Mechanism of substrate recognition and PLP-induced conformational changes in LL-diaminopimelate aminotransferase from Arabidopsis thaliana

LL-Diaminopimelate aminotransferase (LL-DAP-AT), a pyridoxal phosphate (PLP)-dependent enzyme in the lysine biosynthetic pathways of plants and Chlamydia, is a potential target for the development of herbicides or antibiotics. This homodimeric enzyme converts L-tetrahydrodipicolinic acid (THDP) directly to LL-DAP using L-glutamate as the source of the amino group. Earlier, we described the 3D structures of native and malate-bound LL-DAP-AT from Arabidopsis thaliana (AtDAP-AT). Seven additional crystal structures of AtDAP-AT and its variants are reported here as part of an investigation into the mechanism of substrate recognition and catalysis. Two structures are of AtDAP-AT with reduced external aldimine analogues: N-(5'-phosphopyridoxyl)-L-glutamate (PLP-Glu) and N-(5'-phosphopyridoxyl)- LL-Diaminopimelate (PLP-DAP) bound in the active site. Surprisingly, they reveal that both L-glutamate and LL-DAP are recognized in a very similar fashion by the same sets of amino acid residues; both molecules adopt twisted V-shaped conformations. With both substrates, the alpha-carboxylates are bound in a salt bridge with Arg404, whereas the distal carboxylates are recognized via hydrogen bonds to the well-conserved side chains of Tyr37, Tyr125 and Lys129. The distal C(epsilon) amino group of LL-DAP is specifically recognized by several non-covalent interactions with residues from the other subunit (Asn309*, Tyr94*, Gly95*, and Glu97* (Amino acid designators followed by an asterisk (*) indicate that the residues originate in the other subunit of the dimer)) and by three bound water molecules. Two catalytically inactive variants of AtDAP-AT were created via site-directed mutagenesis of the active site lysine (K270N and K270Q). The structures of these variants permitted the observation of the unreduced external aldimines of PLP with L-glutamate and with LL-DAP in the active site, and revealed differences in the torsion angle about the PLP-substrate bond. Lastly, an apo-AtDAP-AT structure missing PLP revealed details of conformational changes induced by PLP binding and substrate entry into the active site.     

Structural and functional characterization of enantiomeric glutamic acid derivatives as potential transition state analogue inhibitors of MurD ligase

Mur ligases play an essential role in the intracellular biosynthesis of bacterial peptidoglycan, the main component of the bacterial cell wall, and represent attractive targets for the design of novel antibacterials. UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase (MurD) catalyses the addition of D-glutamic acid to the cytoplasmic intermediate UDP-N-acetylmuramoyl-L-alanine (UMA) and is the second in the series of Mur ligases. MurD ligase is highly stereospecific for its substrate, D-glutamic acid (D-Glu). Here, we report the high resolution crystal structures of MurD in complexes with two novel inhibitors designed to mimic the transition state of the reaction, which contain either the D-Glu or the L-Glu moiety. The binding modes of N-sulfonyl-D-Glu and N-sulfonyl-L-Glu derivatives were also characterised kinetically. The results of this study represent an excellent starting point for further development of novel inhibitors of this enzyme.     

A novel glycoside hydrolase family 105: the structure of family 105 unsaturated rhamnogalacturonyl hydrolase complexed with a disaccharide in comparison with family 88 enzyme complexed with the disaccharide

YteR, a hypothetical protein with unknown functions, is derived from Bacillus subtilis strain 168 and has an overall structure similar to that of bacterial unsaturated glucuronyl hydrolase (UGL), although it exhibits little amino acid sequence identity with UGL. UGL releases unsaturated glucuronic acid from glycosaminoglycan treated with glycosaminoglycan lyases. The amino acid sequence of YteR shows a significant homology (26% identity) with the hypothetical protein YesR also from B. subtilis strain 168. To clarify the intrinsic functions of YteR and YesR, both proteins were overexpressed in Escherichia coli, purified, and characterized. Based on their gene arrangements in genome and enzyme properties, YteR and YesR were found to constitute a novel enzyme activity, "unsaturated rhamnogalacturonyl hydrolase," classified as new glycoside hydrolase family 105. This enzyme acts specifically on unsaturated rhamnogalacturonan (RG) obtained from RG type-I treated with RG lyases and releases an unsaturated galacturonic acid. The crystal structure of YteR complexed with unsaturated chondroitin disaccharide (UGL substrate) was obtained and compared to the structure of UGL complexed with the same disaccharide. The UGL substrate is sterically hindered with the active pocket of YteR. The protruding loop of YteR prevents the UGL substrate from being bound effectively. The most likely candidate catalytic residues for general acid/base are Asp143 in YteR and Asp135 in YesR. This is supported by three-dimensional structural and site-directed mutagenesis studies. These findings provide molecular insights into novel enzyme catalysis and sequential reaction mechanisms involved in RG-I depolymerization by bacteria.     

