The crystal structures of ornithine carbamoyltransferase from Mycobacterium tuberculosis and its ternary complex with carbamoyl phosphate and L-norvaline reveal the enzyme's catalytic mechanism

Mycobacterium tuberculosis ornithine carbamoyltransferase (Mtb OTC) catalyzes the sixth step in arginine biosynthesis; it produces citrulline from carbamoyl phosphate (CP) and ornithine (ORN). Here, we report the crystal structures of Mtb OTC in orthorhombic (form I) and hexagonal (form II) space groups. The molecules in form II are complexed with CP and l-norvaline (NVA); the latter is a competitive inhibitor of OTC. The asymmetric unit in form I contains a pseudo hexamer with 32 point group symmetry. The CP and NVA in form II induce a remarkable conformational change in the 80s and the 240s loops with the displacement of these loops towards the active site. The displacement of these loops is strikingly different from that seen in other OTC structures. In addition, the ligands induce a domain closure of 4.4° in form II. Sequence comparison of active-site residues of Mtb OTC with several other OTCs of known structure reveals that they are virtually identical. The interactions involving the active-site residues of Mtb OTC with CP and NVA and a modeling study of ORN in the form II structure strongly rule out an earlier proposed mechanistic role of Cys264 in catalysis and suggest a possible mechanism for OTC. Our results strongly support the view that ORN with an already deprotonated N^ε atom is the species that binds to the enzyme and that one of the phosphate oxygen atoms of CP is likely to be involved in accepting a proton from the doubly protonated N^ε atom of ORN. We have interpreted this deprotonation as part of the collapse of the transition state of the reaction.     

N5-phosphonoacetyl-L-ornithine (PALO): a convenient synthesis and investigation of influence on regulation of amino acid biosynthetic genes in Saccharomyces cerevisiae

A scalable four-step synthesis of the ornithine transcarbamylase inhibitor N⁵-phosphonoacetyl-l-ornithine (PALO) is achieved through boroxazolidinone protection of ornithine. Investigations in the model organism Saccharomyces cerevisiae found that, in contrast to a previous report, PALO did not influence growth rate or expression of genes involved in arginine metabolism.     

A highly basic N-terminal extension of the mitochondrial matrix enzyme ornithine transcarbamylase from rat liver

We have deduced the amino acid sequence of the N-terminal leader peptide of the mitochondrial enzyme ornithine transcarbamylase from a cDNA clone obtained from a rat liver cDNA library. The sequence is remarkable in being highly basic, having 4 arginine, 3 lysine and 1 histidine with no acidic residues in a total of 32 residues. The leader sequence has no extensive hydrophobic stretches, has 72% homology with the leader peptide of human ornithine transcarbamylase [1], and in terms of its basic character resembles the N-terminal extensions on a number of fungal mitochondrial [2-5] and pea chloroplast [6] proteins. Thus the basic nature of these leader peptides may constitute the signal for mitochondrial import.     

A single mutation in the active site swaps the substrate specificity of N-acetyl-L-ornithine transcarbamylase and N-succinyl-L-ornithine transcarbamylase

Transcarbamylases catalyze the transfer of the carbamyl group from carbamyl phosphate (CP) to an amino group of a second substrate such as aspartate, ornithine, or putrescine. Previously, structural determination of a transcarbamylase from Xanthomonas campestris led to the discovery of a novel N-acetylornithine transcarbamylase (AOTCase) that catalyzes the carbamylation of N-acetylornithine. Recently, a novel N-succinylornithine transcarbamylase (SOTCase) from Bacteroides fragilis was identified. Structural comparisons of AOTCase from X. campestris and SOTCase from B. fragilis revealed that residue Glu92 (X. campestris numbering) plays a critical role in distinguishing AOTCase from SOTCase. Enzymatic assays of E92P, E92S, E92V, and E92A mutants of AOTCase demonstrate that each of these mutations converts the AOTCase to an SOTCase. Similarly, the P90E mutation in B. fragilis SOTCase (equivalent to E92 in X. campestris AOTCase) converts the SOTCase to AOTCase. Hence, a single amino acid substitution is sufficient to swap the substrate specificities of AOTCase and SOTCase. X-ray crystal structures of these mutants in complexes with CP and N-acetyl-L-norvaline (an analog of N-acetyl-L-ornithine) or N-succinyl-L-norvaline (an analog of N-succinyl-L-ornithine) substantiate this conversion. In addition to Glu92 (X. campestris numbering), other residues such as Asn185 and Lys30 in AOTCase, which are involved in binding substrates through bridging water molecules, help to define the substrate specificity of AOTCase. These results provide the correct annotation (AOTCase or SOTCase) for a set of the transcarbamylase-like proteins that have been erroneously annotated as ornithine transcarbamylase (OTCase, EC 2.1.3.3).     

