Aspartate transcarbamoylase genes of Pseudomonas putida: requirement for an inactive dihydroorotase for assembly into the dodecameric holoenzyme.

The nucleotide sequences of the genes encoding the enzyme aspartate transcarbamoylase (ATCase) from Pseudomonas putida have been determined. Our results confirm that the P. putida ATCase is a dodecameric protein composed of two types of polypeptide chains translated coordinately from overlapping genes. The P. putida ATCase does not possess dissociable regulatory and catalytic functions but instead apparently contains the regulatory nucleotide binding site within a unique N-terminal extension of the pyrB-encoded subunit. The first gene, pyrB, is 1,005 bp long and encodes the 334-amino-acid, 36.4-kDa catalytic subunit of the enzyme. The second gene is 1,275 bp long and encodes a 424-residue polypeptide which bears significant homology to dihydroorotase (DHOase) from other organisms. Despite the homology of the overlapping gene to known DHOases, this 44.2-kDa polypeptide is not considered to be the functional product of the pyrC gene in P. putida, as DHOase activity is distinct from the ATCase complex. Moreover, the 44.2-kDa polypeptide lacks specific histidyl residues thought to be critical for DHOase enzymatic function. The pyrC-like gene (henceforth designated pyrC') does not complement Escherichia coli pyrC auxotrophs, while the cloned pyrB gene does complement pyrB auxotrophs. The proposed function for the vestigial DHOase is to maintain ATCase activity by conserving the dodecameric assembly of the native enzyme. This unique assembly of six active pyrB polypeptides coupled with six inactive pyrC' polypeptides has not been seen previously for ATCase but is reminiscent of the fused trifunctional CAD enzyme of eukaryotes.     

Aquifex aeolicus dihydroorotase: association with aspartate transcarbamoylase switches on catalytic activity

Dihydroorotase (DHOase) catalyzes the reversible condensation of carbamoyl aspartate to form dihydroorotate in de novo pyrimidine biosynthesis. The enzyme from Aquifex aeolicus, a hyperthermophilic organism of ancient lineage, was cloned and expressed in Escherichia coli. The purified protein was found to be a 45-kDa monomer containing a single zinc ion. Although there is no other DHOase gene in the A. aeolicus genome, the recombinant protein completely lacked catalytic activity at any temperature tested. However, DHOase formed an active complex with aspartate transcarbamoylase (ATCase) from the same organism. Whereas the k(cat) of 13.8 +/- 0.03 s(-1) was close to the value observed for the mammalian enzyme, the K (m)for dihydroorotate, 3.03 +/- 0.05 mM was 433-fold higher. Gel filtration and chemical cross-linking showed that the complex exists as a 240-kDa hexamer (DHO(3)-ATC(3)) and a 480-kDa duodecamer (DHO(6)-ATC(6)) probably in rapid equilibrium. Complex formation protects both DHOase and ATCase against thermal degradation at temperatures near 100 degrees C where the organism grows optimally. These results lead to the reclassification of both enzymes: ATCase, previously considered a Class C homotrimer, now falls into Class A, whereas the DHOase is a Class 1B enzyme. CD spectroscopy indicated that association with ATCase does not involve a significant perturbation of the DHOase secondary structure, but the visible absorption spectrum of a Co(2+)-substituted DHOase is appreciably altered upon complex formation suggesting a change in the electronic environment of the active site. The association of DHOase with ATCase probably serves as a molecular switch that ensures that free, uncomplexed DHOase in the cell remains inactive. At pH 7.4, the equilibrium ratio of carbamoyl aspartate to dihydroorotate is 17 and complex formation may drive the reaction in the biosynthetic direction.     

