The trifunctional sulfate-activating complex (SAC) of Mycobacterium tuberculosis

The sulfate activation pathway is essential for the assimilation of sulfate and, in many bacteria, is comprised of three reactions: the synthesis of adenosine 5'-phosphosulfate (APS), the hydrolysis of GTP, and the 3'-phosphorylation of APS to produce 3'-phosphoadenosine 5'-phosphosulfate (PAPS), whose sulfuryl group is reduced or transferred to other metabolites. The entire sulfate activation pathway is organized into a single complex in Mycobacterium tuberculosis. Although present in many bacteria, these tripartite complexes have not been studied in detail. Initial rate characterization of the mycobacterial system reveals that it is poised for extremely efficient throughput: at saturating ATP, PAPS synthesis is 5800 times more efficient than APS synthesis. The APS kinase domain of the complex does not appear to form the covalent E.P intermediate observed in the closely related APS kinase from Escherichia coli. The stoichiometry of GTP hydrolysis and APS synthesis is 1:1, and the APS synthesis reaction is driven 1.1 x 10(6)-fold further during GTP hydrolysis; the system harnesses the full chemical potential of the hydrolysis reaction to the synthesis of APS. A key energy-coupling step in the mechanism is a ligand-induced isomerization that enhances the affinity of GTP and commits APS synthesis and GTP hydrolysis to the completion of the catalytic cycle. Ligand-induced increases in guanine nucleotide affinity observed in the mycobacterial system suggest that it too undergoes the energy-coupling isomerization.     

Rhizobium meliloti NodP and NodQ form a multifunctional sulfate-activating complex requiring GTP for activity.

The nodulation genes nodP and nodQ are required for production of Rhizobium meliloti nodulation (Nod) factors. These sulfated oligosaccharides act as morphogenic signals to alfalfa, the symbiotic host of R. meliloti. In previous work, we have shown that nodP and nodQ encode ATP sulfurylase, which catalyzes the formation of APS (adenosine 5'-phosphosulfate) and PPi. In the subsequent metabolic reaction, APS is converted to PAPS (3'-phosphoadenosine 5'-phosphosulfate) by APS kinase. In Escherichia coli, cysD and cysN encode ATP sulfurylase; cysC encodes APS kinase. Here, we present genetic, enzymatic, and sequence similarity data demonstrating that nodP and nodQ encode both ATP sulfurylase and APS kinase activities and that these enzymes associate into a multifunctional protein complex which we designate the sulfate activation complex. We have previously described the presence of a putative GTP-binding site in the nodQ sequence. The present report also demonstrates that GTP enhances the rate of PAPS synthesis from ATP and sulfate (SO4(2-)) by NodP and NodQ expressed in E. coli. Thus, GTP is implicated as a metabolic requirement for synthesis of the R. meliloti Nod factors.     

Structural and functional analysis of a truncated form of Saccharomyces cerevisiae ATP sulfurylase: C-terminal domain essential for oligomer formation but not for activity

ATP sulfurylase catalyzes the first step in the activation of sulfate by transferring the adenylyl-moiety (AMP approximately ) of ATP to sulfate to form adenosine 5'-phosphosulfate (APS) and pyrophosphate (PP(i)). Subsequently, APS kinase mediates transfer of the gamma-phosphoryl group of ATP to APS to form 3'-phosphoadenosine 5'-phosphosulfate (PAPS) and ADP. The recently determined crystal structure of yeast ATP sulfurylase suggests that its C-terminal domain is structurally quite independent from the other domains, and not essential for catalytic activity. It seems, however, to dictate the oligomerization state of the protein. Here we show that truncation of this domain results in a monomeric enzyme with slightly enhanced catalytic efficiency. Structural alignment of the C-terminal domain indicated that it is extremely similar in its fold to APS kinase although not catalytically competent. While carrying out these structural and functional studies a surface groove was noted. Careful inspection and modeling revealed that the groove is sufficiently deep and wide, as well as properly positioned, to act as a substrate channel between the ATP sulfurylase and APS kinase-like domains of the enzyme.     

