Crystal structure of the archaeosine synthase QueF‐like—Insights into amidino transfer and tRNA recognition by the tunnel fold

The tunneling‐fold (T‐fold) structural superfamily has emerged as a versatile protein scaffold of diverse catalytic activities. This is especially evident in the pathways to the 7‐deazaguanosine modified nucleosides of tRNA queuosine and archaeosine. Four members of the T‐fold superfamily have been confirmed in these pathways and here we report the crystal structure of a fifth enzyme; the recently discovered amidinotransferase QueF‐Like (QueF‐L), responsible for the final step in the biosynthesis of archaeosine in the D‐loop of tRNA in a subset of Crenarchaeota. QueF‐L catalyzes the conversion of the nitrile group of the 7‐cyano‐7‐deazaguanine (preQ₀) base of preQ₀‐modified tRNA to a formamidino group. The structure, determined in the presence of preQ₀, reveals a symmetric T‐fold homodecamer of two head‐to‐head facing pentameric subunits, with 10 active sites at the inter‐monomer interfaces. Bound preQ₀ forms a stable covalent thioimide bond with a conserved active site cysteine similar to the intermediate previously observed in the nitrile reductase QueF. Despite distinct catalytic functions, phylogenetic distributions, and only 19% sequence identity, the two enzymes share a common preQ₀ binding pocket, and likely a common mechanism of thioimide formation. However, due to tight twisting of its decamer, QueF‐L lacks the NADPH binding site present in QueF. A large positively charged molecular surface and a docking model suggest simultaneous binding of multiple tRNA molecules and structure‐specific recognition of the D‐loop by a surface groove. The structure sheds light on the mechanism of nitrile amidation, and the evolution of diverse chemistries in a common fold. Proteins 2016; 85:103–116. © 2016 Wiley Periodicals, Inc.     

Purification of glutathione S‐transferase enzyme from quail liver tissue and inhibition effects of (3aR,4S,7R,7aS)‐2‐(4‐((E)‐3‐(aryl)acryloyl)phenyl)‐3a,4,7,7a‐tetrahydro‐1H‐4,7‐methanoisoindole‐1,3(2H)‐dione derivatives on the enzyme activity

The use of quail meat and eggs has made this animal important in recent years, with its low cost and high yields. Glutathione S‐transferases (GST, E.C.2.5.1.18) are an important enzyme family, which play a critical role in detoxification system. In our study, GST was purified from quail liver tissue with 47.88‐fold purification and 12.33% recovery by glutathione agarose affinity chromatography. The purity of enzyme was checked by SDS‐PAGE method and showed a single band. In addition, inhibition effects of (3aR,4S,7R,7aS)‐2‐(4‐((E)‐3‐(aryl)acryloyl)phenyl)‐3a,4,7,7a‐tetrahydro‐1H‐4,7methanoisoindole‐1,3(2H)‐dion derivatives ( 1a–g ) were investigated on the enzyme activity. The inhibition parameters (IC₅₀ and K_i values) were calculated for these compounds. IC₅₀ values of these derivatives ( 1a–e ) were found as 23.00, 15.75, 115.50, 10.00, and 28.75 μM, respectively. K_i values of these derivatives ( 1a–e ) were calculated in the range of 3.04 ± 0.50 to 131.50 ± 32.50 μM. However, for f and g compounds, the inhibition effects on the enzyme were not found.     

Förster resonance energy transfer measurements of cofactor‐dependent effects on protein arginine N‐methyltransferase homodimerization

Protein arginine N‐methyltransferase (PRMT) dimerization is required for methyl group transfer from the cofactor S‐adenosyl‐L ‐methionine (AdoMet) to arginine residues in protein substrates, forming S‐adenosyl‐L ‐homocysteine (AdoHcy) and methylarginine residues. In this study, we use Förster resonance energy transfer (FRET) to determine dissociation constant (K_D) values for dimerization of PRMT1 and PRMT6. By attaching monomeric Cerulean and Citrine fluorescent proteins to their N‐termini, fluorescent PRMTs are formed that exhibit similar enzyme kinetics to unconjugated PRMTs. These fluorescent proteins are used in FRET‐based binding studies in a multi‐well format. In the presence of AdoMet, fluorescent PRMT1 and PRMT6 exhibit 4‐ and 6‐fold lower dimerization K_D values, respectively, than in the presence of AdoHcy, suggesting that AdoMet promotes PRMT homodimerization in contrast to AdoHcy. We also find that the dimerization K_D values for PRMT1 in the presence of AdoMet or AdoHcy are, respectively, 6‐ and 10‐fold lower than the corresponding values for PRMT6. Considering that the affinity of PRMT6 for AdoHcy is 10‐fold higher than for AdoMet, PRMT6 function may be subject to cofactor‐dependent regulation in cells where the methylation potential (i.e., ratio of AdoMet to AdoHcy) is low. Since PRMT1 affinity for AdoMet and AdoHcy is similar, however, a low methylation potential may not affect PRMT1 function.     