Ca-asp bound X-ray structure and inhibition of Bacillus anthracis dihydroorotase (DHOase)

Dihydroorotase (DHOase) is the third enzyme in the de novo pyrimidine synthesis pathway and is responsible for the reversible cyclization of carbamyl-aspartate (Ca-asp) to dihydroorotate (DHO). DHOase is further divided into two classes based on several structural characteristics, one of which is the length of the flexible catalytic loop that interacts with the substrate, Ca-asp, regulating the enzyme activity. Here, we present the crystal structure of Class I Bacillus anthracis DHOase with Ca-asp in the active site, which shows the peptide backbone of glycine in the shorter loop forming the necessary hydrogen bonds with the substrate, in place of the two threonines found in Class II DHOases. Despite the differences in the catalytic loop, the structure confirms that the key interactions between the substrate and active site residues are similar between Class I and Class II DHOase enzymes, which we further validated by mutagenesis studies. B. anthracis DHOase is also a potential antibacterial drug target. In order to identify prospective inhibitors, we performed high-throughput screening against several libraries using a colorimetric enzymatic assay and an orthogonal fluorescence thermal binding assay. Surface plasmon resonance was used for determining binding affinity (K_D) and competition analysis with Ca-asp. Our results highlight that the primary difference between Class I and Class II DHOase is the catalytic loop. We also identify several compounds that can potentially be further optimized as potential B. anthracis inhibitors.     

The aspartate transcarbamoylase–dihydroorotase complex in Deinococcus radiophilus has an active dihydroorotase

Aspartate transcarbamoylase (ATCase) and dihydroorotase (DHOase) catalyse the first two steps unique to pyrimidine synthesis. In many bacteria they form non-covalently bonded complexes. There are two types of DHOase, type I and type II which share a common ancestry. Type I is the more ancient form and is present in the complexes. In recently evolved bacteria the DHOase is defective and its function has been replaced by a type II DHOase which is separate from the complex. Deinococcus radiophilus diverges early on the phylogenetic tree and so might be expected to have an active type I DHOase. Purification of the 500 kDa ATCase–DHOase complex, by conventional techniques, showed it to possess an active DHOase.     

Synthesis of the nonconserved dihydroorotase domain of the multifunctional hamster CAD protein in Escherichia coli.

CAD is the multifunctional protein of higher eukaryotes which catalyzes the first three steps of pyrimidine biosynthesis. Its enzymatic activities exist as independent domains in the order: N terminus-carbamylphosphate synthetase II(CPSase)-dihydroorotase(DHOase)-aspartate transcarbamylase(ATCase)-C terminus. To functionally define the minimum hamster cDNA region required to encode an active DHOase, expression constructs were generated. Many such constructs complement Escherichia coli mutants defective not only in DHOase but also in ATCase. Constructs deleted for most of the sequence encoding the ATCase domain continue to complement E. coli mutants defective in DHOase. All of these smaller constructs also lack the region encoding CPSase. Therefore, a 'genetic cassette', containing information for neither the CPSase nor the ATCase domain, can direct the synthesis of a polypeptide with DHOase activity. Interestingly, inclusion of a portion of the DHOase-ATCase interdomain bridge appears to be required for optimum activity.     

Studies on the female sterile mutant rudimentary of Drosophila melanogaster. II. An analysis of aspartate transcarbamylase and dihydroorotase activities in wild-type and rudimentary strains

The activities of the enzymes aspartate transcarbamylase (ATCase) and dihydroorotase (DHOase) were determined in adult females from a wild-type strain and from eight different alleles of the X-linked mutation rudimentary (r) of Drosophila melanogaster. The alleles chosen span the genetic map of the r locus. The characteristics of the DHOase-catalyzed reaction which converts carbamyl aspartate to dihydroorotate are briefly described. Of all of the r strains tested, only one, r ⁹, has wild-type levels of aspartate transcarbamylase and dihydroorotase activities. The other seven show either intermediate or very low levels of activity for both enzymes. The lowered ATCase and DHOase activities observed in mutants which do not map in the region of the structural gene for these enzymes are interpreted in light of recent evidence that ATCase and DHOase are part of a three-enzyme complex.This work was supported by the following grants: PHS HDO7918, BMS 74-19691, and a Basil O'Connor Starter Grant from the National Foundation-March of Dimes.     

Rudimentary locus of Drosophila melanogaster: Partial purification of a carbamylphosphate synthase-aspartate transcarbamylase-dihydroorotase complex

Glutamine-dependent CPSase, ATCase, and DHOase from Drosophila, the first three enzymes in pyrimidine biosynthesis, show coordinate variation in activity throughout development. The three activities were highest in first instar larvae and decreased as development proceeded. The three activities cosediment in sucrose gradients as a single peak with a relative sedimentation coefficient of approximately 30S. CPSase, ATCase, and DHOase copurify during (NH₄) ₂SO₄ fractionation and during DEAE-cellulose and hydroxylapatite chromatography.This work was supported by a grant from the National Science Foundation (No. PCM75-22802). In addition, Stuart I. Tsubota was a NIH Predoctoral Trainee (No. 5T32-GM07 127) and Susan E. Germeraad was a Cystic Fibrosis Foundation Postdoctoral Fellow.     