Comparison of wild type neuronal nitric oxide synthase and its Tyr588Phe mutant towards various l-arginine analogues

Crystal structures of nitric oxide synthases (NOS) isoforms have shown the presence of a strongly conserved heme active-site residue, Tyr588 (numbering for rat neuronal NOS, nNOS). Preliminary biochemical studies have highlighted its importance in the binding and oxidation to NO of natural substrates L-Arg and N^ω-hydroxy-l-arginine (NOHA) and suggested its involvement in mechanism. We have used UV-visible and EPR spectroscopy to investigate the effects of the Tyr588 to Phe mutation on the heme-distal environment, on the binding of a large series of guanidines and N-hydroxyguanidines that differ from L-Arg and NOHA by the nature of their alkyl- or aryl-side chain, and on the abilities of wild type (WT) and mutant to oxidize these analogues with formation of NO. Our EPR experiments show that the heme environment of the Tyr588Phe mutant differs from that of WT nNOS. However, the addition of L-Arg to this mutant results in EPR spectra similar to that of WT nNOS. Tyr588Phe mutant binds L-Arg and NOHA with much weaker affinities than WT nNOS but both proteins bind non α-amino acid guanidines and N-hydroxyguanidines with close affinities. WT nNOS and mutant do not form NO from the tested guanidines but oxidize several N-hydroxyguanidines with formation of NO in almost identical rates. Our results show that the Tyr588Phe mutation induces structural modifications of the H-bonds network in the heme-distal site that alter the reactivity of the heme. They support recent spectroscopic and mechanistic studies that involve two distinct heme-based active species in the two steps of NOS mechanism.     

A structural basis for substrate selectivity and stereoselectivity in octopine dehydrogenase from Pecten maximus

Octopine dehydrogenase [N²-(d-1-carboxyethyl)-l-arginine:NAD⁺ oxidoreductase] (OcDH) from the adductor muscle of the great scallop Pecten maximus catalyzes the reductive condensation of l-arginine and pyruvate to octopine during escape swimming. This enzyme, which is a prototype of opine dehydrogenases (OpDHs), oxidizes glycolytically born NADH to NAD⁺, thus sustaining anaerobic ATP provision during short periods of strenuous muscular activity. In contrast to some other OpDHs, OcDH uses only l-arginine as the amino acid substrate. Here, we report the crystal structures of OcDH in complex with NADH and the binary complexes NADH/l-arginine and NADH/pyruvate, providing detailed information about the principles of substrate recognition, ligand binding and the reaction mechanism. OcDH binds its substrates through a combination of electrostatic forces and size selection, which guarantees that OcDH catalysis proceeds with substrate selectivity and stereoselectivity, giving rise to a second chiral center and exploiting a “molecular ruler” mechanism.     

Methylation of the guanidino group of arginine residues prevents citrullination by peptidylarginine deiminase IV

Peptidylarginine deiminase IV (PAD IV) catalyzes the citrullination of Arg residues of proteins, such as histones. Suzuki et al. recently reported that haplotypes of the PAD IV gene are associated with susceptibility to rheumatoid arthritis. To investigate the mechanism of substrate specificity and inhibitors of PAD IV, a series of the Arg derivatives were synthesized and their reactivity to PAD IV examined. The results suggest that both imino and carboxyl groups are important in the molecular recognition of PAD IV and that methylation of the guanidino group prevents citrullination. In addition, the findings herein show that Bz-N(G)-monomethyl-Arg and Bz-N(G),N(G)-dimethyl-Arg specifically inhibit citrullination.     