The Molecular Structure of Ornithine Acetyltransferase from Mycobacterium tuberculosis Bound to Ornithine, a Competitive Inhibitor

Mycobacterium tuberculosis ornithine acetyltransferase (Mtb OAT; E.C. 2.3.1.35) is a key enzyme of the acetyl recycling pathway during arginine biosynthesis. It reversibly catalyzes the transfer of the acetyl group from N-acetylornithine (NAORN) to l-glutamate. Mtb OAT is a member of the N-terminal nucleophile fold family of enzymes. The crystal structures of Mtb OAT in native form and in its complex with ornithine (ORN) have been determined at 1.7 and 2.4 Å resolutions, respectively. ORN is a competitive inhibitor of this enzyme against l-glutamate as substrate. Although the acyl-enzyme complex of Streptomyces clavuligerus ornithine acetyltransferase has been determined, ours is the first crystal structure to be reported of an ornithine acetyltransferase in complex with an inhibitor. ORN binding does not alter the structure of Mtb OAT globally. However, its presence stabilizes the three C-terminal residues that are disordered and not observed in the native structure. Also, stabilization of the C-terminal residues by ORN reduces the size of the active-site pocket volume in the structure of the ORN complex. The interactions of ORN and the protein residues of Mtb OAT unambiguously delineate the active-site residues of this enzyme in Mtb. Moreover, modeling studies carried out with NAORN based on the structure of the ORN-Mtb OAT complex reveal important interactions of the carbonyl oxygen of the acetyl group of NAORN with the main-chain nitrogen atom of Gly128 and with the side-chain oxygen of Thr127. These interactions likely help in the stabilization of oxyanion formation during enzymatic reaction and also will polarize the carbonyl carbon-oxygen bond, thereby enabling the side-chain atom O^γ1 of Thr200 to launch a nucleophilic attack on the carbonyl-carbon atom of the acetyl group of NAORN.     

Crystal structure of a transcarbamylase-like protein from the anaerobic bacterium Bacteroides fragilis at 2.0 A resolution

A transcarbamylase-like protein essential for arginine biosynthesis in the anaerobic bacterium Bacteroides fragilis has been purified and crystallized in space group P4(3)2(1)2 (a=b=153.4 A, c=94.8 A). The structure was solved using a single isomorphous replacement with anomalous scattering (SIRAS) and was refined at 2.0 A resolution to an R-factor of 20.6% (R-free=25.2%). The molecular model is trimeric and comprises 960 amino acid residues, two phosphate groups and 422 water molecules. The monomer has the consensus transcarbamylase fold with two structural domains linked by two long interdomain helices: the putative carbamoyl phosphate-binding domain and a binding domain for the second substrate. Each domain has a central parallel beta-sheet surrounded by alpha-helices and loops with alpha/beta topology. The putative carbamoyl phosphate-binding site is similar to those in ornithine transcarbamylases (OTCases) and aspartate transcarbamylases (ATCases); however, the second substrate-binding site is strikingly different. This site has several insertions and deletions, and residues critical to substrate binding and catalysis in other known transcarbamylases are not conserved. The three-dimensional structure and the fact that this protein is essential for arginine biosynthesis suggest strongly that it is a new member of the transcarbamylase family. A similar protein has been found in Xylella fastidiosa, a bacterium that infects grapes, citrus and other plants.     

Crystal structure of the arginine repressor protein in complex with the DNA operator from Mycobacterium tuberculosis

The arginine repressor (ArgR) from Mycobacterium tuberculosis (Mtb) is a gene product encoded by the open reading frame Rv1657. It regulates the l-arginine concentration in cells by interacting with ARG boxes in the promoter regions of the arginine biosynthesis and catabolism operons. Here we present a 2.5-Å structure of MtbArgR in complex with a 16-bp DNA operator in the absence of arginine. A biological trimer of the protein-DNA complex is formed via the crystallographic 3-fold symmetry axis. The N-terminal domain of MtbArgR has a winged helix-turn-helix motif that binds to the major groove of the DNA. This structure shows that, in the absence of arginine, the ArgR trimer can bind three ARG box half-sites. It also reveals the structure of the whole MtbArgR molecule itself containing both N-terminal and C-terminal domains.     

