Structural basis for the function of pyridoxine 5'-phosphate synthase

BACKGROUND: Pyridoxal 5'-phosphate is the active form of vitamin B(6) that acts as an essential, ubiquitous coenzyme in amino acid metabolism. In Escherichia coli, the pathway of the de novo biosynthesis of vitamin B(6) results in the formation of pyridoxine 5'-phosphate (PNP), which can be regarded as the first synthesized B(6) vitamer. PNP synthase (commonly referred to as PdxJ) is a homooctameric enzyme that catalyzes the final step in this pathway, a complex intramolecular condensation reaction between 1-deoxy-D-xylulose-5'-phosphate and 1-amino-acetone-3-phosphate. RESULTS: The crystal structure of E. coli PNP synthase was solved by single isomorphous replacement with anomalous scattering and refined at a resolution of 2.0 A. The monomer of PNP synthase consists of one compact domain that adopts the abundant TIM barrel fold. Intersubunit contacts are mediated by three additional helices, respective to the classical TIM barrel helices, generating a tetramer of symmetric dimers with 422 symmetry. In the shared active sites of the active dimers, Arg20 is directly involved in substrate binding of the partner monomer. Furthermore, the structure of PNP synthase with its physiological products, PNP and P(i), was determined at 2.3 A resolution, which provides insight into the dynamic action of the enzyme and allows us to identify amino acids critical for enzymatic function. CONCLUSION: The high-resolution structures of the free enzyme and the enzyme-product complex of E. coli PNP synthase suggest essentials of the enzymatic mechanism. The main catalytic features are active site closure upon substrate binding by rearrangement of one C-terminal loop of the TIM barrel, charge-charge stabilization of the protonated Schiff-base intermediate, the presence of two phosphate binding sites, and a water channel that penetrates the beta barrel and allows the release of water molecules in the closed state. All related PNP synthases are predicted to fold into a similar TIM barrel pattern and have comparable active site architecture. Thus, a common mechanism can be anticipated.     

Cloning, expression, and characterization of sialic acid synthases

The most commonly occurring sialic acid, N-acetylneuraminic acid, is the repeating unit in polysialic acid chain of human neuronal cell adhesion molecule as well as in capsular polysialic acid of neuroinvasive bacteria, Escherichia coli K1 and Neisseria meningitidis. Sialic acid synthesis and polymerization occur in slightly different pathways in animals and bacteria. N-Acetylneuraminic acid (NeuNAc) is synthesized by the condensation of phosphoenolpyruvate and N-acetylmannosamine by NeuNAc synthase in bacteria. The mammalian homologue N-acetylneuraminic acid-9-phosphate (NeuNAc-9-P) synthase uses N-acetylmannosamine-6-phosphate in the condensation reaction to produce NeuNAc-9-P. Both subfamilies of sialic acid synthases possess N-terminal triosephosphate isomerase barrel domain and C-terminal antifreeze protein domain. We report cloning of the genes, expression, purification, and characterization of human NeuNAc-9-P synthase and N. meningitidis NeuNAc synthase. Stability of the purified enzymes and effects of pH and temperature on their activities were evaluated. Enzyme kinetics and preliminary mutagenesis experiments reveal the importance of C-terminal antifreeze protein domain and a conserved cysteine residue for the enzyme activities.     

Solution structure of the antifreeze-like domain of human sialic acid synthase

The structure of the C-terminal antifreeze-like (AFL) domain of human sialic acid synthase was determined by NMR spectroscopy. The structure comprises one alpha- and two single-turn 3(10)-helices and two beta-strands, and is similar to those of the type III antifreeze proteins. Evolutionary trace analyses of the type III antifreeze protein family suggested that the class-specific residues in the human and bacterial AFL domains are important for their substrate binding, while the class-specific residues of the fish antifreeze proteins are gathered on the ice-binding surface.     