Reduction of Nomega-hydroxy-L-arginine to L-arginine by pig liver microsomes, mitochondria, and human liver microsomes

Nomega-Hydroxy-L-arginine, the intermediate in nitric oxide formation from L-arginine catalyzed by NO synthase, can be released into the extracellular space. It has been suggested that it can circulate and exert paracrine effects. Since it cannot only be used as substrate by NO synthases, but can also be oxidized by cytochrome P450 and other hemoproteins in a superoxide-dependent manner, it has been proposed that it can serve as NO donor. In the present study, the in vitro reduction of Nomega-hydroxy-L-arginine was examined. Pig and human liver microsomes as well as pig liver mitochondria were capable of reducing Nomega-hydroxy-L-arginine to L-arginine in an oxygen-insensitive enzymatic reaction. These results demonstrate that this metabolic pathway has to be considered when suggesting Nomega-hydroxy-L-arginine as NO-precursor. The reconstituted liver microsomal system of a pig liver CYP2D enzyme, the benzamidoxime reductase, was unable to replace microsomes to produce L-arginine from Nomega-hydroxy-L-arginine.     

A study of l-leucine, l-phenylalanine and l-alanine transport in the perfused rat mammary gland: possible involvement of LAT1 and LAT2

The transport of l-leucine, l-phenylalanine and l-alanine by the perfused lactating rat mammary gland has been examined using a rapid, paired-tracer dilution technique. The clearances of all three amino acids by the mammary gland consisted of a rising phase followed by a rapid fall-off, respectively, reflecting influx and efflux of the radiotracers. The peak clearance of l-leucine was inhibited by BCH (65%) and d-leucine (58%) but not by l-proline. The inhibition of l-leucine clearance by BCH and d-leucine was not additive. l-leucine inhibited the peak clearance of radiolabelled l-leucine by 78%. BCH also inhibited the peak clearance of l-phenylalanine (66%) and l-alanine (33%) by the perfused mammary gland. Lactating rat mammary tissue was found to express both LAT1 and LAT2 mRNA. The results suggest that system L is situated in the basolateral aspect of the lactating rat mammary epithelium and thus probably plays a central role in neutral amino acid uptake from blood. The finding that l-alanine uptake by the gland was inhibited by BCH suggests that LAT2 may make a significant contribution to neutral amino acid uptake by the mammary epithelium.     

Synthesis and intramolecular reactions of Tyr-Gly and Tyr-Gly-Gly related 6-O-glucopyranose esters

6-O-(L-Tyrosylglycyl)- and 6-O-(L-tyrosylglycylglycyl)-D-glucopyranose were synthesized by condensation of the pentachlorophenyl esters of the respective di- and tripeptide with fully unprotected D-glucose. The intramolecular reactivity of the sugar conjugates was studied in pyridine-acetic acid and in dry methanol, at various temperatures and for various incubation times. The composition of the incubation mixtures was monitored by a reversed-phase HPLC method that permits simultaneous analysis of the disappearance of the starting material and the appearance of rearrangement and degradation products. To determine the influence of esterification of the peptide carboxy group on its amino group reactivity, parallel experiments were done in which free peptides were, under identical reaction conditions, incubated with D-glucose (molar ratios 1:1 and 1:5). Depending on the starting compound, different types of Amadori products (cyclic and bicyclic form), methyl ester of peptides, and Tyr-Gly-diketopiperazine were obtained.     

Purification,characterization, and gene cloning of a novel aminoacylase from Burkholderia sp. strain LP5_18B that efficiently catalyzes the synthesis of N-lauroyl-l-amino acids

ABSTRACT

An N-lauroyl-l-phenylalanine-producing bacterium, identified as Burkholderia sp. strain LP5_18B, was isolated from a soil sample. The enzyme was purified from the cell-free extract of the strain and shown to catalyze degradation and synthesis activities toward various N-acyl-amino acids. N-lauroyl-l-phenylalanine and N-lauroyl-l-arginine were obtained with especially high yields (51% and 89%, respectively) from lauric acid and l-phenylalanine or l-arginine by the purified enzyme in an aqueous system. The gene encoding the novel aminoacylase was cloned from Burkholderia sp. strain LP5_18B and expressed in Escherichia coli. The gene contains an open reading frame of 1,323 nucleotides. The deduced protein sequence encoded by the gene has approximately 80% amino acid identity to several hydratase of Burkholderia. The addition of zinc sulfate increased the aminoacylase activity of the recombinant E. coli strain.     

