Isomerization couples chemistry in the ATP sulfurylase-GTPase system.

ATP sulfurylase catalyzes and couples the free energies of two reactions: GTP hydrolysis and the synthesis of activated sulfate, or APS. The GTPase active site undergoes changes during its catalytic cycle that are driven by events that occur at the APS-forming active site, which is located in a separate subunit. GTP responds to its changing environment by moving along its reaction path. The response, which may change the affinity or reactivity of GTP, can, in turn, produce alterations at the APS active site that drive APS synthesis. The resulting stepwise progression of the two reactions couples their free energies. The mechanism of ATP sulfurylase involves an enzyme isomerization that precedes and rate limits cleavage of the beta,gamma-bond of GTP. These fluorescence studies demonstrate that the isomerization is controlled by the binding of activators that drive ATP sulfurylase into forms that mimic different stages of the APS reaction. Only certain activators elicit the isomerization, suggesting that the APS reaction must proceed to a specific point in the catalytic cycle before the conformational "switch" that controls GTP hydrolysis is thrown. The isomerization is shown to require occupancy of the gamma-phosphate subsite of the GTP binding pocket. This requirement establishes that the isomerization results in a change in the interaction between the enzyme and the gamma-phosphate of GTP that emerges in the catalytic cycle during the transition from the nonisomerized to the isomerized E.GTP complex. The newly formed contact(s) appears to carry into the bond-breaking transition state, and to be essential for the enhanced affinity and reactivity of the nucleotide.     

Allosteric and catalytic functions of the PPi-binding motif in the ATP sulfurylase-GTPase system

ATP sulfurylase, from Escherichia coli K-12, catalyzes and couples the Gibbs potentials of two reactions, GTP hydrolysis and activated sulfate (APS, adenosine 5'-phosphosulfate) synthesis. Coupling these potentials requires that the catalytic cycle include reaction stage-dependent conformational changes that gate the activities of the two active sites. These interactions were probed in a mutagenesis study of a highly conserved pyrophosphate-binding motif (SXGXDS), which is located at the APS-forming active site. The motif appears to be unique to the N-type PPi synthetase family, and mutations in it are linked, in other systems, to citrullinemia, an often fatal orphan disease. The conserved sites in the motif were evaluated individually for their ability to activate GTP hydrolysis (which reports interactions among the activator (AMP or Mg2+.PPi), the enzyme, and GTP), to affect the energetic coupling of the two reactions, and to alter the kinetic constants of the adenylyl transfer reaction in the absence of guanine nucleotide. What emerges from this first mutagenic exploration of the PPi motif in any adenylyltransferase is that the residues of the motif participate differently, and in sometimes profoundly important ways, in the different functions of the enzyme.     

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.     

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 ATP sulfurylase from the bacterial symbiont of the hydrothermal vent tubeworm Riftia pachyptila.

In sulfur chemolithotrophic bacteria, the enzyme ATP sulfurylase functions to produce ATP and inorganic sulfate from APS and inorganic pyrophosphate, which is the final step in the biological oxidation of hydrogen sulfide to sulfate. The giant tubeworm, Riftia pachyptila, which lives near hydrothermal vents on the ocean floor, harbors a sulfur chemolithotroph as an endosymbiont in its trophosome tissue. This yet-to-be-named bacterium was found to contain high levels of ATP sulfurylase that may provide a substantial fraction of the organisms ATP. We present here, the crystal structure of ATP sulfurylase from this bacterium at 1.7 A resolution. As predicted from sequence homology, the enzyme folds into distinct N-terminal and catalytic domains, but lacks the APS kinase-like C-terminal domain that is present in fungal ATP sulfurylase. The enzyme crystallizes as a dimer with one subunit in the crystallographic asymmetric unit. Many buried solvent molecules mediate subunit contacts at the interface. Despite the high concentration of sulfate needed for crystallization, no ordered sulfate was observed in the sulfate-binding pocket. The structure reveals a mobile loop positioned over the active site. This loop is in a "closed" or "down" position in the reported crystal structures of fungal ATP sulfurylases, which contained bound substrates, but it is in an "open" or "up" position in the ligand-free Riftia symbiont enzyme. Thus, closure of the loop correlates with occupancy of the active site, although the loop itself does not interact directly with bound ligands. Rather, it appears to assist in the orientation of residues that do interact with active-site ligands. Amino acid differences between the mobile loops of the enzymes from sulfate assimilators and sulfur chemolithotrophs may account for the significant kinetic differences between the two classes of ATP sulfurylase.     