Crystal Structure and Functional Analysis of Homocitrate Synthase, an Essential Enzyme in Lysine Biosynthesis

Homocitrate synthase (HCS) catalyzes the first and committed step in lysine biosynthesis in many fungi and certain Archaea and is a potential target for antifungal drugs. Here we report the crystal structure of the HCS apoenzyme from Schizosaccharomyces pombe and two distinct structures of the enzyme in complex with the substrate 2-oxoglutarate (2-OG). The structures reveal that HCS forms an intertwined homodimer stabilized by domain-swapping between the N- and C-terminal domains of each monomer. The N-terminal catalytic domain is composed of a TIM barrel fold in which 2-OG binds via hydrogen bonds and coordination to the active site divalent metal ion, whereas the C-terminal domain is composed of mixed α/β topology. In the structures of the HCS apoenzyme and one of the 2-OG binary complexes, a lid motif from the C-terminal domain occludes the entrance to the active site of the neighboring monomer, whereas in the second 2-OG complex the lid is disordered, suggesting that it regulates substrate access to the active site through its apparent flexibility. Mutations of the active site residues involved in 2-OG binding or implicated in acid-base catalysis impair or abolish activity in vitro and in vivo. Together, these results yield new insights into the structure and catalytic mechanism of HCSs and furnish a platform for developing HCS-selective inhibitors.     

Molecular basis of the substrate specificity and the catalytic mechanism of citramalate synthase from Leptospira interrogans

Leptospira interrogans is the causative agent for leptospirosis, a zoonotic disease of global importance. In contrast with most other micro-organisms, L. interrogans employs a pyruvate pathway to synthesize isoleucine and LiCMS (L. interrogans citramalate synthase) catalyses the first reaction of the pathway which converts pyruvate and acetyl-CoA into citramalate, thus making it an attractive target for the development of antibacterial agents. We report here the crystal structures of the catalytic domain of LiCMS and its complexes with substrates, and kinetic and mutagenesis studies of LiCMS, which together reveal the molecular basis of the high substrate specificity and the catalytic mechanism of LiCMS. The catalytic domain consists of a TIM barrel flanked by an extended C-terminal region. It forms a homodimer in the crystal structure, and the active site is located at the centre of the TIM barrel near the C-terminal ends of the beta-strands and is composed of conserved residues of the beta-strands of one subunit and the C-terminal region of the other. The substrate specificity of LiCMS towards pyruvate against other alpha-oxo acids is dictated primarily by residues Leu(81), Leu(104) and Tyr(144), which form a hydrophobic pocket to accommodate the C(2)-methyl group of pyruvate. The catalysis follows the typical aldol condensation reaction, in which Glu(146) functions as a catalytic base to activate the methyl group of acetyl-CoA to form an enolated acetyl-CoA intermediate and Arg(16) as a general acid to stabilize the intermediate.     

Crystal structure of Escherichia coli malate synthase G complexed with magnesium and glyoxylate at 2.0 A resolution: mechanistic implications

The crystal structure of selenomethionine-substituted malate synthase G, an 81 kDa monomeric enzyme from Escherichia coli has been determined by MAD phasing, model building, and crystallographic refinement to a resolution of 2.0 A. The crystallographic R factor is 0.177 for 49 242 reflections observed at the incident wavelength of 1.008 A, and the model stereochemistry is satisfactory. The basic fold of the enzyme is that of a beta8/alpha8 (TIM) barrel. The barrel is centrally located, with an N-terminal alpha-helical domain flanking one side. An inserted beta-sheet domain folds against the opposite side of the barrel, and an alpha-helical C-terminal domain forms a plug which caps the active site. Malate synthase catalyzes the condensation of glyoxylate and acetyl-coenzyme A and hydrolysis of the intermediate to yield malate and coenzyme A, requiring Mg(2+). The structure reveals an enzyme-substrate complex with glyoxylate and Mg(2+) which coordinates the aldehyde and carboxylate functions of the substrate. Two strictly conserved residues, Asp631 and Arg338, are proposed to provide concerted acid-base chemistry for the generation of the enol(ate) intermediate of acetyl-coenzyme A, while main-chain hydrogen bonds and bound Mg(2+) polarize glyoxylate in preparation for nucleophilic attack. The catalytic strategy of malate synthase appears to be essentially the same as that of citrate synthase, with the electrophile activated for nucleophilic attack by nearby positive charges and hydrogen bonds, while concerted acid-base catalysis accomplishes the abstraction of a proton from the methyl group of acetyl-coenzyme A. An active site aspartate is, however, the only common feature of these two enzymes, and the active sites of these enzymes are produced by quite different protein folds. Interesting similarities in the overall folds and modes of substrate recognition are discussed in comparisons of malate synthase with pyruvate kinase and pyruvate phosphate dikinase.     