Dipeptide synthesis by L-amino acid ligase from Ralstonia solanacearum

Despite its utility, dipeptides have not been widely used due to the absence of an efficient manufacturing method. Recently, a novel method for effective production of dipeptides using l-amino acid α-ligase (Lal) is presented. Lal, which is only identified in Bacillus subtilis, catalyzes dipeptide synthesis from unprotected amino acids in an ATP-dependent manner. However, not all the dipeptide can be synthesized by Lal from B. subtilis (BsLal) due to its substrate specificity. Here, we attempted to find a novel Lal exhibiting different substrate specificity from BsLal. By in silico screening based on the amino acid sequence of BsLal, RSp1486a an unknown protein from Ralstonia solanacearum was found to show the Lal activity. RSp1486a exhibited different substrate specificity from BsLal, and preferably synthesized hetero-dipeptides where more bulky amino acid was placed at N terminus and less bulky amino acid was placed at C terminus in opposition to those synthesized by BsLal.     

Structural Basis for Catalysis by the Mono- and Dimetalated Forms of the dapE-Encoded N-succinyl-l,l-Diaminopimelic Acid Desuccinylase

Biosynthesis of lysine and meso-diaminopimelic acid in bacteria provides essential components for protein synthesis and construction of the bacterial peptidoglycan cell wall. The dapE operon enzymes synthesize both meso-diaminopimelic acid and lysine and, therefore, represent potential targets for novel antibacterials. The dapE-encoded N-succinyl-l,l-diaminopimelic acid desuccinylase functions in a late step of the pathway and converts N-succinyl-l,l-diaminopimelic acid to l,l-diaminopimelic acid and succinate. Deletion of the dapE gene is lethal to Helicobacter pylori and Mycobacterium smegmatis, indicating that DapE's are essential for cell growth and proliferation. Since there are no similar pathways in humans, inhibitors that target DapE may have selective toxicity against only bacteria. A major limitation in developing antimicrobial agents that target DapE has been the lack of structural information. Herein, we report the high-resolution X-ray crystal structures of the DapE from Haemophilus influenzae with one and two zinc ions bound in the active site, respectively. These two forms show different activity. Based on these newly determined structures, we propose a revised catalytic mechanism of peptide bond cleavage by DapE enzymes. These structures provide important insight into catalytic mechanism of DapE enzymes as well as a structural foundation that is critical for the rational design of DapE inhibitors.     

Multiple incorporation of non-natural amino acids into a single protein using tRNAs with non-standard structures

The ability to introduce non-natural amino acids into proteins opens up new vistas for the study of protein structure and function. This approach requires suppressor tRNAs that deliver the non-natural amino acid to a ribosome associated with an mRNA containing an expanded codon. The suppressor tRNAs must be absolutely protected from aminoacylation by any of the aminoacyl-tRNA synthetases in the protein synthesizing system, or a natural amino acid will be incorporated instead of the non-natural amino acid. Here, we found that some tRNAs with non-standard structures could work as efficient four-base suppressors fulfilling the above orthogonal conditions. Using these tRNAs, we successfully demonstrated incorporation of three different non-natural amino acids into a single protein.     