Crystal structure of D‐glycero‐Β‐D‐manno‐heptose‐1‐phosphate adenylyltransferase from Burkholderia pseudomallei

The crystal structure of HldC from B. pseudomallei (BpHldC), the fourth enzyme of the heptose biosynthesis pathway, has been determined. BpHldC converts ATP and d ‐glycero‐β‐d ‐manno‐heptose‐1‐phosphate into ADP‐d ‐glycero‐β‐d ‐manno‐heptose and pyrophosphate. The crystal structure of BpHldC belongs to the nucleotidyltransferase α/β phosphodiesterase superfamily sharing a common Rossmann‐like α/β fold with a conserved T/HXGH sequence motif. The invariant catalytic key residues of BpHldC indicate that the core catalytic mechanism of BpHldC may be similar to that of other closest homologues. Intriguingly, a reorientation of the C‐terminal helix seems to guide open and close states of the active site for the catalytic reaction.     

SPASM and Twitch Domains in S-Adenosylmethionine (SAM) Radical Enzymes

S-Adenosylmethionine (SAM, also known as AdoMet) radical enzymes use SAM and a [4Fe-4S] cluster to catalyze a diverse array of reactions. They adopt a partial triose-phosphate isomerase (TIM) barrel fold with N- and C-terminal extensions that tailor the structure of the enzyme to its specific function. One extension, termed a SPASM domain, binds two auxiliary [4Fe-4S] clusters and is present within peptide-modifying enzymes. The first structure of a SPASM-containing enzyme, anaerobic sulfatase-maturating enzyme (anSME), revealed unexpected similarities to two non-SPASM proteins, butirosin biosynthetic enzyme 2-deoxy-scyllo-inosamine dehydrogenase (BtrN) and molybdenum cofactor biosynthetic enzyme (MoaA). The latter two enzymes bind one auxiliary cluster and exhibit a partial SPASM motif, coined a Twitch domain. Here we review the structure and function of auxiliary cluster domains within the SAM radical enzyme superfamily.     

Ferredoxins as interchangeable redox components in support of MiaB,a radical S‐adenosylmethionine methylthiotransferase

MiaB is a member of the methylthiotransferase subclass of the radical S‐adenosylmethionine (SAM) superfamily of enzymes, catalyzing the methylthiolation of C2 of adenosines bearing an N⁶‐isopentenyl (i⁶A) group found at position 37 in several tRNAs to afford 2‐methylthio‐N⁶‐(isopentenyl)adenosine (ms²i⁶A). MiaB uses a reduced [4Fe–4S]⁺ cluster to catalyze a reductive cleavage of SAM to generate a 5′‐deoxyadenosyl 5′‐radical (5′‐dA?)—a required intermediate in its reaction—as well as an additional [4Fe–4S]²⁺ auxiliary cluster. In Escherichia coli and many other organisms, re‐reduction of the [4Fe–4S]²⁺ cluster to the [4Fe–4S]⁺ state is accomplished by the flavodoxin reducing system. Most mechanistic studies of MiaBs have been carried out on the enzyme from Thermotoga maritima (Tm), which lacks the flavodoxin reducing system, and which is not activated by E. coli flavodoxin. However, the genome of this organism encodes five ferredoxins (TM0927, TM1175, TM1289, TM1533, and TM1815), each of which might donate the requisite electron to MiaB and perhaps to other radical SAM enzymes. The genes encoding each of these ferredoxins were cloned, and the associated proteins were isolated and shown to support turnover by Tm MiaB. In addition, TM1639, the ferredoxin‐NADP⁺ oxidoreductase subunit α (NfnA) from Tm was overproduced and isolated and shown to provide electrons to the Tm ferredoxins during Tm MiaB turnover. The resulting reactions demonstrate improved coupling between formation of the 5′‐dA? and ms²i⁶A production, indicating that only one hydrogen atom abstraction is required for the reaction.     