Catalytic and regulatory site composition of yeast AMP deaminase by comparative binding and rate studies. Resolution of the cooperative mechanism

Yeast AMP deaminase is allosterically activated by ATP and MgATP and inhibited by GTP and PO4. The tetrameric enzyme binds 2 mol each of ATP, GTP, and PO4/subunit with Kd values of 8.4 +/- 4.0, 4.1 +/- 0.6, and 169 +/- 12 microM, respectively. At 0.7 M KCl, ATP binds to the enzyme, but no longer activates. Titration with coformycin 5'-monophosphate, a slow, tight-binding inhibitor, indicates a single catalytic site/subunit. ATP and GTP bind at regulatory sites distinct from the catalytic site and their binding is mutually exclusive. Inorganic phosphate competes poorly with ATP for the ATP sites (Kd = 20.1 +/- 4.1 mM). However, near-saturating ATP reduces the moles of phosphate bound per subunit to 1 PO4, which binds with a Kd = 275 +/- 22 microM. In the presence of ATP, PO4 cannot effectively compete with ATP for the nucleotide triphosphate sites. The PO4 which binds in the presence of ATP is competitive with AMP at the catalytic site since the Kd equals the kinetic inhibition constant for PO4. Initial reaction rate curves are a cooperative function of AMP concentration and activation by ATP is also cooperative. However, no cooperativity is observed in the binding of any of the regulator ligands and ATP binding and kinetic activation by ATP is independent of substrate analog concentration. Cooperativity in initial rate curves results, therefore, from altered rate constants for product formation from each (enzyme.substrate)n species and not from cooperative substrate binding. The traditional cooperative binding models of allosteric regulation do not apply to yeast AMP deaminase, which regulates catalytic activity by kinetic control of product formation. The data are used to estimate the rates of AMP hydrolysis under reported metabolite concentrations in yeast.     

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.     

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 physiology of stringent factor (ATP:GTP 3'-diphosphotransferase) in Escherichia coli

The enzyme ATP:GTP 3'-diphosphotransferase catalyzes the transfer of the beta, gamma-pyrophosphate of ATP to the 3' position of GTP or GDP. The amounts of enzyme were measured in cell extracts of a relA+ strain of E. coli grown at different growth rates between 0.4 and 1.9 generations per hour, using precipitation with specific antibodies to purify the enzyme. The amount of enzyme was found to be a constant fraction of total protein at all growth rates corresponding to about 45 molecules of enzyme per genome equivalent of DNA. The purified enzyme has little catalytic activity by itself but has to be activated either by a complex of 70S ribosomes, mRNA and uncharged tRNA or by a solvent like ethanol at a concentration of about 20%. The kinetic constants of the enzyme for the transfer pyrophosphate from ATP to GTP in the ribosome-activated state were determined. The Vmax was estimated to be 140 mumol/min X mg at 37 degrees C and the S0.5 values for GTP and ATP were 0.35 and 0.53 mM, respectively. The reaction was estimated to have an equilibrium constant of about 300. In the pyrophosphate transfer from ATP to GDP the Vmax was estimated to be 90 mumol/min X mg at 37 degrees C and the S0.5 for GDP as 0.3 mM. During amino acid starvation of a relA+ strain of E. coli the amounts of enzyme and the catalytic capacity of the enzyme are sufficient to maintain the observed ppGpp levels in the cells at all growth rates.     