Recognition of Non-α-amino Substrates by Pyrrolysyl-tRNA Synthetase

Pyrrolysyl-tRNA synthetase (PylRS), an aminoacyl-tRNA synthetase (aaRS) recently found in some methanogenic archaea and bacteria, recognizes an unusually large lysine derivative, l-pyrrolysine, as the substrate, and attaches it to the cognate tRNA (tRNA^Pyl). The PylRS-tRNA^Pyl pair interacts with none of the endogenous aaRS-tRNA pairs in Escherichia coli, and thus can be used as a novel aaRS-tRNA pair for genetic code expansion. The crystal structures of the Methanosarcina mazei PylRS revealed that it has a unique, large pocket for amino acid binding, and the wild type M. mazei PylRS recognizes the natural lysine derivative as well as many lysine analogs, including N^?-(tert-butoxycarbonyl)-l-lysine (Boc-lysine), with diverse side chain sizes and structures. Moreover, the PylRS only loosely recognizes the α-amino group of the substrate, whereas most aaRSs, including the structurally and genetically related phenylalanyl-tRNA synthetase (PheRS), strictly recognize the main chain groups of the substrate. We report here that wild type PylRS can recognize substrates with a variety of main-chain α-groups: α-hydroxyacid, non-α-amino-carboxylic acid, N_α-methyl-amino acid, and d-amino acid, each with the same side chain as that of Boc-lysine. In contrast, PheRS recognizes none of these amino acid analogs. By expressing the wild type PylRS and its cognate tRNA^Pyl in E. coli in the presence of the α-hydroxyacid analog of Boc-lysine (Boc-LysOH), the amber codon (UAG) was recoded successfully as Boc-LysOH, and thus an ester bond was site-specifically incorporated into a protein molecule. This PylRS-tRNA^Pyl pair is expected to expand the backbone diversity of protein molecules produced by both in vivo and in vitro ribosomal translation.     

A highly specific glyoxylate reductase derived from a formate dehydrogenase

A Glu141Asn mutant Paracoccus sp. 12-A formate dehydrogenase catalyzes marked glyoxylate reduction. Additional replacement of the His332-Gln313 pair with His-Glu, which is a consensus acid/base catalyst in D-hydroxyacid dehydrogenases, further improved the catalytic activity of the enzyme as to glyoxylate reduction through enhancement of the hydrogen transfer step in the catalytic process, slightly shifting the optimal pH for the reaction. On the other hand, the replacement induced no marked activity toward other 2-ketoacid substrates, and diminished the enzyme activity as to formate oxidation. Consequently, the formate dehydrogenase was converted to a highly specific and active glyoxylate reductase through only the two amino acid replacements.     

Synthesis of D- and L-myo-inositol 2,4,5-trisphosphate and trisphosphorothioate: structural analogues of D-myo-inositol 1,4,5-trisphosphate

The preparation of D- and L-myo-inositol 2,4,5-trisphosphate is described, together with the phosphorothioate counterparts. The known chiral diols D- and L-1,4-di-O-benzyl-5,6-bis-O-p-methoxybenzyl-myo-inositol were regioselectively protected at the 3-position using a benzyl group via a 2,3-O-stannylene acetal. Removal of the p-methoxybenzyl groups of each enantiomer gave D- and L-1,3,6-tri-O-benzyl-myo-inositol. Phosphitylation with bis(benzyloxy)diisoproplyaminophosphine and 1H-tetrazole gave the trisphosphite intermediate for each enantiomer. Oxidation with 3-chloroperoxybenzoic acid gave the fully protected D- and L-myo-inositol 2,4,5-trisphosphates. Sulphoxidation of the D- and L-2,4,5-trisphosphite intermediates gave the fully protected D- and L-myo-inositol 2,4,5-trisphosphorothioate compounds. The fully protected trisphosphates were deblocked using hydrogenolysis and the phosphorothioates were deprotected using sodium in liquid ammonia. The individual compounds were then purified using ion exchange chromatography to afford pure D- and L-myo-inositol 2,4,5-trisphosphates together with the corresponding phosphorothioates.     

Dual roles of a conserved pair, Arg23 and Ser20, in recognition of multiple substrates in α-aminoadipate aminotransferase from Thermus thermophilus

To clarify the mechanism for substrate recognition of α-aminoadipate aminotransferase (AAA-AT) from Thermus thermophilus, the crystal structure of AAA-AT complexed with N-(5′-phosphopyridoxyl)-l-glutamate (PPE) was determined at 1.67 Å resolution. The crystal structure revealed that PPE is recognized by amino acid residues the same as those seen in N-(5′-phosphopyridoxyl)-l-α-aminoadipate (PPA) recognition; however, to bind the γ-carboxyl group of Glu at a fixed position, the Cα atom of the Glu moiety moves 0.80 Å toward the γ-carboxyl group in the PPE complex. Markedly decreased activity for Asp can be explained by the shortness of the aspartyl side chain to be recognized by Arg23 and further dislocation of the Cα atom of bound Asp. Site-directed mutagenesis revealed that Arg23 has dual functions for reaction, (i) recognition of γ (δ)-carboxyl group of Glu (AAA) and (ii) rearrangement of α2 helix by changing the interacting partners to place the hydrophobic substrate at the suitable position.     