Crystal structure of Methanococcus jannaschii dihydroorotase

In this paper, we report the structural analysis of dihydroorotase (DHOase) from the hyperthermophilic and barophilic archaeon Methanococcus jannaschii. DHOase catalyzes the reversible cyclization of N-carbamoyl-l -aspartate to l -dihydroorotate in the third step of de novo pyrimidine biosynthesis. DHOases form a very diverse family of enzymes and have been classified into types and subtypes with structural similarities and differences among them. This is the first archaeal DHOase studied by x-ray diffraction. Its structure and comparison with known representatives of the other subtypes help define the structural features of the archaeal subtype. The M. jannaschii DHOase is found here to have traits from all subtypes. Contrary to expectations, it has a carboxylated lysine bridging the two Zn ions in the active site, and a long catalytic loop. It is a monomeric protein with a large β sandwich domain adjacent to the TIM barrel. Loop 5 is similar to bacterial type III and the C-terminal extension is long.     

The aspartate transcarbamylase domain of a mammalian multifunctional protein expressed as an independent enzyme in Escherichia coli

Summary Although aspartate transcarbamylase (ATCase) is an independent, monofunctional enzyme in Escherichia coli, mammalian ATCase is one of the globular enzymatic domains of the multifunctional CAD protein. We subcloned fragments of the hamster CAD cDNA and assayed polypeptide products expressed in E. coli for ATCase activity in order to isolate a stretch of cDNA which encodes only the ATCase domain. Three such expression constructs contain fragments of hamster CAD cDNA similar in length to the gene encoding the E. coli ATCase catalytic subunit (pyrB). These constructs yield stable proteins with ATCase activity, ascertained by both in vivo and in vitro assays; the clones also possess sequence homology with the pyrB gene at both the 5 and 3 ends. The clone producing the most active ATCase contains cDNA which is analogous to the entire pyrB gene, plus a small amount of CAD sequence upstream of this region. Because these constructs produce independently folded, active ATCase from a piece of cDNA the size of the E. coli pyrB gene, they open the door for the in-depth investigation of the isolated mammalian enzyme domain utilizing recombinant DNA technology. This approach is potentially useful for the analysis of domains of other multifunctional proteins.Abbreviations (EC 2.1.3.2) ATCase, aspartate transcarbamylase - CAD the trifunctional protein catalyzing the first three steps of pyrimidine biosynthesis in higher eukaryotes - (EC 6.3.5.5) CPSaseII, glutamine-dependent carbamylphosphate synthetase II - (EC 3.5.2.3) DHOase, dihydroorotase - IPTG isopropyl--d-thiogalactopyranoside     

The structural organization of the hamster multifunctional protein CAD. Controlled proteolysis, domains, and linkers.

CAD is a multidomain protein that catalyzes the first three steps in mammalian de novo pyrimidine biosynthesis. The 243-kDa polypeptide consists of four functional domains; glutamine amidotransferase (GLNase), carbamyl phosphate synthetase (CPSase), aspartate transcarbamylase (ATCase), and dihydroorotase (DHOase). Controlled proteolysis of hamster CAD was found to cleave the molecule into 18 fragments which successively accumulate and disappear during the course of digestion. Each fragment was isolated and partially sequenced to determine its location in the polypeptide chain. Proteolysis was found to usually occur at the junctions between the domains and sub-domains identified by sequence homology. All proteases of low to moderate specificity cleaved the molecule in a similar fashion. The rate of proteolysis widely varied and the interdomain regions were not always accessible to proteases. Each of the major functional domains is postulated to consist of subdomains. The duplicated halves of the CPSase domain (116 kDa) have a homologous structure consisting of 11-, 25-26-, and 21-22-kDa subdomains. Prolonged digestion cleaved the DHOase domain (36.6 kDa) into two stable species suggesting that this region is comprised of 11.5- and 15.0-kDa subdomains. Similarly, proteolysis of the 21-kDa catalytic subdomain of the GLNase domain (40 kDa) indicated a bilobal structure consisting of 12.3- and 8.5-kDa chain segments. The connecting region between the two ATCase subdomains (16.4 and 18 kDa) was not cleaved. Copurification of many of the domains showed that they remain associated by noncovalent interactions even after the connecting segments have been cleaved. The chain segments, the linkers, which connect the domains and subdomains were conserved in length but not in sequence, were predicted to be relatively hydrophilic and flexible but did not show a tendency to assume a particular secondary structure. These studies provide a more detailed map of the structural organization of the CAD polypeptide.     