A catalytic mechanism revealed by the crystal structures of the imidazolonepropionase from Bacillus subtilis

Imidazolonepropionase (EC 3.5.2.7) catalyzes the third step in the universal histidine degradation pathway, hydrolyzing the carbon-nitrogen bonds in 4-imidazolone-5-propionic acid to yield N-formimino-l-glutamic acid. Here we report the crystal structures of the Bacillus subtilis imidazolonepropionase and its complex at 2.0-A resolution with substrate analog imidazole-4-acetic acid sodium (I4AA). The structure of the native enzyme contains two domains, a TIM (triose-phosphate isomerase) barrel domain with two insertions and a small beta-sandwich domain. The TIM barrel domain is quite similar to the members of the alpha/beta barrel metallo-dependent hydrolase superfamily, especially to Escherichia coli cytosine deaminase. A metal ion was found in the central cavity of the TIM barrel and was tightly coordinated to residues His-80, His-82, His-249, Asp-324, and a water molecule. X-ray fluorescence scan analysis confirmed that the bound metal ion was a zinc ion. An acetate ion, 6 A away from the zinc ion, was also found in the potential active site. In the complex structure with I4AA, a substrate analog, I4AA replaced the acetate ion and contacted with Arg-89, Try-102, Tyr-152, His-185, and Glu-252, further defining and confirming the active site. The detailed structural studies allowed us to propose a zinc-activated nucleophilic attack mechanism for the hydrolysis reaction catalyzed by the enzyme.     

Dipole moment in TIM alpha/beta fold proteins

TIM proteins of alpha/beta barrel fold from alpha/beta class as given in SCOP database were taken for dipole moment analysis. In all, 32 structures were analyzed for their dipole moment contributions. Representative structures from 20 super families in the alpha/beta fold, with different enzyme functions and 12 protein domains of TIM family in TIM super family were considered. The active sites of these proteins are located on the C-terminal side of the beta-strands. The molecules of same alpha/beta fold, but differing in their functionality also showed a common electrostatic field pattern along the barrel axis and had the dipole moment along the barrel axis and towards C-terminal end of the beta-strands. However, it is observed from our calculations that the dipole moment direction is possibly a consequence of the structural fold, with distribution of charges playing a modulatory role, and does not contribute to the location of active site. We show here that apart from the commonly held view as proposed by Hol et al [Hol W G L, van Duijnen PT and Berendsen H J C (1978) Nature (London), 273, 443-446] of the role of the alpha helical dipole moment, the beta-sheets in the barrel can also have a considerable dipole moment contribution. Taken together with our dipole moment analysis on integral membrane proteins [Vasanthi G and Krishnaswamy S (2002) Indian J Biochem Biophys 39, 93-100], this suggests the need to examine the role of dipole moment in the case of especially beta sheets forming barrels.     

Cobalamin-independent methionine synthase (MetE): a face-to-face double barrel that evolved by gene duplication