Cysteine biosynthetic enzymes are the pieces of a metabolic energy pump

Understanding the mechanisms of free energy transfer in metabolism is fundamental to understanding how the chemical forces that sustain the molecular organization of the cell are distributed. Recent studies of molecular motors (1-3) and ATP-driven proton transport (4-6) describe how chemical potential is transferred at the molecular level. These systems catalyze energy transfer through structural change and appear to be dedicated exclusively to their coupling tasks (7, 8). Here we report the discovery of a new class of energy-transfer system. It is a biosynthetic pump composed of cysteine biosynthesis enzymes, ATP sulfurylase and O-acetylserine sulfhydrylase, each with its own catalytic function and from whose interactions emerge new function: the hydrolysis of ATP. The hydrolysis is kinetically and energetically linked to the chemistry catalyzed by ATP sulfurylase, the first enzyme in the cysteine biosynthetic pathway, in such a way that each molecule of ATP hydrolyzed, each stroke of the pump, produces 1 equivalent of that enzyme's product. These findings integrate cysteine metabolism and broaden our understanding of the ways in which higher order allostery is used to effect free energy transfer.     

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.     

ATP sulfurylase from Penicillium chrysogenum: measurements of the true specific activity of an enzyme subject to potent product inhibition and a reassessment of the kinetic mechanism

Homogeneous ATP sulfurylase from Penicillium chrysogenum has been reported to have an extremely low activity toward its physiological inorganic substrate, sulfate. This low activity is an artifact resulting from potent product inhibition by 5'-adenylylsulfate (APS) (Ki less than 0.25 microM). Assays based on 35S incorporation from 35SO4(2-) into charcoal-adsorbable [35S]APS are nonlinear with time, even in the presence of a large excess of inorganic pyrophosphatase. However, in the presence of excess APS kinase (along with excess pyrophosphatase), the ATP sulfurylase reaction is linear with time and the enzyme has a specific activity (Vmax) of 6 to 7 units mg protein-1 corresponding to an active site turnover number of at least 400 min-1. Monovalent oxyanions such as NO3-, ClO3-, ClO4-, and FSO3- are competitive with sulfate (or molybdate) and essentially uncompetitive with respect to MgATP. However, thiosulfate (SSO3(2-)), a true sulfate analog and dead-end inhibitor of the enzyme (competitive with sulfate or molybdate), exhibited clear noncompetitive inhibition against MgATP. Furthermore, APS was competitive with both MgATP and molybdate in the molybdolysis assay. These results suggest (a) that the mechanism of the normal forward reaction may be random rather than ordered and (b) that the monovalent oxyanions have a much greater affinity for the E X MgATP complex than for free E. In this respect, FSO3-, ClO4-, etc., are not true sulfate analogs although they might mimic an enzyme-bound species formed when MgATP is at the active site. The nonlinear ATP sulfurylase reaction progress curves (with APS accumulating in the presence of excess pyrophosphatase or PPi accumulating in the presence of excess APS kinase) were analyzed by means of "average velocity" plots based on an integrated rate equation. This new approach is useful for enzymes subject to potent product inhibition over a reaction time course in which the substrate concentrations do not change significantly. The analysis showed that ATP sulfurylase has an intrinsic specific activity of 6 to 7 units mg protein-1. Thus, the apparent stimulation of sulfurylase activity by APS kinase results from the continual removal of inhibitory APS rather than from an association of the two sulfate-activating enzymes to form a "3'-phospho-5'-adenylylsulfate synthetase" complex in which the sulfurylase has an increased catalytic activity. The progress curve analyses suggest that APS is competitive with both MgATP and sulfate, while MgPPi is a mixed-type inhibitor with respect to both substrates. The cumulative data point to a random sequence for the forward reaction with APS release being partially rate limiting.     

Insights into the product release mechanism of dengue virus NS3 helicase

The non-structural protein 3 helicase (NS3h) is a multifunctional protein that is critical in RNA replication and other stages in the flavivirus life cycle. NS3h uses energy from ATP hydrolysis to translocate along single stranded nucleic acid and to unwind double stranded RNA. Here we present a detailed mechanistic analysis of the product release stage in the catalytic cycle of the dengue virus (DENV) NS3h. This study is based on a combined experimental and computational approach of product-inhibition studies and free energy calculations. Our results support a model in which the catalytic cycle of ATP hydrolysis proceeds through an ordered sequential mechanism that includes a ternary complex intermediate (NS3h-Pi-ADP), which evolves releasing the first product, phosphate (Pi), and subsequently ADP. Our results indicate that in the product release stage of the DENV NS3h a novel open-loop conformation plays an important role that may be conserved in NS3 proteins of other flaviviruses as well.     