Conformational transitions driven by pyridoxal‐5′‐phosphate uptake in the psychrophilic serine hydroxymethyltransferase from Psychromonas ingrahamii

Serine hydroxymethyltransferase (SHMT) is a pyridoxal‐5′‐phosphate (PLP)‐dependent enzyme belonging to the fold type I superfamily, which catalyzes in vivo the reversible conversion of l ‐serine and tetrahydropteroylglutamate (H₄PteGlu) to glycine and 5,10‐methylenetetrahydropteroylglutamate (5,10‐CH₂‐H₄PteGlu). The SHMT from the psychrophilic bacterium Psychromonas ingrahamii (piSHMT) had been recently purified and characterized. This enzyme was shown to display catalytic and stability properties typical of psychrophilic enzymes, namely high catalytic activity at low temperature and thermolability. To gain deeper insights into the structure–function relationship of piSHMT, the three‐dimensional structure of its apo form was determined by X‐ray crystallography. Homology modeling techniques were applied to build a model of the piSHMT holo form. Comparison of the two forms unraveled the conformation modifications that take place when the apo enzyme binds its cofactor. Our results show that the apo form is in an “open” conformation and possesses four (or five, in chain A) disordered loops whose electron density is not visible by X‐ray crystallography. These loops contain residues that interact with the PLP cofactor and three of them are localized in the major domain that, along with the small domain, constitutes the single subunit of the SHMT homodimer. Cofactor binding triggers a rearrangement of the small domain that moves toward the large domain and screens the PLP binding site at the solvent side. Comparison to the mesophilic apo SHMT from Salmonella typhimurium suggests that the backbone conformational changes are wider in psychrophilic SHMT. Proteins 2014; 82:2831–2841. © 2014 Wiley Periodicals, Inc.     

Structural diversity in the AdoMet radical enzyme superfamily

AdoMet radical enzymes are involved in processes such as cofactor biosynthesis, anaerobic metabolism, and natural product biosynthesis. These enzymes utilize the reductive cleavage of S-adenosylmethionine (AdoMet) to afford l-methionine and a transient 5'-deoxyadenosyl radical, which subsequently generates a substrate radical species. By harnessing radical reactivity, the AdoMet radical enzyme superfamily is responsible for an incredible diversity of chemical transformations. Structural analysis reveals that family members adopt a full or partial Triose-phosphate Isomerase Mutase (TIM) barrel protein fold, containing core motifs responsible for binding a catalytic [4Fe-4S] cluster and AdoMet. Here we evaluate over twenty structures of AdoMet radical enzymes and classify them into two categories: 'traditional' and 'ThiC-like' (named for the structure of 4-amino-5-hydroxymethyl-2-methylpyrimidine phosphate synthase (ThiC)). In light of new structural data, we reexamine the 'traditional' structural motifs responsible for binding the [4Fe-4S] cluster and AdoMet, and compare and contrast these motifs with the ThiC case. We also review how structural data combine with biochemical, spectroscopic, and computational data to help us understand key features of this enzyme superfamily, such as the energetics, the triggering, and the molecular mechanisms of AdoMet reductive cleavage. This article is part of a Special Issue entitled: Radical SAM Enzymes and Radical Enzymology.     

Activation of class III ribonucleotide reductase by flavodoxin: a protein radical-driven electron transfer to the iron-sulfur center

In its active form, Escherichia coli class III ribonucleotide reductase homodimer alpha(2) relies on a protein free radical located on the Gly(681) residue of the alpha polypeptide. The formation of the glycyl radical, namely, the activation of the enzyme, involves the concerted action of four components: S-adenosylmethionine (AdoMet), dithiothreitol (DTT), an Fe-S protein called beta or "activase", and a reducing system consisting of NADPH, NADPH:flavodoxin oxidoreductase, and flavodoxin (fldx). It has been proposed that a reductant serves to generate a reduced [4Fe-4S](+) cluster absolutely required for the reductive cleavage of AdoMet and the generation of the radical. Here, we suggest that the one-electron reduced form of flavodoxin (SQ), the only detectable product of the in vitro enzymatic reduction of flavodoxin, can support the formation of the glycyl radical. However, the redox potential of the Fe-S center of the enzyme is shown to be approximately 300 mV more negative than that of the SQ/fldx couple and not shifted to a more positive value by AdoMet binding. It is also more negative than that of the HQ/SQ couple, HQ being the fully reduced form of flavodoxin. Our interpretation is that activation of ribonucleotide reductase occurs through coupling of the reduction of the Fe-S center by flavodoxin to two thermodynamically favorable reactions, the oxidation of the cluster by AdoMet, yielding methionine and the 5'-deoxyadenosyl radical, and the oxidation of the glycine residue to the corresponding glycyl radical by the 5'-deoxyadenosyl radical. The second reaction plays the major role on the basis that a Gly-to-Ala mutation results in a greatly decreased production of methionine.     