Dihydroorotase of human malarial parasite Plasmodium falciparum differs from host enzyme

Plasmodium falciparum, the causative agent of human malaria, is totally dependent on de novo pyrimidine biosynthetic pathway. A gene encoding P. falciparum dihydroorotase (pfDHOase) was cloned and expressed in Escherichia coli as monofunctional enzyme. PfDHOase revealed a molecular mass of 42 kDa. In gel filtration chromatography, the major enzyme activity eluted at 40 kDa, indicating that it functions in a monomeric form. This was similarly observed using the native enzyme purified from P. falciparum. Interestingly, kinetic parameters of the enzyme and inhibitory effect by orotate and its 5-substituted derivatives parallel that found in mammalian type I DHOase. Thus, the malarial enzyme shares characteristics of both type I and type II DHOases. This study provides the monofunctional property of the parasite DHOase lending further insights into its differences from the human enzyme which forms part of a multifunctional protein.     

An improved purification method and a further characterization of the 33-kilodalton protein of spinach chloroplasts

The 33-kDa protein was purified in a high yield from thylakoid membranes of spinach chloroplasts. The extinction coefficient and A^1%_1cm value at 276 nm of the protein were 22000 M^?1·cm^?1 and 6.8, respectively. The 33-kDa protein and a polypeptide appearing at 32 kDa in the SDS-polyacrylamide gel electrophoresis of thylakoid membranes were compared by peptide mapping after limited proteolysis. This indicates that the 32-kDa band is entirely due to the 33-kDa protein. The molar ratio of chlorophyll to the 33-kDa protein in the chloroplasts was estimated to be 300. This suggests that one photosynthetic unit possesses one or two molecules of the 33-kDa protein.     

Iron-sulfur centers in the photosynthetic reaction center complex fromChlorobium vibrioforme. Differences from and similarities to the iron-sulfur centers in Photosystem I

The photosynthetic reaction center complex from the green sulfur bacteriumChlorobium vibrioforme has been isolated under anaerobic conditions. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis reveals polypeptides with apparent molecular masses of 80, 40, 30, 18, 15, and 9 kDa. The 80- and 18-kDa polypeptides are identified as the reaction center polypeptide and the secondary donor cytochromec ₅₅₁ encoded by thepscA andpscC genes, respectively. N-terminal amino acid sequences identify the 40-kDa polypeptide as the bacteriochlorophylla-protein of the baseplate (the Fenna-Matthews-Olson protein) and the 30-kDa polypeptide as the putative 2[4Fe-4S] protein encoded bypscB. Electron paramagnetic resonance (EPR) analysis shows the presence of an iron-sulfur cluster which is irreversibly photoreduced at 9K. Photoaccumulation at higher temperature shows the presence of an additional photoreduced cluster. The EPR spectra of the two iron-sulfur clusters resemble those of F_A and F_B of Photosystem I, but also show significantly differentg-values, lineshapes, and temperature and power dependencies. We suggest that the two centers are designated Center I (with calculatedg-values of 2.085, 1.898, 1.841), and Center II (with calculatedg-values of 2.083, 1.941, 1.878). The data suggest that Centers I and II are bound to thepscB polypeptide.     

Peptide-protein interaction markedly alters the functional properties of the catalytic subunit of aspartate transcarbamoylase.