Cloning of two cDNAs encoding a family of ATP sulfurylase from Camellia sinensis related to selenium or sulfur metabolism and functional expression in Escherichia coli.

ATP sulfurylase, the first enzyme in the sulfate assimilation pathway of plants, catalyzes the formation of adenosine phosphosulfate from ATP and sulfate. Here we report the cloning of two cDNAs encoding ATP sulfurylase (APS1 and APS2) from Camellia sinensis. They were isolated by RT-PCR and RACE-PCR reactions. The expression of APS1 and APS2 are correlated with the presence of ATP sulfurylase enzyme activity in cell extracts. APS1 is a 1415-bp cDNA with an open reading frame predicted to encode a 360-amino acid, 40.5kD protein; APS2 is a 1706-bp cDNA with an open reading frame to encode a 465-amino acid, 51.8kD protein. The predicted amino acid sequences of APS1 and APS2 have high similarity to ATP sulfurylases of Medicago truncatula and Solanum tuberosum, with 86% and 84% identity respectively. However, they share only 59.6% identity with each other. The enzyme extracts prepared from recombinant Escherichia coli containing Camellia sinensis APS genes had significant enzyme activity.     

Characterization of the gene encoding the autotrophic ATP sulfurylase from the bacterial endosymbiont of the hydrothermal vent tubeworm Riftia pachyptila.

ATP sulfurylase is a key enzyme in the energy-generating sulfur oxidation pathways of many chemoautotrophic bacteria. The utilization of reduced sulfur compounds to fuel CO2 fixation by the still-uncultured bacterial endosymbionts provides the basis of nutrition in invertebrates, such as the tubeworm Riftia pachyptila, found at deep-sea hydrothermal vents. The symbiont-containing trophosome tissue contains high levels of ATP sulfurylase activity, facilitating the recent purification of the enzyme. The gene encoding the ATP sulfurylase from the Riftia symbiont (sopT) has now been cloned and sequenced by using the partial amino acid sequence of the purified protein. Characterization of the sopT gene has unequivocally shown its bacterial origin. This is the first ATP sulfurylase gene to be cloned and sequenced from a sulfur-oxidizing bacterium. The deduced amino acid sequence was compared to those of ATP sulfurylases reported from organisms which assimilate sulfate, resulting in the discovery that there is substantial homology with the Saccharomyces cerevisiae MET3 gene product but none with the products of the cysDN genes from Escherichia coli nor with the nodP and nodQ genes from Rhizobium meliloti. This and emerging evidence from other sources suggests that E. coli may be atypical, even among prokaryotic sulfate assimilators, in the enzyme it employs for adenosine 5'-phosphosulfate formation. The sopT gene probe also was shown to specifically identify chemoautotrophic bacteria which utilize ATP sulfurylase to oxidize sulfur compounds.     

Properties of chloroplast F1-ATPase partially modified by 2-azido adenine nucleotides, including demonstration of three catalytic pathways

Previous investigations on the distribution of [18O]Pi isotopomers formed by hydrolysis of [gamma-18O]ATP by the chloroplast F1-ATPase (CF1) showed that a single reaction pathway is used by all participating sites and that the pathway is modulated by ATP concentration as expected for cooperative interactions between catalytic sites. Such oxygen exchange measurements have been applied to CF1 modified at a single catalytic or noncatalytic site by 2-azido adenine nucleotides. When less than one catalytic or one noncatalytic site per enzyme is modified, hydrolysis occurs in part by the pathway of the unmodified enzyme plus at least one additional pathway at 200 microM and two additional pathways at 4 microM [gamma-18O]ATP. Thus, three sites are potentially catalytically active. The two new pathways shown by the derivatized enzyme logically can arise from nonidentical interactions of the remaining two underivatized beta subunits with the derivatized beta subunit. Reversals of bound ATP cleavage before Pi is released are increased, and the amount of product formed by the new pathways is changed when the ATP concentration is lowered. These modulations must result from the behavior of two remaining active catalytic sites rather than of one catalytic and one regulatory site. When the CF1 is derivatized more extensively, the original catalytic pathway is lost, and two catalytic pathways that do not show modulation by ATP concentration are found. The remaining beta subunits now have weak but independent catalytic capacity. In addition, the enzyme is no longer activated by Ca2+, loses MgGTPase activity, and is much less sensitive to azide.     

