests the identity within the octamer of a dimer conserved throughout evolution. The width of the groove leading to the active site is consistent with an oriented molecule of thioredoxin controlling the oxidation state of two cysteines that regulate activity in the eukaryotic enzymes. Although neither Asp 42 nor Asp 169 can be definitively assigned as the catalytic base, the crystal structure suggests the location of a ribulose 5-phosphate binding site and suggests a role for several of the conserved basic residues.

Functional evaluation of invariant arginines situated in the mobile lid domain of phosphoribulokinase.

Rhodobacter sphaeroides phosphoribulokinase contains four invariant arginines (R49, R168, R173, and R187). The high-resolution structure of this enzyme [Harrison, D. H. T., Runquist, J. A., Holub, A., and Miziorko, H. M. (1998) Biochemistry (submitted for publication)] reveals that it folds in a manner similar to that of adenylate kinase. Three invariant arginines (R168, R173, and R187) as well as arginine-186, which is conserved in prokaryotic phosphoribulokinases, have not been previously functionally evaluated. These arginine residues map within the mobile lid domain that is a distinctive feature of the adenylate kinase family of proteins. Precedent for the significant function of arginines in phosphotransferase reactions prompted substitution of glutamine for each of these three invariant arginines. Solution state characterization of the isolated mutant proteins indicated that they retained a high degree of structural integrity, as indicated by their stoichiometric binding of an alternative nucleotide substrate (trinitrophenyl-ATP) as well as the allosteric effector (NADH). Kinetic characterization indicated > 10(4)-fold diminution in V/KRu5P for R168Q, attributable to a > 300-fold decrease in catalytic efficiency and an increase (approximately 50-fold) in Km Ru5P. For R173Q, a 15-fold diminution in Vmax and a 100-fold increase in Km Ru5P were observed. These observations implicate new components of the ribulose 5-phosphate binding site. Additionally, they confirm assignment of the mobile lid domain as part of the phosphoribulokinase active site, even though this region is well separated from other active site elements in the structure of the open form of the protein. Characterization of R186Q and R187Q mutants suggests that they influence the cooperativity of substrate binding.

Rhodobacter sphaeroides phosphoribulokinase: binary and ternary complexes with nucleotide substrate analogs and effectors.

Rhodobacter sphaeroides phosphoribulokinase (PRK) binds ATP substrate, as well as spectroscopically active ATP analogs (trinitrophenyl-ATP and ATP gamma S-acetamidoproxyl), to form stable binary complexes. Stoichiometric binding of these nucleotide triphosphates in PRK's substrate site is observed not only with wild-type enzyme but also with D42A and D169A mutants. The demonstration that these mutants contain a full complement of functional substrate binding sites indicates their substantial structural integrity and underscores the significance of their markedly diminished catalytic activity [Charlier et al. (1994) Biochemistry 33, 9343-9350]. Similarly, PRK forms a stable binary complex with the allosteric activator NADH. The negative allosteric effector AMP displaces activator NADH but not substrate from their respective binary complexes with enzyme. When trinitrophenyl-ATP, a fluorescent nucleotide triphosphate that functions as an alternative PRK substrate, forms a binary complex with enzyme, its fluorescence emission is enhanced and lambda max shifted from approximately 557 to 545 nm. Upon formation of a binary PRK-NADH complex, the fluorescence emission of the dinucleotide effector is also enhanced and the lambda max shifted from approximately 460 to 440 nm. PRK forms stable ternary complexes containing NADH and either ATP or trinitrophenyl-ATP. Due to energy transfer, NADH fluorescence in the ternary complex with trinitrophenyl-ATP is markedly quenched, allowing an estimation of the spatial separation between this novel donor/acceptor pair.

Utility of a novel spin-labeled nucleotide in investigation of the substrate and effector sites of phosphoribulokinase.

The activated spin-label 3-(2-bromoacetamido)proxyl modifies the sulfur atom of phosphorothioate-containing AMP, ADP, and ATP analogs in a facile reaction that produces a new series of spin-labeled nucleotides. One of these products, adenosine 5'-O-(S-acetamidoproxyl 3-thiotriphosphate) (ATP gamma SAP), has been evaluated as a structural probe for Rhodobacter sphaeroides phosphoribulokinase (PRK). When incubated with affinity-purified enzyme that contains tightly bound substrate ATP, ATP gamma SAP binds noncooperatively to the allosteric site (n = 1; KD = 8 microM). Probe bound in this site is displaced (K1/2 = 100 microM) by the allosteric effector, NADH, at concentrations comparable to those required for enzyme activation (Ka = 133 microM). In the presence of NADH, when PRK's substrate site is vacant, ATP gamma SAP binds in a cooperative mode (Hill coefficient approximately 2.9; KD = 20 microM). In the absence of NADH, ATP gamma SAP mimics ATP by exhibiting nonequilibrium binding to PRK. The observations with phosphoribulokinase, together with the straightforward nature of the methodology documented for synthesis and isolation of this class of spin-labeled nucleotides, suggest that these analogs have potentially wide application as structural probes.