Effect of streptozotocin diabetes on some urea cycle enzymes

Streptozotocin induced diabetes in rats increased the activities of the three mitochondrial enzymes, carbamylphosphate synthetase, ornithine transcarbamylase and N-acetylglutamate synthetase, but not of the cytosolic N-acetylglutamate deacylase. Levels of both N-acetylglutamate and arginine, which are activators of carbamylphosphate synthetase and N-acetylglutamate synthetase respectively, increased in diabetes. These results serve to explain the increase both of mitochondrial citrulline and urea formation in hepatocytes and the increased urea excretion in diabetes.     

In situ staining procedure for the detection of ornithine transcarbamylase activity in polyacrylamide gels

Ornithine transcarbamylase deficiency is a human genetic disease potentially susceptible to gene therapy. A murine model system exists for the disease in the sparse-fur (spf) mouse. Before gene therapy studies can be performed it is necessary to have practical methods which could detect successful gene transfer. Therefore we have developed an in situ staining procedure for the detection of ornithine transcarbamylase activity in polyacrylamide gels. Following electrophoretic separation under nondenaturing conditions inorganic phosphate cleaved from carbamyl phosphate in gels as a result of enzymatic activity was precipitated as phosphomolybdic acid and visualized by reduction with ascorbic acid. Results from the procedure correlated with ornithine transcarbamylase activity as measured by solution assay for citrulline, the other product of the reaction. This procedure readily distinguished mutant forms of ornithine transcarbamylase as exemplified by the murine spf mutation and resolved ornithine transcarbamylases of all animals tested into multiple forms. The procedure further distinguished ornithine transcarbamylases of animals of several different genera while yielding virtually identical patterns of the enzyme from species within the same genus. This procedure also suggested that the human enzyme was more labile than murine ornithine transcarbamylase; direct thermolability studies confirmed this finding.     

Regulation of ornithine transcarbamylase in Rhodotorula glutinis

The regulation of ornithine transcarbamylase (OTC) of Rhodotorula glutinis has been studied, by growing the yeasts in different carbon and nitrogen sources and estimating the enzyme level in crude yeasts extracts.The results show a nutritional repression of OTC by arginine, when added to the culture media as carbon, nitrogen or carbon and nitrogen sources. On the other hand ornithine does not exert any effect in the same experimental conditions.     

Crystal Structure of the Periplasmic Component of a Tripartite Macrolide-Specific Efflux Pump

In Gram-negative bacteria, type I protein secretion systems and tripartite drug efflux pumps have a periplasmic membrane fusion protein (MFP) as an essential component. MFPs bridge the outer membrane factor and an inner membrane transporter, although the oligomeric state of MFPs remains unclear. The most characterized MFP AcrA connects the outer membrane factor TolC and the resistance-nodulation-division-type efflux transporter AcrB, which is a major multidrug efflux pump in Escherichia coli. MacA is the periplasmic MFP in the MacAB-TolC pump, where MacB was characterized as a macrolide-specific ATP-binding-cassette-type efflux transporter. Here, we report the crystal structure of E. coli MacA and the experimentally phased map of Actinobacillus actinomycetemcomitans MacA, which reveal a domain orientation of MacA different from that of AcrA. Notably, a hexameric assembly of MacA was found in both crystals, exhibiting a funnel-like structure with a central channel and a conical mouth. The hexameric MacA assembly was further confirmed by electron microscopy and functional studies in vitro and in vivo. The hexameric structure of MacA provides insight into the oligomeric state in the functional complex of the drug efflux pump and type I secretion system.     