Adenosine-5'-phosphosulfate kinase from Escherichia coli K12. Purification, characterization, and identification of a phosphorylated enzyme intermediate

Adenosine-5'-phosphosulfate kinase (ATP:adenylylsulfate 3'-phosphotransferase), the second enzyme in the pathway of sulfate activation, has been purified (approximately 300-fold) to homogeneity from an Escherichia coli K12 strain, which overproduces the enzyme activity (approximately 100-fold). The purified enzyme has a specific activity of 153 mumol of 3'-phosphoadenosine 5'-phosphosulfate (PAPS) formed/min/mg of protein at 25 degrees C. The enzyme is remarkably efficient with a Vmax/Km(APS) of greater than 10(8) M-1 s-1, indicating that at physiologically low substrate concentrations the reaction is essentially diffusion limited. Upon incubation with MgATP a phosphorylated enzyme is formed; the isolated phosphorylated enzyme can transfer its phosphoryl group to adenosine 5'-phosphosulfate (APS) to form PAPS or to ADP to form ATP. The phosphorylated enzyme exists as a dimer of identical 21-kilodalton subunits, while the dephosphorylated form primarily exists as a tetramer. Divalent cations are required for activity with Mg(II), Mn(II), Co(II), and Cd(II) activating. Studies of the divalent metal-dependent stereoselectivity for the alpha- and beta-phosphorothioate derivatives of ATP indicate metal coordination to at least the alpha-phosphoryl group of the nucleotide. Steady state kinetic studies of the reverse reaction indicate a sequential mechanism, with a rapid equilibrium ordered binding of MgADP before PAPS. In the forward direction APS is a potent substrate inhibitor, competitive with ATP, complicating kinetic studies. The primary kinetic mechanism in the forward direction is sequential. Product inhibition studies at high concentrations of APS suggest an ordered kinetic mechanism with MgATP binding before APS. At submicromolar concentrations of APS, product inhibition by both MgADP and PAPS is more complex and is not consistent with a solely ordered sequential mechanism. The formation of a phosphorylated enzyme capable of transferring its phosphoryl group to APS or to MgADP suggests that a ping-pong pathway in which the rate of MgADP dissociation is comparable to the rate of APS binding might contribute at very low concentrations of APS. The substrate inhibition by APS is consistent with APS binding to the enzyme, to form a dead-end E.APS complex.     

Kinetic and stability properties of Penicillium chrysogenum ATP sulfurylase missing the C-terminal regulatory domain

ATP sulfurylase from Penicillium chrysogenum is a homohexameric enzyme that is subject to allosteric inhibition by 3'-phosphoadenosine 5'-phosphosulfate. In contrast to the wild type enzyme, recombinant ATP sulfurylase lacking the C-terminal allosteric domain was monomeric and noncooperative. All kcat values were decreased (the adenosine 5'-phosphosulfate (adenylylsulfate) (APS) synthesis reaction to 17% of the wild type value). Additionally, the Michaelis constants for MgATP and sulfate (or molybdate), the dissociation constant of E.APS, and the monovalent oxyanion dissociation constants of dead end E.MgATP.oxyanion complexes were all increased. APS release (the k6 step) was rate-limiting in the wild type enzyme. Without the C-terminal domain, the composite k5 step (isomerization of the central complex and MgPPi release) became rate-limiting. The cumulative results indicate that besides (a) serving as a receptor for the allosteric inhibitor, the C-terminal domain (b) stabilizes the hexameric structure and indirectly, individual subunits. Additionally, (c) the domain interacts with and perfects the catalytic site such that one or more steps following the formation of the binary E.MgATP and E.SO4(2-) complexes and preceding the release of MgPPi are optimized. The more negative entropy of activation of the truncated enzyme for APS synthesis is consistent with a role of the C-terminal domain in promoting the effective orientation of MgATP and sulfate at the active site.     

Sulfate-activating enzymes of Penicillium chrysogenum. The ATP sulfurylase.adenosine 5'-phosphosulfate complex does not serve as a substrate for adenosine 5'-phosphosulfate kinase

At a noninhibitory steady state concentration of adenosine 5'-phosphosulfate (APS), increasing the concentration of Penicillium chrysogenum ATP sulfurylase drives the rate of the APS kinase-catalyzed reaction toward zero. The result indicates that the ATP sulfurylase.APS complex does not serve as a substrate for APS kinase, i.e. there is no "substrate channeling" of APS between the two sulfate-activating enzymes. APS kinase had no effect on the [S]0.5 values, nH values, or maximum isotope trapping in the single turnover of ATP sulfurylase-bound [35S]APS. Equimolar APS kinase (+/- MgATP or APS) also had no effect on the rate constants for the inactivation of ATP sulfurylase by phenylglyoxal, diethylpyrocarbonate, or N-ethylmaleimide. Similarly, ATP sulfurylase (+/- ligands) had no effect on the inactivation of equimolar APS kinase by trinitrobenzene sulfonate, diethylpyrocarbonate, or heat. (The last promotes the dissociation of dimeric APS kinase to inactive monomers.) ATP sulfurylase also had no effect on the reassociation of APS kinase subunits at low temperature. The cumulative results suggest that the two sulfate activating enzymes do not associate to form a "3'-phosphoadenosine 5'-phosphosulfate synthetase" complex.     