Crystallization and preliminary X-ray crystallographic analysis of phosphoribulokinase from Rhodobacter sphaeroides.

A recombinant form of Rhodobacter sphaeroides phosphoribulokinase (PRK), expressed in Escherichia coli and isolated by affinity chromatography, was crystallized by the sitting drop vapor diffusion technique using NH4H2PO4 (pH 5.6) as the precipitating agent. PRK crystallizes in the cubic space group P432, with unit cell parameters a = b = c = 129.55 A. Based on the assumption of one 32-kDa monomer per asymmetric unit, the Vm value is 2.83 A3/Da. The octameric molecular symmetry is consistent with two planar tetramers stacked in a nearly eclipsed arrangement. A native data set has been collected to 2.6 A resolution.

Evidence supporting catalytic roles for aspartate residues in phosphoribulokinase.

The DNA encoding Rhodobacter sphaeroides phosphoribulokinase (PRK) has been modified to allow ligation into pET-3d. Using the resulting expression plasmid, PRK was overexpressed in Escherichia coli and isolated in milligram quantities. Homogeneous preparations of the enzyme exhibit properties comparable to those of PRK expressed using a previously described pUC19-derived construct [Sandbaken et al., Biochemistry 31, 3715-3719]. Mutagenesis experiments have been designed to produce conservative substitutions that eliminate the carboxyl groups of each of four conserved acidic residues (D42, E131, D169, and E178). Using the newly developed expression system, the resulting PRK variants have been expressed, isolated, and characterized. Expression levels and recoveries upon affinity chromatography purification are similar to the results obtained with wild-type PRK. Apparent substrate affinities of these mutant proteins do not differ greatly from values observed for wild-type PRK. In contrast, these PRK variants display a wide range of Vmax values, ranging from wild-type activity (approximately 200 units/mg; E178A) to levels that are diminished by 4 (D169A) to 5 (D42A, D42N) orders of magnitude. That the large diminutions in catalytic activity are significant and do not merely reflect gross perturbations in protein structure is suggested not only by the modest effects on substrate affinity but also by the allosteric properties of D169A, D42A, and D42N. The activities of these proteins, like that of wild-type PRK, are markedly stimulated by the positive effector NADH. The magnitude of the Vmax perturbations suggests that D42 and D169 are candidates for the role of active site base or activator cation ligand.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of the phosphoribulokinase sugar phosphate binding domain.

A recombinant form of Rhodobacter sphaeroides phosphoribulokinase (form I; NADH dependent) has been expressed in and purified to homogeneity from Escherichia coli that harbor the prkA gene in the plasmid pKP1565b. Restriction digestion of the phosphoribulokinase-encoding plasmid produces a tractable 450 bp fragment that encodes amino acid residues 28-179, which include a region (residues 42-54) highly conserved among phosphoribulokinase proteins. Using overlap extension polymerase chain reaction methodology, directed mutagenesis was performed to produce mutant proteins in which basic residues in this conserved region were replaced by neutral amino acids. Lysine-53, implicated by affinity labeling studies, has been replaced by methionine; little effect on substrate binding or catalysis is apparent. In contrast, when histidine-45 is replaced by asparagine, a 40-fold increase in the Km for ribulose 5-phosphate results; a 200-fold increase results when arginine-49 is replaced by glutamine. Implication of this region as part of the sugar phosphate binding site is compatible with previous results that indicate targeting by an ATP analogue containing a reactive functionality esterified to the gamma-phosphoryl group. The phosphoribulokinase reaction involves a single in-line phosphoryl transfer, requiring that the gamma-phosphoryl of ATP be closely juxtaposed to the bound cosubstrate. It follows that any reactive group attached to the gamma-phosphoryl in a nucleotide analogue that is bound to PRK in the absence of the cosubstrate will be favorably positioned to modify the sugar phosphate binding site.

The primary structure of the subunits of carbon monoxide dehydrogenase/acetyl-CoA synthase from Clostridium thermoaceticum.