Molecular Interplay between the Replicative Helicase DnaC and Its Loader Protein DnaI from Geobacillus kaustophilus

Helicase loading factors are thought to transfer the hexameric ring-shaped helicases onto the replication fork during DNA replication. However, the mechanism of helicase transfer onto DNA remains unclear. In Bacillus subtilis, the protein DnaI, which belongs to the AAA+ family of ATPases, is responsible for delivering the hexameric helicase DnaC onto DNA. Here we investigated the interaction between DnaC and DnaI from Geobacillus kaustophilus HTA426 (GkDnaC and GkDnaI, respectively) and determined that GkDnaI forms a stable complex with GkDnaC with an apparent stoichiometry of GkDnaC₆-GkDnaI₆ in the absence of ATP. Surface plasmon resonance analysis indicated that GkDnaI facilitates loading of GkDnaC onto single-stranded DNA (ssDNA) and supports complex formation with ssDNA in the presence of ATP. Additionally, the GkDnaI C-terminal AAA+ domain alone could bind ssDNA, and binding was modulated by nucleotides. We also determined the crystal structure of the C-terminal AAA+ domain of GkDnaI in complex with ADP at 2.5 Å resolution. The structure not only delineates the binding of ADP in the expected Walker A and B motifs but also reveals a positively charged region that may be involved in ssDNA binding. These findings provide insight into the mechanism of replicative helicase loading onto ssDNA.     

A case with combined rare inborn metabolic disorders: Congenital adrenal hyperplasia and ornithine transcarbamylase deficiency

Congenital adrenal hyperplasia (CAH) due to 21-hydroxylase deficiency is a common autosomal recessive disorder. Ornithine transcarbamylase (OTC) deficiency is the most common urea cycle disorder and demonstrates X-linked inheritance. In female OTC deficiency, phenotypes are variable according to X-inactivation patterns. These disorders develop separately, and their co-morbidity is extremely rare. We report one girl with CAH showing recurrent hyperammonemia and hepatitis after 2 years-of-age due to additional OTC deficiency.     

Oligomeric State in the Crystal Structure of Modular FAD Synthetase Provides Insights into Its Sequential Catalysis in Prokaryotes

The crystal structure of the modular flavin adenine dinucleotide (FAD) synthetase from Corynebacterium ammoniagenes has been solved at 1.95 Å resolution. The structure of C. ammoniagenes FAD synthetase presents two catalytic modules—a C-terminus with ATP-riboflavin kinase activity and an N-terminus with ATP-flavin mononucleotide (FMN) adenylyltransferase activity—that are responsible for the synthesis of FAD from riboflavin in two sequential steps. In the monomeric structure, the active sites from both modules are placed 40 Å away, preventing the direct transfer of the product from the first reaction (FMN) to the second catalytic site, where it acts as substrate. Crystallographic and biophysical studies revealed a hexameric assembly formed by the interaction of two trimers. Each trimer presents a head-tail configuration, with FMN adenylyltransferase and riboflavin kinase modules from different protomers approaching the active sites and allowing the direct transfer of FMN. Experimental results provide molecular-level evidences of the mechanism of the synthesis of FMN and FAD in prokaryotes in which the oligomeric state could be involved in the regulation of the catalytic efficiency of the modular enzyme.     

Crystal structure of the plant epigenetic protein arginine methyltransferase 10

Protein arginine methyltransferase 10 (PRMT10) is a type I arginine methyltransferase that is essential for regulating flowering time in Arabidopsis thaliana. We present a 2.6 Å resolution crystal structure of A. thaliana PRMT 10 (AtPRMT10) in complex with a reaction product, S-adenosylhomocysteine. The structure reveals a dimerization arm that is 12-20 residues longer than PRMT structures elucidated previously; as a result, the essential AtPRMT10 dimer exhibits a large central cavity and a distinctly accessible active site. We employ molecular dynamics to examine how dimerization facilitates AtPRMT10 motions necessary for activity, and we show that these motions are conserved in other PRMT enzymes. Finally, functional data reveal that the 10 N-terminal residues of AtPRMT10 influence substrate specificity, and that enzyme activity is dependent on substrate protein sequences distal from the methylation site. Taken together, these data provide insights into the molecular mechanism of AtPRMT10, as well as other members of the PRMT family of enzymes. They highlight differences between AtPRMT10 and other PRMTs but also indicate that motions are a conserved element of PRMT function.     