Crystal structure of Streptococcus pneumoniae Sp1610, a putative tRNA methyltransferase,in complex with S‐adenosyl‐L‐methionine

Streptococcus pneumoniae Sp1610, a Class‐I fold S‐adenosylmethionine (AdoMet)‐dependent methyltransferase, is a member of the COG2384 family in the Clusters of Orthologous Groups database, which catalyzes the methylation of N¹‐adenosine at position 22 of bacterial tRNA. We determined the crystal structure of Sp1610 in the ligand‐free and the AdoMet‐bound forms at resolutions of 2.0 and 3.0 Å, respectively. The protein is organized into two structural domains: the N‐terminal catalytic domain with a Class I AdoMet‐dependent methyltransferase fold, and the C‐terminal substrate recognition domain with a novel fold of four α‐helices. Observations of the electrostatic potential surface revealed that the concave surface located near the AdoMet binding pocket was predominantly positively charged, and thus this was predicted to be an RNA binding area. Based on the results of sequence alignment and structural analysis, the putative catalytic residues responsible for substrate recognition are also proposed.     

Isolation of cellular membranes from lignin‐producing tissues of Norway spruce and analysis of redox enzymes

There are no earlier reports with successful isolation of plasma membranes from lignin‐forming tissues of conifers. A method to isolate cellular membranes from extracellular lignin‐producing tissue‐cultured cells and developing xylem of Norway spruce was optimized. Modifications to the homogenization buffer were needed to obtain membranes from these phenolics‐rich tissues. Membranes were separated by aqueous polymer two‐phase partitioning. Chlorophyll a determination, marker enzyme assays and western blot analyses using antibodies for each membrane type showed that mitochondrial, chloroplastic and to a certain extent also ER and Golgi membranes were efficiently diminished from the upper phase, but tonoplast and plasma membranes distributed evenly between the upper and lower phases. Redox enzymes present in the partially purified membrane fractions were assayed in order to reveal the origin of H₂O₂ needed for lignification. The membranes of spruce contained enzymes able to generate superoxide in the presence of NAD(P)H. Besides members of the flavodoxin and flavodoxin‐like family proteins, cytochrome b5, cytochrome P450 and several stress responsive proteins were identified by nitroblue tetrazolium staining of isoelectric focusing gels and by mass spectrometry. Naphthoquinones juglone and menadione increased superoxide production in activity‐stained gels. Some juglone‐activated enzymes were preferentially using NADH. With NADH, menadione activated only some of the enzymes that juglone did, whereas with NADPH the activation patterns were identical. Duroquinone, a benzoquinone, did not affect superoxide production. Superoxide dismutase, ascorbate peroxidase, catalase and an acidic class III peroxidase isoenzyme were detected in partially purified spruce membranes. The possible locations and functions of these enzymes are discussed.     

Crystal structure of the N‐terminal methyltransferase‐like domain of anamorsin

Anamorsin is a recently identified molecule that inhibits apoptosis during hematopoiesis. It contains an N‐terminal methyltransferase‐like domain and a C‐terminal Fe‐S cluster motif. Not much is known about the function of the protein. To better understand the function of anamorsin, we have solved the crystal structure of the N‐terminal domain at 1.8 Å resolution. Although the overall structure resembles a typical S‐adenosylmethionine (SAM) dependent methyltransferase fold, it lacks one α‐helix and one β‐strand. As a result, the N‐terminal domain as well as the full‐length anamorsin did not show S‐adenosyl‐l ‐methionine (AdoMet) dependent methyltransferase activity. Structural comparisons with known AdoMet dependent methyltransferases reveals subtle differences in the SAM binding pocket that preclude the N‐terminal domain from binding to AdoMet. The N‐terminal methyltransferase‐like domain of anamorsin probably functions as a structural scaffold to inhibit methyl transfers by out‐competing other AdoMet dependant methyltransferases or acts as bait for protein–protein interactions.Proteins 2014; 82:1066–1071. © 2013 Wiley Periodicals, Inc.     