Cobalamin-independent methionine synthase (MetE) catalyzes the transfer of a methyl group from methyltetrahydrofolate to L-homocysteine (Hcy) without using an intermediate methyl carrier. Although MetE displays no detectable sequence homology with cobalamin-dependent methionine synthase (MetH), both enzymes require zinc for activation and binding of Hcy. Crystallographic analyses of MetE from T. maritima reveal an unusual dual-barrel structure in which the active site lies between the tops of the two (βα)₈ barrels. The fold of the N-terminal barrel confirms that it has evolved from the C-terminal polypeptide by gene duplication; comparisons of the barrels provide an intriguing example of homologous domain evolution in which binding sites are obliterated. The C-terminal barrel incorporates the zinc ion that binds and activates Hcy. The zinc-binding site in MetE is distinguished from the (Cys)₃Zn site in the related enzymes, MetH and betaine–homocysteine methyltransferase, by its position in the barrel and by the metal ligands, which are histidine, cysteine, glutamate, and cysteine in the resting form of MetE. Hcy associates at the face of the metal opposite glutamate, which moves away from the zinc in the binary E·Hcy complex. The folate substrate is not intimately associated with the N-terminal barrel; instead, elements from both barrels contribute binding determinants in a binary complex in which the folate substrate is incorrectly oriented for methyl transfer. Atypical locations of the Hcy and folate sites in the C-terminal barrel presumably permit direct interaction of the substrates in a ternary complex. Structures of the binary substrate complexes imply that rearrangement of folate, perhaps accompanied by domain rearrangement, must occur before formation of a ternary complex that is competent for methyl transfer.     

The crystal structure and active site location of isocitrate lyase from the fungus Aspergillus nidulans

BACKGROUND: Isocitrate lyase catalyses the first committed step of the carbon-conserving glyoxylate bypass, the Mg(2+)-dependent reversible cleavage of isocitrate into succinate and glyoxylate. This metabolic pathway is an inviting target for the control of a number of diseases, because the enzymes involved in this cycle have been identified in many pathogens including Mycobacterium leprae and Leishmania. RESULTS: As part of a programme of rational drug design the structure of the tetrameric Aspergillus nidulans isocitrate lyase and its complex with glyoxylate and a divalent cation have been solved to 2.8 A resolution using X-ray diffraction. Each subunit comprises two domains, one of which adopts a folding pattern highly reminiscent of the triose phosphate isomerase (TIM) barrel. A 'knot' between subunits observed in the three-dimensional structure, involving residues towards the C terminus, implies that tetramer assembly involves considerable flexibility in this part of the protein. CONCLUSIONS: Difference Fourier analysis together with the pattern of sequence conservation has led to the identification of both the glyoxylate and metal binding sites and implicates the C-terminal end of the TIM barrel as the active site, which is consistent with studies of other enzymes with this fold. Two disordered regions of the polypeptide chain lie close to the active site, one of which includes a critical cysteine residue suggesting that conformational rearrangements are essential for catalysis. Structural similarities between isocitrate lyase and both PEP mutase and enzymes belonging to the enolase superfamily suggest possible relationships in aspects of the mechanism.     

Identification and characterization of NeuB3 from Campylobacter jejuni as a pseudaminic acid synthase

Campylobacter jejuni and Campylobacter coli are the main causes of bacterial diarrhea worldwide, and Helicobacter pylori is known to cause duodenal ulcers. In all of these pathogenic organisms, the flagellin proteins are heavily glycosylated with a 2-keto-3-deoxy acid, pseudaminic acid (5,7-diacetamido-3,5,7,9-tetradeoxy-L-glycero-L-manno-nonulosonic acid). The presence of pseudaminic acid is required for the proper development of the flagella and is thereby necessary for motility in, and invasion of, the host. In this study we report the first characterization of NeuB3 from C. jejuni as a pseudaminic acid synthase; the enzyme directly responsible for the biosynthesis of pseudaminic acid. Pseudaminic acid synthase catalyzes the condensation of phosphoenolpyruvate (PEP) with the hexose, 2,4-diacetamido-2,4,6-trideoxy-L-altrose (6-deoxy-AltdiNAc), to form pseudaminic acid and phosphate. The enzymatic activity was monitored using 1H and 31P NMR spectroscopy, and the product was isolated and characterized. Kinetic analysis reveals that pseudaminic acid synthase requires the presence of a divalent metal ion for catalysis and that optimal catalysis occurs at pH 7.0. A coupled enzymatic assay gave the values for k(cat) of 0.65 +/- 0.01 s(-1), K(m)PEP of 6.5 +/- 0.4 microM, and K(m)6-deoxy-AltdiNAc of 9.5 +/- 0.7 microM. A mechanistic study on pseudaminic acid synthase, using [2-18O]PEP, shows that catalysis proceeds through a C-O bond cleavage mechanism similar to other PEP condensing synthases such as sialic acid synthase.     