The complex structures of ATP sulfurylase with thiosulfate, ADP and chlorate reveal new insights in inhibitory effects and the catalytic cycle.

The ubiquitous enzyme ATP sulfurylase (ATPS) catalyzes the primary step of intracellular sulfate activation, the formation of adenosine 5'-phosphosulfate (APS). It has been shown that the enzyme catalyzes the generation of APS from ATP and inorganic sulfate in vitro and in vivo, and that this reaction can be inhibited by a number of simple molecules. Here, we present the crystal structures of ATPS from the yeast Saccharomyces cerevisiae complexed with compounds that have inhibitory effects on the catalytic reaction of ATPS. Thiosulfate and ADP mimic the substrates sulfate and ATP in the active site, but are non-reactive and thus competitive inhibitors of the sulfurylase reaction. Chlorate is bound in a crevice between the active site and the intermediate domain III of the complex structure. It forms hydrogen bonds to residues of both domains and stabilizes a "closed" conformation, inhibiting the release of the reaction products APS and PPi. These new observations are evidence for the crucial role of the displacement mechanism for the catalysis by ATPS.     

Crystal structure of ATP sulfurylase from Saccharomyces cerevisiae, a key enzyme in sulfate activation

ATP sulfurylases (ATPSs) are ubiquitous enzymes that catalyse the primary step of intracellular sulfate activation: the reaction of inorganic sulfate with ATP to form adenosine-5'-phosphosulfate (APS) and pyrophosphate (PPi). With the crystal structure of ATPS from the yeast Saccharomyces cerevisiae, we have solved the first structure of a member of the ATP sulfurylase family. We have analysed the crystal structure of the native enzyme at 1.95 Angstroms resolution using multiple isomorphous replacement (MIR) and, subsequently, the ternary enzyme product complex with APS and PPi bound to the active site. The enzyme consists of six identical subunits arranged in two stacked rings in a D:3 symmetric assembly. Nucleotide binding causes significant conformational changes, which lead to a rigid body structural displacement of domains III and IV of the ATPS monomer. Despite having similar folds and active site design, examination of the active site of ATPS and comparison with known structures of related nucleotidylyl transferases reveal a novel ATP binding mode that is peculiar to ATP sulfurylases.     

Mechanistic studies of Escherichia coli adenosine-5'-phosphosulfate kinase

Adenosine-5'-phosphosulfate kinase (APS kinase) catalyzes the formation of 3'-phosphoadenosine 5'-phosphosulfate (PAPS), the major form of activated sulfate in biological systems. The enzyme from Escherichia coli has complex kinetic behavior, including substrate inhibition by APS and formation of a phosphorylated enzyme (E-P) as a reaction intermediate. The presence of a phosphorylated enzyme potentially enables the steady-state kinetic mechanism to change from sequential to ping-pong as the APS concentration decreases. Kinetic and equilibrium binding measurements have been used to evaluate the proposed mechanism. Equilibrium binding studies show that APS, PAPS, ADP, and the ATP analog AMPPNP each bind at a single site per subunit; thus, substrates can bind in either order. When ATPgammaS replaces ATP as substrate the V(max) is reduced 535-fold, the kinetic mechanism is sequential at each APS concentration, and substrate inhibition is not observed. The results indicate that substrate inhibition arises from a kinetic phenomenon in which product formation from ATP binding to the E. APS complex is much slower than paths in which product formation results from APS binding either to the E. ATP complex or to E-P. APS kinase requires divalent cations such as Mg(2+) or Mn(2+) for activity. APS kinase binds one Mn(2+) ion per subunit in the absence of substrates, consistent with the requirement for a divalent cation in the phosphorylation of APS by E-P. The affinity for Mn(2+) increases 23-fold when the enzyme is phosphorylated. Two Mn(2+) ions bind per subunit when both APS and the ATP analog AMPPNP are present, indicating a potential dual metal ion catalytic mechanism.     