The structure of a bacterial L-amino acid oxidase from Rhodococcus opacus gives new evidence for the hydride mechanism for dehydrogenation

l-Amino acid oxidase from Rhodococcus opacus (roLAAO) is classified as a member of the GR(2)-family of flavin-dependent oxidoreductases according to a highly conserved sequence motif for the cofactor binding. The monomer of the homodimeric enzyme consists of three well-defined domains: the FAD-binding domain corresponding to a general topology throughout the whole GR(2)-family; a substrate-binding domain with almost the same topology as the snake venom LAAO and a helical domain exclusively responsible for the unusual dimerisation mode of the enzyme and not found in other members of the family so far. We describe here high-resolution structures of the binary complex of protein and cofactor as well as the ternary complexes of protein, cofactor and ligands. This structures in addition to the structural knowledge of snake venom LAAO and DAAO from yeast and pig kidney permit more insight into different steps in the reaction mechanism of this class of enzymes. There is strong evidence for hydride transfer as the mechanism of dehydrogenation. This mechanism appears to be uncommon in a sense that the chemical transformation can proceed efficiently without the involvement of amino acid functional groups. Most groups present at the active site are involved in substrate recognition, binding and fixation, i.e. they direct the trajectory of the interacting orbitals. In this mode of catalysis orbital steering/interactions are the predominant factors for the chemical step(s). A mirror-symmetrical relationship between the two substrate-binding sites of d and l-amino acid oxidases is observed which facilitates enantiomeric selectivity while preserving a common arrangement of the residues in the active site. These results are of general relevance for the mechanism of flavoproteins and lead to the proposal of a common dehydrogenation step in the mechanism for l and d-amino acid oxidases.     

Achacin induces cell death in HeLa cells through two different mechanisms

Achacin, which belongs to the L-amino acid oxidase group, oxidizes free amino acids and produces hydrogen peroxide in cell culture systems. Morphological changes in cells incubated with achacin were similar to those of cells incubated with H(2)O(2). In both cases, the end result was cell death. To examine the mechanism of achacin-associated cytotoxicity, the H(2)O(2) scavenger catalase was added to culture media. Features typical of apoptosis, including morphological changes, DNA fragmentation, and PARP cleavage, were observed when cells were incubated with achacin in the presence of catalase. Moreover, apoptosis was inhibited by Z-VAD-fmk, a broad-spectrum caspase inhibitor. Herein, we present evidence that two pathways are involved in achacin-induced cell death. One is direct generation of H(2)O(2) through the L-amino acid oxidase activity of achacin. The other is the caspase-mediated apoptotic pathway that is induced by depletion of L-amino acids by achacin.     

alpha-D-Glucuronosyl-(1-->3)-L-galactose,an unusual disaccharide from polysaccharides of the hornwort Anthoceros caucasicus

Acid hydrolysis of cell wall-rich material from thalli of the hornwort Anthoceros caucasicus yielded substantial amounts of an unusual disaccharide (1). Hydrolysis of 1 yielded only GlcA, Gal and unhydrolysed 1. Compound 1 was identified as alpha-D-GlcpA-(1-->3)-L-Gal by 1H and 13C NMR spectroscopic analysis and by the susceptibility of its monosaccharide units to phosphorylation by enantiomer-specific kinases. Compound 1 was not detected in acid hydrolysates of other land plants including mosses, leafy and thalloid liverworts, lycopodiophytes and euphyllophytes; it was also absent from charophytes. The Anthoceros polysaccharide that yields 1 was partially extractable in cold aqueous buffer (pH 4.7) and Na(2)CO(3), but not in EDTA or NaOH, suggesting that it was not a typical pectin or hemicellulose. The yield of 1 from various polysaccharide fractions correlated with the yields of Xyl, suggesting a previously unreported polymer containing D-GlcA, L-Gal and Xyl. The existence of a unique polysaccharide in an evolutionarily isolated plant (Anthoceros) supports the view that major steps in plant phylogeny were accompanied by significant changes in cell wall composition.