Neisseria meningitidis expresses a single 3‐deoxy‐d‐arabino‐heptulosonate 7‐phosphate synthase that is inhibited primarily by phenylalanine

Neisseria meningitidis is the causative agent of meningitis and meningococcal septicemia is a major cause of disease worldwide, resulting in brain damage and hearing loss, and can be fatal in a large proportion of cases. The enzyme 3‐deoxy‐d ‐arabino‐heptulosonate 7‐phosphate synthase (DAH7PS) catalyzes the first reaction in the shikimate pathway leading to the biosynthesis of aromatic metabolites including the aromatic acids l ‐Trp, l ‐Phe, and l ‐Tyr. This pathway is absent in humans, meaning that enzymes of the pathway are considered as potential candidates for therapeutic intervention. As the entry point, feedback inhibition of DAH7PS by pathway end products is a key mechanism for the control of pathway flux. The structure of the single DAH7PS expressed by N. meningitidis was determined at 2.0 Å resolution. In contrast to the other DAH7PS enzymes, which are inhibited only by a single aromatic amino acid, the N. meningitidis DAH7PS was inhibited by all three aromatic amino acids, showing greatest sensitivity to l ‐Phe. An N. meningitidis enzyme variant, in which a single Ser residue at the bottom of the inhibitor‐binding cavity was substituted to Gly, altered inhibitor specificity from l ‐Phe to l ‐Tyr. Comparison of the crystal structures of both unbound and Tyr‐bound forms and the small angle X‐ray scattering profiles reveal that N. meningtidis DAH7PS undergoes no significant conformational change on inhibitor binding. These observations are consistent with an allosteric response arising from changes in protein motion rather than conformation, and suggest ligands that modulate protein dynamics may be effective inhibitors of this enzyme.     

The cystathionine‐β‐synthase domains on the guanosine 5′’‐monophosphate reductase and inosine 5′‐monophosphate dehydrogenase enzymes from Leishmania regulate enzymatic activity in response to guanylate and adenylate nucleotide levels

The Leishmania guanosine 5′‐monophosphate reductase (GMPR) and inosine 5′‐monophosphate dehydrogenase (IMPDH) are purine metabolic enzymes that function maintaining the cellular adenylate and guanylate nucleotide. Interestingly, both enzymes contain a cystathionine‐β‐synthase domain (CBS). To investigate this metabolic regulation, the Leishmania GMPR was cloned and shown to be sufficient to complement the guaC (GMPR), but not the guaB (IMPDH), mutation in Escherichia coli. Kinetic studies confirmed that the Leishmania GMPR catalyzed a strict NADPH‐dependent reductive deamination of GMP to produce IMP. Addition of GTP or high levels of GMP induced a marked increase in activity without altering the K_m values for the substrates. In contrast, the binding of ATP decreased the GMPR activity and increased the GMP K_m value 10‐fold. These kinetic changes were correlated with changes in the GMPR quaternary structure, induced by the binding of GMP, GTP, or ATP to the GMPR CBS domain. The capacity of these CBS domains to mediate the catalytic activity of the IMPDH and GMPR provides a regulatory mechanism for balancing the intracellular adenylate and guanylate pools.     

Quinazolin‐4(3H)‐one‐Based Hydroxamic Acids: Design,Synthesis and Evaluation of Histone Deacetylase Inhibitory Effects and Cytotoxicity

The present article describes the synthesis and biological activity of various series of novel hydroxamic acids incorporating quinazolin‐4(3H)‐ones as novel small molecules targeting histone deacetylases. Biological evaluation showed that these hydroxamic acids were potently cytotoxic against three human cancer cell lines (SW620, colon; PC‐3, prostate; NCI?H23, lung). Most compounds displayed superior cytotoxicity than SAHA (suberoylanilide hydroxamic acid, Vorinostat) in term of cytotoxicity. Especially, N‐hydroxy‐7‐(7‐methyl‐4‐oxoquinazolin‐3(4H)‐yl)heptanamide ( 5b ) and N‐hydroxy‐7‐(6‐methyl‐4‐oxoquinazolin‐3(4H)‐yl)heptanamide ( 5c ) (IC₅₀ values, 0.10–0.16 μm ) were found to be approximately 30‐fold more cytotoxic than SAHA (IC₅₀ values of 3.29–3.67 μm ). N‐Hydroxy‐7‐(4‐oxoquinazolin‐3(4H)‐yl)heptanamide ( 5a ; IC₅₀ values of 0.21–0.38 μm ) was approximately 10‐ to 15‐fold more potent than SAHA in cytotoxicity assay. These compounds also showed comparable HDAC inhibition potency with IC₅₀ values in sub‐micromolar ranges. Molecular docking experiments indicated that most compounds, as represented by 5b and 5c , strictly bound to HDAC2 at the active binding site with binding affinities much higher than that of SAHA.     