Nucleotide Binding Site Communication in Arabidopsis thaliana Adenosine 5'-Phosphosulfate Kinase

Adenosine 5'-phosphosulfate kinase (APSK) catalyzes the ATP-dependent synthesis of adenosine 3'-phosphate 5'-phosphosulfate (PAPS), which is an essential metabolite for sulfur assimilation in prokaryotes and eukaryotes. Using APSK from Arabidopsis thaliana, we examine the energetics of nucleotide binary and ternary complex formation and probe active site features that coordinate the order of ligand addition. Calorimetric analysis shows that binding can occur first at either nucleotide site, but that initial interaction at the ATP/ADP site was favored and enhanced affinity for APS in the second site by 50-fold. The thermodynamics of the two possible binding models (i.e. ATP first versus APS first) differs and implies that active site structural changes guide the order of nucleotide addition. The ligand binding analysis also supports an earlier suggestion of intermolecular interactions in the dimeric APSK structure. Crystallographic, site-directed mutagenesis, and energetic analyses of oxyanion recognition by the P-loop in the ATP/ADP binding site and the role of Asp(136), which bridges the ATP/ADP and APS/PAPS binding sites, suggest how the ordered nucleotide binding sequence and structural changes are dynamically coordinated for catalysis.     

GTPase-mediated activation of ATP sulfurylase.

GTP stimulates the synthesis of APS (adenosine 5'-phosphosulfate) by the enzyme ATP sulfurylase (ATP:sulfate adenylyltransferase, EC 2.7.7.4) via a GTPase mechanism. The activation of the enzyme, purified from Escherichia coli, is titratable with GTP. The initial rate of APS formation is increased 116-fold at a saturating concentration of GTP. The enzyme exhibits a GTPase activity that is stimulated by ATP and further enhanced by SO4; however, SO4 alone does not significantly stimulate GTP hydrolysis. The larger subunit of ATP sulfurylase, encoded by cysN, contains a GTP-binding consensus sequence common to other known GTP-binding proteins. This is the first evidence that the sulfate activation pathway is a metabolic target for regulation by a GTPase.     

Crystal structure of the bifunctional ATP sulfurylase-APS kinase from the chemolithotrophic thermophile Aquifex aeolicus

The thermophilic chemolithotroph, Aquifex aeolicus, expresses a gene product that exhibits both ATP sulfurylase and adenosine-5'-phosphosulfate (APS) kinase activities. These enzymes are usually segregated on two separate proteins in most bacteria, fungi, and plants. The domain arrangement in the Aquifex enzyme is reminiscent of the fungal ATP sulfurylase, which contains a C-terminal domain that is homologous to APS kinase yet displays no kinase activity. Rather, in the fungal enzyme, the motif serves as a sulfurylase regulatory domain that binds the allosteric effector 3'-phosphoadenosine-5'-phosphosulfate (PAPS), the product of true APS kinase. Therefore, the Aquifex enzyme may represent an ancestral homolog of a primitive bifunctional enzyme, from which the fungal ATP sulfurylase may have evolved. In heterotrophic sulfur-assimilating organisms such as fungi, ATP sulfurylase catalyzes the first committed step in sulfate assimilation to produce APS, which is subsequently metabolized to generate all sulfur-containing biomolecules. In contrast, ATP sulfurylase in sulfur chemolithotrophs catalyzes the reverse reaction to produce ATP and sulfate from APS and pyrophosphate. Here, the 2.3 A resolution X-ray crystal structure of Aquifex ATP sulfurylase-APS kinase bifunctional enzyme is presented. The protein dimerizes through its APS kinase domain and contains ADP bound in all four active sites. Comparison of the Aquifex ATP sulfurylase active site with those from sulfate assimilators reveals similar dispositions of the bound nucleotide and nearby residues. This suggests that minor perturbations are responsible for optimizing the kinetic properties for the physiologically relevant direction. The APS kinase active-site lid adopts two distinct conformations, where one conformation is distorted by crystal contacts. Additionally, a disulfide bond is observed in one ATP-binding P-loop of the APS kinase active site. This linkage accounts for the low kinase activity of the enzyme under oxidizing conditions. The thermal stability of the Aquifex enzyme can be explained by the 43% decreased cavity volume found within the protein core.     