The TIM-barrel fold: a versatile framework for efficient enzymes

Recent studies on triosephosphate isomerase (TIM)-barrel enzymes highlight the remarkable versatility of the TIM-barrel scaffold. At least 15 distinct enzyme families use this framework to generate the appropriate active site geometry, always at the C-terminal end of the eight parallel beta-strands of the barrel. Sequence and structure comparisons now suggest that many of the TIM-barrel enzymes are evolutionarily related. Common structural properties of TIM-barrel enzymes are discussed.     

Three dimensional structure of porcine pancreatic alpha-amylase at 2.9 A resolution. Role of calcium in structure and activity.

The crystal structure of porcine pancreatic alpha-amylase (PPA) has been solved at 2.9 A resolution by X-ray crystallographic methods. The enzyme contains three domains. The larger, in the N-terminal part, consists of 330 amino acid residues. This central domain has the typical parallel-stranded alpha-beta barrel structure (alpha beta)8, already found in a number of other enzymes like triose phosphate isomerase and pyruvate kinase. The C-terminal domain forms a distinct globular unit where the chain folds into an eight-stranded antiparallel beta-barrel. The third domain lies between a beta-strand and a alpha-helix of the central domain, in a position similar to those found for domain B in triose phosphate isomerase and pyruvate kinase. It is essentially composed of antiparallel beta-sheets. The active site is located in a cleft within the N-terminal central domain, at the carboxy-end of the beta-strands of the (alpha beta)8 barrel. Binding of various substrate analogues to the enzyme suggests that the amino acid residues involved in the catalytic reaction are a pair of aspartic acids. A number of other residues surround the substrate and seem to participate in its binding via hydrogen bonds and hydrophobic interactions. The 'essential' calcium ion has been located near the active site region and between two domains, each of them providing two calcium ligands. On the basis of sequence comparisons this calcium binding site is suggested to be a common structural feature of all alpha-amylases. It represents a new type of calcium-protein interaction pattern.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structures of pyruvate phosphate dikinase from maize revealed an alternative conformation in the swiveling-domain motion

Pyruvate phosphate dikinase (PPDK) reversibly catalyzes the conversion of ATP, phosphate, and pyruvate into AMP, pyrophosphate, and phosphoenolpyruvate (PEP), respectively. Since the nucleotide binding site (in the N-terminal domain) and the pyruvate/PEP binding site (in the C-terminal domain) are separated by approximately 45 A, it has been proposed that an intermediary domain, called the central domain, swivels between these remote domains to transfer the phosphate. However, no direct structural evidence for the swiveling central domain has been found. In this study, the crystal structures of maize PPDK with and without PEP have been determined at 2.3 A resolution. These structures revealed that the central domain is located near the pyruvate/PEP binding C-terminal domain, in contrast to the PPDK from Clostridium symbiosum, wherein the central domain is located near the nucleotide-binding N-terminal domain. Structural comparisons between the maize and C. symbiosum PPDKs demonstrated that the swiveling motion of the central domain consists of a rotation of at least 92 degrees and a translation of 0.5 A. By comparing the maize PPDK structures with and without PEP, we have elucidated the mode of binding of PEP to the C-terminal domain and the induced conformational changes in the central domain.     