Crystal Structure of the Extracellular Domain of a Bacterial Ligand-Gated Ion Channel

The crystal structure of the extracellular domain (ECD) of the pentameric ligand-gated ion-channel from Gloeobacter violaceus (GLIC) was solved at neutral pH at 2.3 Å resolution in two crystal forms, showing a surprising hexameric quaternary structure with a 6-fold axis replacing the expected 5-fold axis. While each subunit retains the usual β-sandwich immunoglobulin-like fold, small deviations from the whole GLIC structure indicate zones of differential flexibility. The changes in interface between two adjacent subunits in the pentamer and the hexamer can be described in a downward translation by one inter-strand distance and a global rotation of the second subunit, using the first one for superposition. While global characteristics of the interface, such as the buried accessible surface area, do not change very much, most of the atom-atom interactions are rearranged. It thus appears that the transmembrane domain is necessary for the proper oligomeric assembly of GLIC and that there is an intrinsic plasticity or polymorphism in possible subunit-subunit interfaces at the ECD level, the latter behaving as a monomer in solution. Possible functional implications of these novel structural data are discussed in the context of the allosteric transition of this family of proteins. In addition, we propose a novel way to quantify elastic energy stored in the interface between subunits, which indicates a tenser interface for the open form than for the closed form (rest state). The hexameric or pentameric forms of the ECD have a similar negative curvature in their subunit-subunit interface, while acetylcholine binding proteins have a smaller and positive curvature that increases from the apo to the holo form.     

Roles of arginine and canavanine in the synthesis and repression of ornithine transcarbamylase by Escherichia coli

Conditions were found under which the processes of repression and derepression of ornithine transcarbamylase were separated from the process of enzyme synthesis. After 10 min of arginine deprivation followed by the addition of 2 to 200 mug of l-arginine per ml, a number of strains of Escherichia coli exhibited a significant burst of ornithine transcarbamylase synthesis which lasted 3 to 4 min before the onset of repression. The rapid increase of enzyme activity was shown to require protein synthesis, and was not due to a slow uptake of arginine or induction of an arginine-inducible ornithine transcarbamylase. The capacity of E. coli to synthesize the burst of ornithine transcarbamylase reached a maximum after 10 min of arginine deprivation and then remained constant. The observed increase in enzyme synthesis may reflect the level of unstable messenger ribonucleic acid (RNA) for ornithine transcarbamylase present in the cell at the time protein synthesis was reinitiated. After the addition of arginine in the absence of protein synthesis, the burst of ornithine transcarbamylase decayed with a half-life of about 3 min. The data implied that arginine prevents synthesis of new messenger RNA that can translate this enzyme. Repression of ornithine transcarbamylase by l-canavanine (100 to 200 mug/ml) was observed, and no active enzyme was formed in the presence of this analogue. The action of canavanine as a repressor was distinguished from the inhibitory effect of this compound on protein synthesis.     

Nautilus pompilius hemocyanin: 9 A cryo-EM structure and molecular model reveal the subunit pathway and the interfaces between the 70 functional units

Hemocyanins are giant extracellular oxygen carriers in the hemolymph of many molluscs. Nautilus pompilius (Cephalopoda) hemocyanin is a cylindrical decamer of a 350 kDa polypeptide subunit that in turn is a “pearl-chain” of seven different functional units (FU-a to FU-g). Each globular FU has a binuclear copper centre that reversibly binds one O₂ molecule, and the 70-FU decamer is a highly allosteric protein. Its primary structure and an 11 Å cryo-electron microscopy (cryo-EM) structure have recently been determined, and the crystal structures of two related FU types are available in the databanks. However, in molluscan hemocyanin, the precise subunit pathway within the decamer, the inter-FU interfaces, and the allosteric unit are still obscure, but this knowledge is crucial to understand assembly and allosterism of these proteins. Here we present the cryo-EM structure of Nautilus hemocyanin at 9.1 Å resolution (FSC_1/2-bit criterion), and its molecular model obtained by rigid-body fitting of the individual FUs. In this model we identified the subunit dimer, the subunit pathway, and 15 types of inter-FU interface. Four interface types correspond to the association mode of the two protomers in the published Octopus FU-g crystal. Other interfaces explain previously described morphological structures such as the fenestrated wall (which shows D5 symmetry), the three horizontal wall tiers, the major and minor grooves, the anchor structure and the internal collar (which unexpectedly has C5 symmetry). Moreover, the potential calcium/magnesium and N-glycan binding sites have emerged. Many interfaces have amino acid constellations that might transfer allosteric interaction between FUs. From their topologies we propose that the prime allosteric unit is the oblique segment between major and minor groove, consisting of seven FUs from two different subunits. Thus, the 9 Å structure of Nautilus hemocyanin provides fundamentally new insight into the architecture and function of molluscan hemocyanins.