The role of enzyme isomerization in the native catalytic cycle of the ATP sulfurylase-GTPase system

ATP sulfurylase, from E. coli Kappa-12, is a GTPase.target complex that conformationally couples the free energies of GTP hydrolysis and activated sulfate (adenosine 5'-phosphosulfate, or APS) synthesis. Energy coupling is achieved by an allosterically driven isomerization that switches on and off chemistry at specific points in the catalytic cycle. This coupling mechanism is derived from the results of model studies using analogue complexes that mimic different stages of the native catalytic cycle. The current investigation extends the analogue studies to the native catalytic cycle. Isomerization is monitored using the fluorescent, guanine nucleotide analogues mGMPPNP (3'-O-(N-methylanthraniloyl)-2'-deoxyguanosine 5'-[beta, gamma-imido]triphosphate) and mGTP [3'-O-(N-methylanthraniloyl)-2'-deoxyguanosine 5'-triphosphate]. The isomerization is shown to be initiated by an allosteric interaction that requires the simultaneous occupancy of all three substrate-binding sites. Stopped-flow fluorescence and single-turnover studies were used to define and quantitate the isomerization mechanism, and to show that the isomerization precedes and rate-limits both GTP hydrolysis and APS synthesis. These findings are incorporated into a model of the energy-coupling mechanism.     

5'-adenosinephosphosulfate lies at a metabolic branch point in mycobacteria

Bacterial sulfate assimilation pathways provide for activation of inorganic sulfur for the biosynthesis of cysteine and methionine, through either adenosine 5'-phosphosulfate (APS) or 3'-phosphoadenosine 5'-phosphosulfate (PAPS) as intermediates. PAPS is also the substrate for sulfotransferases that produce sulfolipids, putative virulence factors, in Mycobacterium tuberculosis such as SL-1. In this report, genetic complementation using Escherichia coli mutant strains deficient in APS kinase and PAPS reductase was used to define the M. tuberculosis and Mycobacterium smegmatis CysH enzymes as APS reductases. Consequently, the sulfate assimilation pathway of M. tuberculosis proceeds from sulfate through APS, which is acted on by APS reductase in the first committed step toward cysteine and methionine. Thus, M. tuberculosis most likely produces PAPS for the sole use of this organism's sulfotransferases. Deletion of CysH from M. smegmatis afforded a cysteine and methionine auxotroph consistent with a metabolic branch point centered on APS. In addition, we have redefined the substrate specificity of the B. subtilis CysH, formerly designated a PAPS reductase, as an APS reductase, based on its ability to complement a mutant E. coli strain deficient in APS kinase. Together, these studies show that two conserved sequence motifs, CCXXRKXXPL and SXGCXXCT, found in the C termini of all APS reductases, but not in PAPS reductases, may be used to predict the substrate specificity of these enzymes. A functional domain of the M. tuberculosis CysC protein was cloned and expressed in E. coli, confirming the ability of this organism to make PAPS. The expression of recombinant M. tuberculosis APS kinase provides a means for the discovery of inhibitors of this enzyme and thus of the biosynthesis of SL-1.     

Nuclear localization of PAPS synthetase 1: a sulfate activation pathway in the nucleus of eukaryotic cells.

Sulfation is a major modification of many molecules in eukaryotes that is dependent on the enzymatic synthesis of an activated sulfate donor, 3'-phosphoadenosine 5'-phosphosulfate (PAPS). While sulfate activation has long been assumed to occur in the cytosol, we show in this study that human PAPS synthetase 1 (PAPSS1), a bifunctional ATP sulfurylase/adenosine 5'-phosphosulfate (APS) kinase enzyme sufficient for PAPS synthesis, accumulates in the nucleus of mammalian cells. Nuclear targeting of the enzyme is mediated by its APS kinase domain and requires a catalytically dispensable 21 amino acid sequence at the amino terminus. Human PAPSS1 and Drosophila melanogaster PAPSS localize to the nucleus in yeast and relieve the methionine auxotrophy of ATP sulfurylase- or APS kinase-deficient strains, suggesting that PAPSS1 is fully functional in vivo when targeted to the nucleus. A second PAPS synthetase gene, designated PAPSS2, has recently been described, mutations of which are responsible for abnormal skeletal development in human spondyloepimetaphyseal dysplasia and murine brachymorphism. We found that PAPSS2, which localizes to the cytoplasm when ectopically expressed in mammalian cells, is relocated to the nucleus when coexpressed with PAPSS1. Taken together, these results indicate that a sulfation pathway might exist in the nucleus of eukaryotic cells. -Besset, S., Vincourt, J.-B., Amalric, F., Girard, J.-P. Nuclear localization of PAPS synthetase 1: a sulfate activation pathway in the nucleus of eukaryotic cells.     