Comparison of backbone dynamics of the type III antifreeze protein and antifreeze-like domain of human sialic acid synthase

Antifreeze proteins (AFPs) are found in a variety of cold-adapted (psychrophilic) organisms to promote survival at subzero temperatures by binding to ice crystals and decreasing the freezing temperature of body fluids. The type III AFPs are small globular proteins that consist of one α-helix, three 3₁₀-helices, and two β-strands. Sialic acids play important roles in a variety of biological functions, such as development, recognition, and cell adhesion and are synthesized by conserved enzymatic pathways that include sialic acid synthase (SAS). SAS consists of an N-terminal catalytic domain and a C-terminal antifreeze-like (AFL) domain, which is similar to the type III AFPs. Despite having very similar structures, AFL and the type III AFPs exhibit very different temperature-dependent stability and activity. In this study, we have performed backbone dynamics analyses of a type III AFP (HPLC12 isoform) and the AFL domain of human SAS (hAFL) at various temperatures. We also characterized the structural/dynamic properties of the ice-binding surfaces by analyzing the temperature gradient of the amide proton chemical shift and its correlation with chemical shift deviation from random coil. The dynamic properties of the two proteins were very different from each other. While HPLC12 was mostly rigid with a few residues exhibiting slow motions, hAFL showed fast internal motions at low temperature. Our results provide insight into the molecular basis of thermostability and structural flexibility in homologous psychrophilic HPLC12 and mesophilic hAFL proteins.     

Enzyme I of the phosphotransferase system: induced-fit protonation of the reaction transition state by Cys-502

Enzyme I (EI), the first component of the phosphoenolpyruvate (PEP):sugar phosphotransferase system (PTS), consists of an N-terminal domain with the phosphorylation site (His-189) and a C-terminal domain with the PEP binding site. Here we use C3-substituted PEP analogues as substrates and inhibitors and the EI(C502A) mutant to characterize structure-activity relationships of the PEP binding site. EI(C502A) is 10 000 times less active than wild-type EI [EI(wt)] with PEP as the substrate, whereas the two forms are equally active with ZClPEP. Cys-502 acts as an acid-base catalyst which stereospecifically protonates the pyruvoyl enolate at C3. The electron-withdrawing chlorine of ZClPEP can compensate for the lack of Cys-502, and in this case, the released 3-Cl-enolate is protonated nonstereospecifically. Several PEP analogues were assayed as inhibitors and as substrates. The respective K(I)/K(m) ratios vary between 3 and 40 for EI(wt), but they are constant and around unity for EI(C502A). EI(wt) with PEP as the substrate is inhibited by oxalate, whereas EI(C502A) with ZClPEP is not. The different behavior of EI(wt) and EI(C502A) toward the PEP analogues and oxalate suggests that the PEP binding site of EI(wt) exists in a "closed" and an "open" form. The open to closed transition is triggered by the interaction of the substrate with Cys-502. The closed conformation is sterically disfavored by C3-modified substrate analogues such as ZClPEP and ZMePEP. If site closure does not occur as with EI(C502A) and bulky substrates, the transition state is stabilized by electron dispersion to the electron-withdrawing substituent at C3.     

Structure of the lysosomal sphingolipid activator protein 1 by homology with influenza virus neuraminidase

The sphingolipid activator protein 1 (SAP-1) increases the rate of hydrolysis of sphingolipids in the lysosome by apparently bringing together the substrate and the corresponding hydrolytic enzyme. This implies specific recognition of both the substrate and enzyme by SAP-1. However, binding domains in SAP-1 and recognition mechanisms involved are unknown. Amino acid sequence comparison of SAP-1 with influenza virus neuraminidase (EC 3.2.1.18, FLU NA) indicates that functional amino acid residues in or near the sialic acid binding site of FLU NA are also found at equivalent positions in the first 48 N-terminal amino acids of SAP-1. This region of homology allows to propose folding of the SAP-1 polypeptide chain by comparison with known crystallographic structure of FLU NA and identify a potential domain for lysosomal enzyme recognition through sialic acid binding. There is also a region of 10 amino acid residues near the C-terminal end of SAP-1 which has a strong propensity to form an alpha-helix with amphiphilic properties of lipid-binding helices. This domain in SAP-1 is probably responsible for the lipid(substrate)-binding function of SAP-1.     