CO dehydrogenase/acetyl-coenzyme A synthase (CODH) is the central enzyme in the pathway of acetyl-coenzyme A biosynthesis in Clostridium thermoaceticum. It catalyzes the interconversion of CO and CO2 and the synthesis of acetyl-coenzyme A from the methylated corrinoid/iron sulfur protein, CO, and coenzyme A. It is a nickel-iron-sulfur protein and contains two subunits in the form (alpha beta)3. Reported here is the cloning and sequencing of the genes for both subunits of CODH. The gene for the alpha subunit codes for a protein with 729 amino acids and a molecular weight of 81,730, and the beta gene for a protein with 674 amino acids and a molecular weight of 72,928. The alpha subunit follows the beta subunit by 23 bases and the genes for both subunits are preceded by a sequence which is similar to the Shine-Dalgarno sequence of Escherichia coli. No significant amino acid sequence homology has been found to any known sequence. Labeling CODH with 2,4-dinitrophenylsulfenyl chloride and isolating labeled peptide fragments demonstrated that a tryptophan, residue 418 of the alpha subunit, is protected by coenzyme A and thus may be considered a potential part of the coenzyme A site.

Cloning and expression of the gene cluster encoding key proteins involved in acetyl-CoA synthesis in Clostridium thermoaceticum: CO dehydrogenase, the corrinoid/Fe-S protein, and methyltransferase.

Acetogenic bacteria fix CO or CO2 by a pathway of autotrophic growth called the acetyl-CoA (or Wood) pathway. Key enzymes in the pathway are a methyltransferase, a corrinoid/Fe-S protein, a disulfide reductase, and a carbon monoxide dehydrogenase. This manuscript describes the isolation of the genes that code for the methyltransferase, the two subunits of the corrinoid/Fe-S protein, and the two subunits of carbon monoxide dehydrogenase. These five genes were found to be clustered within an approximately 10-kilobase segment on the Clostridium thermoaceticum genome. The proteins were expressed at up to 5-10% of Escherichia coli cell protein, and isopropyl beta-D-thiogalactopyranoside had no effect on the levels of expression, implying that the C. thermoaceticum inserts contained transcriptional and translational signals that were recognized by E. coli. The methyltransferase is expressed in E. coli in a fully active dimeric form with a specific activity and heat stability similar to the enzyme expressed in C. thermoaceticum. However, both the corrinoid/Fe-S protein and carbon dioxide dehydrogenase, although expressed in high amounts and with identical subunit molecular weights in E. coli, are inactive and less heat stable than are the native enzymes from C. thermoaceticum.

Catalysis of electron transfer across phospholipid bilayers by iron-porphyrin complexes.

Phospholipid vesicles containing K3Fe(CN)6 were prepared form egg yolk phosphatidylcholine. Hemin dimethyl ester was incorporated into these vesicles during preparation in ratios of phospholipid to hemin dimethyl ester that varied from 200 : 1 to 45 000: 1. Electron transfer across the bilayer was measured anaerobically after injecting the vesicles into a solution containing reduced indigotetrasulfonic acid. Vesicles containing hemin dimethyl ester exhibited high rates of electron transfer (240 electrons/molecule hemin dimethyl ester per min). Conditions could be selected where the rate-limiting step for catalysis was either the biomolecular reaction between ferric hemin dimethyl ester and reduced indigotetrasulfonic acid or the movement of hemin dimethyl ester from interface to interface. The hemin dimethyl ester-catalyzed electron transfer went to completion within a few seconds, completely oxidizing the reduced indigotetrasulfonic acid. Valinomycin (in the presence of potassium) and carbonyl cyanide p-trifluoromethoxyphenylhydrazone were without effect on catalyzed electron transport. Thus, the electron transport is not electrogenic but is a coupled, neutral system. By specific assay, neither phosphate nor cyanide was significantly transported during electron transfer but evidence is provided to suggest that a coordinated hydroxide accompanies movement of Fe(III) hemin dimethyl ester from the inside surface to the outside surface of the bilayer. It was also demonstrated in a bulk phase transport system that hemin dimethyl ester readily catalyzes transfer of S14CN- through a chloroform layer separating two aqueous phases. Another more hydrophobic iron-porphyrin complex, Fe(III) tetraphenylporphyrin, was found to be twice as effective as hemin dimethyl ester. Other porphyrin complexes were also tested as control systems. No significant catalysis was found for metal-free protoporphyrin IX dimethyl ester or Ni(II) tetraphenylporphyrin. The results are discussed in comparison with in vivo electron transport and the future usefulness of this model system.