Adenosine-5′-phosphosulfate kinase from Thermobifida fusca

Sulfur, as a macronutrient, is essential for all kinds of organisms. Sulfate, the primary available source of sulfur, is firstly activated by adenylation catalyzed by ATP sulfurylase (ATPS) to form adenosine 5′-phosphosulfate (APS), which will be further phosphorylated into 3′-phosphoadenosine 5′-phosphosulfate (PAPS) by APS kinase (APSK). In some organisms, sulfate activating related enzymes are assembled to form sulfate-activating complex (SAC) to facilitate APS synthesis, the thermodynamically unfavorable reaction. In genome of a moderate thermophilic bacterium, Thermobifida fusca, there are presumably GTPasecoupled ATPS and one putative bifunctional ATPS/APSK type SAC. In this study, this putative SAC of T. fusca was prokaryotically expressed, purified and characterized. Activity assays showed that it contained APSK activity, while lacked ATPS activity. SAC of T. fusca was further used as a coupling enzyme to assay APS formation catalyzed by yeast ATPS. Based on the sequence alignment and modeled structure, we infer that the divergences of two conserved motifs and the missing of a loop and a helix-turn-helix motifs may contribute to the deficiency of ATPS activity.     

Rhizobium Meliloti Genes Involved in Sulfate Activation: The Two Copies of Nodpq and a New Locus, Saa

The nitrogen-fixing symbiont Rhizobium meliloti establishes nodules on leguminous host plants. Nodulation (nod) genes used for this process are located in a cluster on the pSym-a megaplasmid of R. meliloti. These genes include nodP and nodQ (here termed nodPQ), which encode ATP sulfurylase and APS kinase, enzymes that catalyze the conversion of ATP and SO(4)2- into the activated sulfate form 3'-phosphoadenosine 5'-phosphosulfate (PAPS), an intermediate in cysteine synthesis. In Rhizobium, PAPS is also a precursor for sulfated and N-acylated oligosaccharide Nod-factor signals that cause symbiotic responses on specific host plants such as alfalfa. We previously found a highly conserved second copy of nodPQ in R. meliloti. We report here the mapping and cloning of this second copy, and its location on the second megaplasmid, pSym-b. The function of nodP2Q2 is equivalent to that of nodP1Q1 in complementation tests of R. meliloti and Escherichia coli mutants in ATP sulfurylase and adenosine 5'-phosphosulfate (APS) kinase. Mutations in nodP2Q2 do not have as severe an effect on symbiosis or plant host range as do those in nodP1Q1, however, possibly reflecting differences in expression and/or channeling of metabolites to specific enzymes involved in sulfate transfer. Strains mutated or deleted for both copies of nodQ are severely defective in symbiotic phenotypes, but remain prototrophic. This suggests the existence in R. meliloti of a third locus for ATP sulfurylase and APS kinase activities. We have found a new locus saa (sulfur amino acid), which may also encode these activities.     

ATP sulfurylase from the hyperthermophilic chemolithotroph Aquifex aeolicus

ATP sulfurylase from the hyperthermophilic chemolithotroph Aquifex aeolicus is a bacterial ortholog of the enzyme from filamentous fungi. (The subunit contains an adenosine 5'-phosphosulfate (APS) kinase-like, C-terminal domain.) The enzyme is highly heat stable with a half-life >1h at 90 degrees C. Steady-state kinetics are consistent with a random A-B, ordered P-Q mechanism where A=MgATP, B=SO4(2-), P=PP(i), and Q=APS. The kinetic constants suggest that the enzyme is optimized to act in the direction of ATP+sulfate formation. Chlorate is competitive with sulfate and with APS. In sulfur chemolithotrophs, ATP sulfurylase provides an efficient route for recycling PP(i) produced by biosynthetic reactions. However, the protein possesses low APS kinase activity. Consequently, it may also function to produce PAPS for sulfate ester formation or sulfate assimilation when hydrogen serves as the energy source and a reduced inorganic sulfur source is unavailable.     