Interaction of a 70-amino acid zinc-binding polypeptide from the regulatory chain of aspartate transcarbamoylase (ATCase) with the catalytic (C) subunit leads to dramatic changes in enzyme activity and affinity for ligand binding at the active sites. The complex between the polypeptide (zinc domain) and wild-type C trimer exhibits hyperbolic kinetics in contrast to the sigmoidal kinetics observed with the intact holoenzyme. Moreover, the Scatchard plot for binding N-(phosphonacetyl)-L-aspartate (PALA) to the complex is linear with a Kd corresponding to that evaluated for the holoenzyme converted to the relaxed (R) state. Additional evidence that the binding of the zinc domain to the C trimer converts it to the R state was attained with a mutant form of ATCase in which Lys 164 in the catalytic chain is replaced by Glu. As shown previously (Newell, J.O. & Schachman, H.K., 1990, Biophys. Chem. 37, 183-196), this mutant holoenzyme, which exists in the R conformation even in the absence of active site ligands, has a 50-fold greater affinity for PALA than the free C subunit. Adding the zinc domain to the C trimer containing the Lys 164-->Glu substitution leads to a 50-fold enhancement in the affinity for the bisubstrate analog yielding a value of Kd equal to that for the holoenzyme. A different mutant ATCase containing the Gln 231 to Ile replacement was shown (Peterson, C.B., Burman, D.L., & Schachman, H.K., 1992, Biochemistry 31, 8508-8515) to be much less active as a holoenzyme than as the free C trimer. For this mutant holoenzyme, the addition of substrates does not cause its conversion to the R state. However, the addition of the zinc domain to the Gln 231-->Ile C trimer leads to a marked increase in enzyme activity, and PALA binding data indicate that the complex resembles the R state of the holoenzyme. This interaction leading to a more active conformation serves as a model of intergenic complementation in which peptide binding to a protein causes a conformational correction at a site remote from the interacting surfaces resulting in activation of the protein. This linkage was also demonstrated by difference spectroscopy using a chromophore covalently bound at the active site, which served as a spectral probe for a local conformational change. The binding of ligands at the active sites was shown also to lead to a strengthening of the interaction between the zinc domain and the C trimer.     

Characterization of CaMKIIα holoenzyme stability

Ca²⁺/calmodulin‐dependent protein kinase II (CaMKII) is a Ser/Thr kinase necessary for long‐term memory formation and other Ca²⁺‐dependent signaling cascades such as fertilization. Here, we investigated the stability of CaMKIIα using a combination of differential scanning calorimetry (DSC), X‐ray crystallography, and mass photometry (MP). The kinase domain has a low thermal stability (apparent T_m = 36°C), which is slightly stabilized by ATP/MgCl₂ binding (apparent T_m = 40°C) and significantly stabilized by regulatory segment binding (apparent T_m = 60°C). We crystallized the kinase domain of CaMKII bound to p‐coumaric acid in the active site. This structure reveals solvent‐exposed hydrophobic residues in the substrate‐binding pocket, which are normally buried in the autoinhibited structure when the regulatory segment is present. This likely accounts for the large stabilization that we observe in DSC measurements comparing the kinase alone with the kinase plus regulatory segment. The hub domain alone is extremely stable (apparent T_m ~ 90°C), and the holoenzyme structure has multiple unfolding transitions ranging from ~60°C to 100°C. Using MP, we compared a CaMKIIα holoenzyme with different variable linker regions and determined that the dissociation of both these holoenzymes occurs at a higher concentration (is less stable) compared with the hub domain alone. We conclude that within the context of the holoenzyme structure, the kinase domain is stabilized, whereas the hub domain is destabilized. These data support a model where domains within the holoenzyme interact.     

Production of Cellulases by Aspergillus fumigatus and Characterization of One β-Glucosidase

Aspergillus fumigatus produces substantial extracellular cellulases on several cellulosic substrates including simple sugars. Low glucose potentiates enzyme production, but most cellulose-induced cellulases are repressed by high glucose. As production of cellulase in a wide substrate range is unusual, the cellulolytic complex of this thermophilic fungus was investigated. A β-glucosidase was separated by gel filtration and ion-exchange chromatography. It migrated in native polyacrylamide gel as a single protein (130 kDa), which split under denaturing conditions into two smaller proteins having molecular masses of 90 kDa and 45 kDa. However, only the 90-kDa protein was active. Conventional chromatographic procedures were unsuccessful for the separation of these two proteins. Therefore, the 130-kDa protein was studied for its kinetic properties. It hydrolyzed p-nitrophenyl-β-D-glucopyranoside (p-NPG) and cellobiose, but not β-glucans, laminarin, and p-nitrophenyl-β-D-xilopyranoside. The optimal pH and temperature of p-NPG and cellobiose hydrolysis were 5.0 and 4.0, and 65°C and 60°C, respectively. The K _m values, determined for cellobiose and p-NPG of hydrolysis, were 0.075 mM and 1.36 mM, respectively. Glucose competitively inhibited the hydrolysis of p-NPG. The K_i was 3.5 mM.     