Differential subcellular localization and expression of ATP sulfurylase and 5'-adenylylsulfate reductase during ontogenesis of Arabidopsis leaves indicates that cytosolic and plastid forms of ATP sulfurylase may have specialized functions

ATP sulfurylase and 5'-adenylylsulfate (APS) reductase catalyze two reactions in the sulfate assimilation pathway. Cell fractionation of Arabidopsis leaves revealed that ATP sulfurylase isoenzymes exist in the chloroplast and the cytosol, whereas APS reductase is localized exclusively in chloroplasts. During development of Arabidopsis plants the total activity of ATP sulfurylase and APS reductase declines by 3-fold in leaves. The decline in APS reductase can be attributed to a reduction of enzyme during aging of individual leaves, the highest activity occurring in the youngest leaves and the lowest in fully expanded leaves. By contrast, total ATP sulfurylase activity declines proportionally in all the leaves. The distinct behavior of ATP sulfurylase can be attributed to reciprocal expression of the chloroplast and cytosolic isoenzymes. The chloroplast form, representing the more abundant isoenzyme, declines in parallel with APS reductase during aging; however, the cytosolic form increases over the same period. In total, the results suggest that cytosolic ATP sulfurylase plays a specialized function that is probably unrelated to sulfate reduction. A plausible function could be in generating APS for sulfation reactions.     

酿酒酵母ATP-硫酸化酶在大肠杆菌中的表达纯化及其在焦测序中的应用

ATP-硫酸化酶(ATPS,EC2.7.7.4)是一种可逆催化ATP和SO42-反应生成腺嘌呤-5′-磷酸硫酸(APS)和焦磷酸盐(PPi)的酶,已经用于焦测序反应。以酿酒酵母(Saccharomyces cerevisias,CICC1202)基因组DNA为模板,用PCR扩增得到ATPS基因,并克隆到原核表达质粒pET28a( ),得到重组表达质粒pET28a( )-ATPS,在IPTG诱导下,携带pET28a( )-ATPS的大肠杆菌BL21(DE3)表达分子量约为60kD的带有His标签的ATPS酶,经镍亲和层析和超滤两步纯化后,可得到电泳纯级ATPS,比活达5.1×104u/mg,并成功应用于焦测序反应中。     

Structural and enzymatic investigation of the Sulfolobus solfataricus uridylate kinase shows competitive UTP inhibition and the lack of GTP stimulation

The pyrH gene encoding uridylate kinase (UMPK) from the extreme thermoacidophilic archaeon Sulfolobus solfataricus was cloned and expressed in Escherichia coli, and the enzyme (SsUMPK) was purified. Size exclusion chromatography and sedimentation experiments showed that the oligomeric state in solution is hexameric. SsUMPK shows maximum catalytic rate at pH 7.0, and variation of pH only influences the turnover number. Catalysis proceeds by a sequential reaction mechanism of random order and depends on a divalent cation. The enzyme exhibits high substrate specificity toward UMP and ATP and is inhibited by UTP, whereas CTP and GTP do not influence activity. UTP binds to the enzyme with a sigmoid binding curve, whereas GTP does not bind. The crystal structure of SsUMPK was determined for three different complexes, a ternary complex with UMP and the nonhydrolyzable ATP analogue beta,gamma-methylene-ATP, a complex with UMP, and a complex with UTP to 2.1, 2.2, and 2.8 A resolution, respectively. One UTP molecule was bound in the acceptor site per subunit, leading to the exclusion of both substrates from the active site. In all cases, SsUMPK crystallized as a hexamer with the main fold shared with other prokaryotic UMPKs. Similar to UMPK from Pyrococcus furiosus, SsUMPK has an active site enclosing loop. This loop was only ordered in one subunit in the ternary complex, which also contained an unusual arrangement of ligands (possibly a dinucleotide) in the active site and an altered orientation of the catalytic residue Arg48 relative to the other five subunits of the hexamer.