The sulfate activation locus of Escherichia coli K12: cloning, genetic, and enzymatic characterization

The sulfate activation locus of Escherichia coli K12 has been cloned by complementation. The genes and gene products of this locus have been characterized by correlating the enzyme activity, complementation patterns, and polypeptides associated with subclones of the cloned DNA. The enzymes of the sulfate activation pathway, ATP sulfurylase (ATP:sulfate adenylyltransferase, EC 2.7.7.4) and APS kinase (ATP:adenosine-5'-phosphosulfate 3'-phosphotransferase, EC 2.7.1.25) have been overproduced approximately 100-fold. Overproduction of ATP sulfurylase requires the expression of both the cysD gene, encoding a 27-kDa polypeptide, and a previously unidentified gene, denoted cysN, which encodes a 62-kDa polypeptide. Purification of ATP sulfurylase to homogeneity reveals that the enzyme is composed of two types of subunits which are encoded by cysD and cysN. Insertion of a kanamycin resistance gene into plasmid or chromosomal cysN prevents sulfate activation and decreases expression of the downstream cysC gene. cysC appears to be the APS kinase structural gene and encodes a 21-kDa polypeptide. The genes are adjacent and are transcribed counterclockwise on the E. coli chromosome in the order cysDNC. cysN and cysC are within the same operon and cysDNC are not in an operon containing cysHIJ.     

Human 3'-phosphoadenosine 5'-phosphosulfate synthetase (isoform 1, brain): kinetic properties of the adenosine triphosphate sulfurylase and adenosine 5'-phosphosulfate kinase domains

Recombinant human 3'-phosphoadenosine 5'-phosphosulfate (PAPS) synthetase, isoform 1 (brain), was purified to near-homogeneity from an Escherichia coli expression system and kinetically characterized. The native enzyme, a dimer with each 71 kDa subunit containing an adenosine triphosphate (ATP) sulfurylase and an adenosine 5'-phosphosulfate (APS) kinase domain, catalyzes the overall formation of PAPS from ATP and inorganic sulfate. The protein is active as isolated, but activity is enhanced by treatment with dithiothreitol. APS kinase activity displayed the characteristic substrate inhibition by APS (K(I) of 47.9 microM at saturating MgATP). The maximum attainable activity of 0.12 micromol min(-1) (mg of protein)(-1) was observed at an APS concentration ([APS](opt)) of 15 microM. The theoretical K(m) for APS (at saturating MgATP) and the K(m) for MgATP (at [APS](opt)) were 4.2 microM and 0.14 mM, respectively. At likely cellular levels of MgATP (2.5 mM) and sulfate (0.4 mM), the overall endogenous rate of PAPS formation under optimum assay conditions was 0.09 micromol min(-1) (mg of protein)(-1). Upon addition of pure Penicillium chrysogenum APS kinase in excess, the overall rate increased to 0.47 micromol min(-1) (mg of protein)(-1). The kinetic constants of the ATP sulfurylase domain were as follows: V(max,f) = 0.77 micromol min(-1) (mg of protein)(-1), K(mA(MgATP)) = 0.15 mM, K(ia(MgATP)) = 1 mM, K(mB(sulfate)) = 0.16 mM, V(max,r) = 18.7 micromol min(-1) (mg of protein)(-1), K(mQ(APS)) = 4.8 microM, K(iq(APS)) = 18 nM, and K(mP(PPi)) = 34.6 microM. The (a) imbalance between ATP sulfurylase and APS kinase activities, (b) accumulation of APS in solution during the overall reaction, (c) rate acceleration provided by exogenous APS kinase, and (d) availability of both active sites to exogenous APS all argue against APS channeling. Molybdate, selenate, chromate ("chromium VI"), arsenate, tungstate, chlorate, and perchlorate bind to the ATP sulfurylase domain, with the first five serving as alternative substrates that promote the decomposition of ATP to AMP and PP(i). Selenate, chromate, and arsenate produce transient APX intermediates that are sufficiently long-lived to be captured and 3'-phosphorylated by APS kinase. (The putative PAPX products decompose to adenosine 3',5'-diphosphate and the original oxyanion.) Chlorate and perchlorate form dead-end E.MgATP.oxyanion complexes. Phenylalanine, reported to be an inhibitor of brain ATP sulfurylase, was without effect on PAPS synthetase isoform 1.