Location of the dihydroorotase domain within trifunctional hamster dihydroorotate synthetase

Mammalian dihydroorotase (DHOase, EC 3.5.2.3) is part of a trifunctional protein, dihydroorotate synthetase which catalyzes the first three reactions of de novo pyrimidine biosynthesis. We have subcloned a portion of the cDNA from the plasmid pCAD142 and obtained a nucleotide sequence which extends 2.1 kb in the 5' direction from the sequence encoding the aspartate transcarbamoylase (ATCase) domain at the 3'-end of the cDNA. The DHOase and ATCase domains have been purified from an elastase digest of the trifunctional protein and subjected to amino acid (aa) sequencing from their N termini. The sequence of the N-terminal 24 aa of the DHOase domain has been obtained and aligned with the cDNA sequence. The C-terminal residues of the DHOase domain have been identified as Leu followed by Val which, when taken with partial sequences of the CNBr fragments of this domain, defines the coding sequence of the active, globular DHOase domain released by proteolysis. Prediction of protein secondary structure from the deduced aa sequence showed that the DHOase domain (Mr 37,751) is separated from the C-terminal ATCase domain (Mr 34,323) by a bridging sequence (Mr 12,532) consisting of multiple beta-turns.     

Enzymes of de novo Pyrimidine Biosynthesis in Babesia rodhaini1

ABSTRACT. The pathway of de novo pyrimidine biosynthesis in the rodent parasitic protozoa Babesia rodhaini has been investigated. Specific activities of five of the six enzymes of the pathway were determined: aspartate transcarbamylase (ATCase: E.C. 2.1.3.2): dihydroorotase (DHOase: E.C. 3.5.2.3): dihydroorotate dehydrogenase (DHO-DHase: E.C. 1.3.3.1); orotate phosphoribosyltransferase (OPRTase: E.C. 2.4.2.10); and orotidine-5′-phosphate decarboxylase (ODCase: E.C. 4.1.1.23). Michaelis constants for ATCase, DHO-DHasc. OPRTase, and ODCase were determined in whole homogenates. Several substrate analogs were also investigated as inhibitors and inhibitor constants determined. N-(phosphonacetyl)-L-aspartate was shown to be an inhibitor of the ATCase with an apparent K, of 7μM. Dihydro-5-azaorotate inhibited the DHO-DHase (K, 16 μM) and 5-azaorotate (K_i, 21 μM) was an inhibitor of the OPRTase. The UMP analog, 6-aza-UMP (K_i, 0.3 μM) was a potent inhibitor of ODCase, while lower levels of inhibition were found with the product. UMP (K_i, 120 μM) and the purine nucleotide, XMP (K₁, 95 μM). Additionally, menoctone, a ubiquinone analog, was shown to inhibit DHO-DHase.     

Partial Purification and Characterization of Thermostable Acid Phosphatase from Thermoacidophilic Archaeon Sulfolobus acidocaldarius

Thermostable acid phosphatase (APase) from thermoacidophilic archaeon Sulfolobus acidocaldarius was isolated, partially purified, and characterized. The optimum pH and temperature of the enzyme for p-nitrophenylphosphate (pNPP) as a substrate were 5.0 and 70°C, respectively. The apparent K _m value was 1.9 mM. This APase showed a native molecular mass of 20 kDa on a gel filtration chromatography. Of the APase activity, 60% remained after 60 min of heat treatment at 75°C. To confirm whether the APase is active in the monomeric form, we attempted to elute the enzyme from SDS-polyacrylamide gels with Disk electrophoresis apparatus and renature the enzyme. The APase activity was recovered up to 50% in the 14- to 35-kDa range, and maximum around 25 kDa. These results suggest that this APase is monomeric protein. Received: 8 July 1999 / Accepted: 9 August 1999