Three‐dimensional structure of a sugar N‐formyltransferase from Francisella tularensis

N‐formylated sugars have been observed on the O‐antigens of such pathogenic Gram‐negative bacteria as Campylobacter jejuni and Francisella tularensis. Until recently, however, little was known regarding the overall molecular architectures of the N‐formyltransferases that are required for the biosynthesis of these unusual sugars. Here we demonstrate that the protein encoded by the wbtj gene from F. tularensis is an N‐formyltransferase that functions on dTDP‐4‐amino‐4,6‐dideoxy‐d ‐glucose as its substrate. The enzyme, hereafter referred to as WbtJ, demonstrates a strict requirement for N¹⁰‐formyltetrahydrofolate as its carbon source. In addition to the kinetic analysis, the three‐dimensional structure of the enzyme was solved in the presence of dTDP‐sugar ligands to a nominal resolution of 2.1 Å. Each subunit of the dimeric enzyme is dominated by a “core” domain defined by Met 1 to Ser 185. This core motif harbors the active site residues. Following the core domain, the last 56 residues fold into two α‐helices and a β‐hairpin motif. The hairpin motif is responsible primarily for the subunit:subunit interface, which is characterized by a rather hydrophobic pocket. From the study presented here, it is now known that WbtJ functions on C‐4′ amino sugars. Another enzyme recently investigated in the laboratory, WlaRD, formylates only C‐3′ amino sugars. Strikingly, the quaternary structures of WbtJ and WlaRD are remarkably different. In addition, there are several significant variations in the side chains that line their active site pockets, which may be important for substrate specificity. Details concerning the kinetic and structural properties of WbtJ are presented.     

Engineering of Phosphoserine Aminotransferase Increases the Conversion of l‐Homoserine to 4‐Hydroxy‐2‐ketobutyrate in a Glycerol‐Independent Pathway of 1,3‐Propanediol Production from Glucose

Phosphoserine aminotransferase (SerC) from Escherichia coli (E. coli) MG1655 is engineered to catalyze the deamination of homoserine to 4‐hydroxy‐2‐ketobutyrate, a key reaction in producing 1,3‐propanediol (1,3‐PDO) from glucose in a novel glycerol‐independent metabolic pathway. To this end, a computation‐based rational approach is used to change the substrate specificity of SerC from l ‐phosphoserine to l ‐homoserine. In this approach, molecular dynamics simulations and virtual screening are combined to predict mutation sites. The enzyme activity of the best mutant, SerC_R42W/R77W, is successfully improved by 4.2‐fold in comparison to the wild type when l ‐homoserine is used as the substrate, while its activity toward the natural substrate l ‐phosphoserine is completely deactivated. To validate the effects of the mutant on 1,3‐PDO production, the “homoserine to 1,3‐PDO” pathway is constructed in E. coli by coexpression of SerC_R42W/R77W with pyruvate decarboxylase and alcohol dehydrogenase. The resulting mutant strain achieves the production of 3.03 g L^?1 1,3‐PDO in fed‐batch fermentation, which is 13‐fold higher than the wild‐type strain and represents an important step forward to realize the promise of the glycerol‐independent synthetic pathway for 1,3‐PDO production from glucose.     

Molecular characterization of novel pyridoxal‐5′‐phosphate‐dependent enzymes from the human microbiome

Pyridoxal‐5′‐phosphate or PLP, the active form of vitamin B6, is a highly versatile cofactor that participates in a large number of mechanistically diverse enzymatic reactions in basic metabolism. PLP‐dependent enzymes account for ～1.5% of most prokaryotic genomes and are estimated to be involved in ～4% of all catalytic reactions, making this an important class of enzymes. Here, we structurally and functionally characterize three novel PLP‐dependent enzymes from bacteria in the human microbiome: two are from Eubacterium rectale, a dominant, nonpathogenic, fecal, Gram‐positive bacteria, and the third is from Porphyromonas gingivalis, which plays a major role in human periodontal disease. All adopt the Type I PLP‐dependent enzyme fold and structure‐guided biochemical analysis enabled functional assignments as tryptophan, aromatic, and probable phosphoserine aminotransferases.