Cytidine 5'-monophosphate (CMP)-induced structural changes in a multifunctional sialyltransferase from Pasteurella multocida

Sialyltransferases catalyze reactions that transfer a sialic acid from CMP-sialic acid to an acceptor (a structure terminated with galactose, N-acetylgalactosamine, or sialic acid). They are key enzymes that catalyze the synthesis of sialic acid-containing oligosaccharides, polysaccharides, and glycoconjugates that play pivotal roles in many critical physiological and pathological processes. The structures of a truncated multifunctional Pasteurella multocida sialyltransferase (Delta24PmST1), in the absence and presence of CMP, have been determined by X-ray crystallography at 1.65 and 2.0 A resolutions, respectively. The Delta24PmST1 exists as a monomer in solution and in crystals. Different from the reported crystal structure of a bifunctional sialyltransferase CstII that has only one Rossmann domain, the overall structure of the Delta24PmST1 consists of two separate Rossmann nucleotide-binding domains. The Delta24PmST1 structure, thus, represents the first sialyltransferase structure that belongs to the glycosyltransferase-B (GT-B) structural group. Unlike all other known GT-B structures, however, there is no C-terminal extension that interacts with the N-terminal domain in the Delta24PmST1 structure. The CMP binding site is located in the deep cleft between the two Rossmann domains. Nevertheless, the CMP only forms interactions with residues in the C-terminal domain. The binding of CMP to the protein causes a large closure movement of the N-terminal Rossmann domain toward the C-terminal nucleotide-binding domain. Ser 143 of the N-terminal domain moves up to hydrogen-bond to Tyr 388 of the C-terminal domain. Both Ser 143 and Tyr 388 form hydrogen bonds to a water molecule, which in turn hydrogen-bonds to the terminal phosphate oxygen of CMP. These interactions may trigger the closure between the two domains. Additionally, a short helix near the active site seen in the apo structure becomes disordered upon binding to CMP. This helix may swing down upon binding to donor CMP-sialic acid to form the binding pocket for an acceptor.     

Insights into enzyme evolution revealed by the structure of methylaspartate ammonia lyase.

Methylaspartate ammonia lyase (MAL) catalyzes the magnesium-dependent reversible alpha,beta-elimination of ammonia from L-threo-(2S,3S)-3-methylaspartic acid to mesaconic acid. The 1.3 A MAD crystal structure of the dimeric Citrobacter amalonaticus MAL shows that each subunit comprises two domains, one of which adopts the classical TIM barrel fold, with the active site at the C-terminal end of the barrel. Despite very low sequence similarity, the structure of MAL is closely related to those of representative members of the enolase superfamily, indicating that the mechanism of MAL involves the initial abstraction of a proton alpha to the 3-carboxyl of (2S,3S)-3-methylasparic acid to yield an enolic intermediate. This analysis resolves the conflict that had linked MAL to the histidine and phenylalanine ammonia lyase family of enzymes.     

Structure of the Ulster Strain Newcastle Disease Virus Hemagglutinin-Neuraminidase Reveals Auto-Inhibitory Interactions Associated with Low Virulence

Paramyxovirus hemagglutinin-neuraminidase (HN) plays roles in viral entry and maturation, including binding to sialic acid receptors, activation of the F protein to drive membrane fusion, and enabling virion release during virus budding. HN can thereby directly influence virulence and in a subset of avirulent Newcastle disease virus (NDV) strains, such as NDV Ulster, HN must be proteolytically activated to remove a C-terminal extension not found in other NDV HN proteins. Ulster HN is 616 amino acids long and the 45 amino acid C-terminal extension present in its precursor (HN₀) form has to be cleaved to render HN biologically active. Here we show that Ulster HN contains an inter-subunit disulfide bond within the C-terminal extension at residue 596, which regulates HN activities and neuraminidase (NA) domain dimerization. We determined the crystal structure of the dimerized NA domain containing the C-terminal extension, which extends along the outside of the sialidase β-propeller domain and inserts C-terminal residues into the NA domain active site. The C-terminal extension also engages a secondary sialic acid binding site present in NDV HN proteins, which is located at the NA domain dimer interface, that most likely blocks its attachment function. These results clarify how the Ulster HN C-terminal residues lead to an auto-inhibited state of HN, the requirement for proteolytic activation of HN₀ and associated reduced virulence.