Mapping the catalytic conformations of an assembly-line polyketide synthase module.

Assembly-line polyketide synthases, such as the 6-deoxyerythronolide B synthase (DEBS), are large enzyme factories prized for their ability to produce specific and complex polyketide products. By channeling protein-tethered substrates across multiple active sites in a defined linear sequence, these enzymes facilitate programmed small-molecule syntheses that could theoretically be harnessed to access countless polyketide product structures. Using cryogenic electron microscopy to study DEBS module 1, we present a structural model describing this substrate-channeling phenomenon. Our 3.2- to 4.3-angstrom-resolution structures of the intact module reveal key domain-domain interfaces and highlight an unexpected module asymmetry. We also present the structure of a product-bound module that shines light on a recently described "turnstile" mechanism for transient gating of active sites along the assembly line.

Evidence for an Enzyme-Catalyzed Rauhut-Currier Reaction during the Biosynthesis of Spinosyn A.

The catalog of enzymes known to catalyze the nucleophile-assisted formation of C-C bonds is extremely small, and there is presently no definitive example of a biological Rauhut-Currier reaction. Biosynthesis of the polyketide insecticide spinosyn A in Saccharopolyspora spinosa involves a [4 + 2]-cycloaddition and a subsequent intramolecular C-C bond formation catalyzed by SpnF and SpnL, respectively. Isotope tracer experiments and kinetic isotope effects, however, imply that the SpnL-catalyzed reaction proceeds without initial deprotonation of the substrate. The crystal structure of SpnL exhibits high similarity to SAM-dependent methyltransferases as well as SpnF. The residue Cys60 is also shown to reside in the SpnL active site, and the Cys60Ala SpnL mutant is found to be devoid of activity. Moreover, SpnL is covalently modified at Cys60 and irreversibly inactivated when it is coincubated with a fluorinated substrate analogue designed as a suicide inactivator of nucleophile-assisted C-C bond formation. These results suggest that SpnL catalyzes a biological Rauhut-Currier reaction.

Polyketide Starter and Extender Units Serve as Regulatory Ligands to Coordinate the Biosynthesis of Antibiotics in Actinomycetes.

Polyketides are one of the largest categories of secondary metabolites, and their biosynthesis is initiated by polyketide synthases (PKSs) using coenzyme A esters of short fatty acids (acyl-CoAs) as starter and extender units. In this study, we discover a universal regulatory mechanism in which the starter and extender units, beyond direct precursors of polyketides, function as ligands to coordinate the biosynthesis of antibiotics in actinomycetes. A novel acyl-CoA responsive TetR-like regulator (AcrT) is identified in an erythromycin-producing strain of Saccharopolyspora erythraea. AcrT shows the highest binding affinity to the promoter of the PKS-encoding gene eryAI in the DNA affinity capture assay (DACA) and directly represses the biosynthesis of erythromycin. Propionyl-CoA (P-CoA) and methylmalonyl-CoA (MM-CoA) as the starter and extender units for erythromycin biosynthesis can serve as the ligands to release AcrT from PeryAI, resulting in an improved erythromycin yield. Intriguingly, anabolic pathways of the two acyl-CoAs are also suppressed by AcrT through inhibition of the transcription of acetyl-CoA (A-CoA) and P-CoA carboxylase genes and stimulation of the transcription of citrate synthase genes, which is beneficial to bacterial growth. As P-CoA and MM-CoA accumulate, they act as ligands in turn to release AcrT from those targets, resulting in a redistribution of more A-CoA to P-CoA and MM-CoA against citrate. Furthermore, based on analyses of AcrT homologs in Streptomyces avermitilis and Streptomyces coelicolor, it is believed that polyketide starter and extender units have a prevalent, crucial role as ligands in modulating antibiotic biosynthesis in actinomycetes. IMPORTANCE Numerous antibiotics are derived from polyketides, whose biosynthesis is accurately controlled by transcriptional regulators that respond to diverse physiological or environmental signals. It is generally accepted that antibiotics or biosynthetic intermediates serve as effectors to modulate their production in actinomycetes. Our study unprecedentedly demonstrates that the direct precursors of polyketide, propionyl-CoA and methylmalonyl-CoA, play a role as ligands to modulate erythromycin biosynthesis in Saccharopolyspora erythraea. More importantly, the two acyl-CoAs as ligands could adjust their own supplies by regulating the acetyl-CoA metabolic pathway so as to well settle the relationship between cellular growth and secondary metabolism. Significantly, polyketide starter and extender units have a universal role as ligands to coordinate antibiotic biosynthesis in actinomycetes. These findings not only expand the understanding of ligand-mediated regulation for antibiotic biosynthesis but also provide new insights into the physiological functions of polyketide starter and extender units in actinomycetes.

RNA-Seq-Based Transcriptomic Analysis of Saccharopolyspora spinosa Revealed the Critical Function of PEP Phosphonomutase in the Replenishment Pathway.

Spinosyns, the secondary metabolites produced by Saccharopolyspora spinosa, are the active ingredients in a family of novel biological insecticides. Although the complete genome sequence of S. spinosa has been published, the transcriptome of S. spinosa remains poorly characterized. In this study, high-throughput RNA sequencing (RNA-seq) technology was applied to dissect the transcriptome of S. spinosa. Through transcriptomic analysis of different periods of S. spinosa growth, we found large numbers of differentially expressed genes and classified them according to their different functions. Based on the RNA-seq data, the CRISPR-Cas9 method was used to knock out the PEP phosphonomutase gene (orf 06952-4171). The yield of spinosyns A and D in S. spinosa-ΔPEP was 178.91 mg/L and 42.72 mg/L, which was 2.14-fold and 1.76-fold higher than that in the wild type (83.51 and 24.34 mg/L), respectively. The analysis of the mutant strains also verified the validity of the transcriptome data. The deletion of the PEP phosphonomutase gene leads to an increase in pyruvate content and affects the biosynthesis of spinosad. The replenishment of phosphoenol pyruvate in S. spinosa provides the substrate for the production of spinosad. We envision that these transcriptomic analysis results will contribute to the further study of secondary metabolites in actinomycetes.

Increasing cytochrome P450 enzyme diversity by identification of two distinct cyclodipeptide dimerases.

Genome mining revealed the presence of two cdps-p450 operons in Saccharopolyspora antimicrobica. Heterologous expression, biochemical characterisation and structure elucidation proved that the two P450 enzymes catalyse distinct regio- and stereospecific dimerizations of cyclo-(l-Trp-l-Trp), which significantly expands the repertoire of diketopiperazine-tailoring enzymes. TtpB1 connects the monomers via C3-C3', both from the opposite side of H-11/H-11', while TtpB2 is characterised as the first P450 to mainly catalyse the unusual linkage between N1' and C3 from the H-11 side.

Identification and Characterization of a Novel N- and O-Glycosyltransferase from Saccharopolyspora erythraea.

Glycosyltransferases are important enzymes which are often used as tools to generate novel natural products. In this study, we describe the identification and characterization of an inverting N- and O-glycosyltransferase from Saccharopolyspora erythraea NRRL2338. When feeding experiments with 1,4-diaminoanthraquinone in Saccharopolyspora erythraea were performed, the formation of new compounds (U3G and U3DG) was observed by HPLC-MS. Structure elucidation by NMR revealed that U3G consists of two compounds, N1-α-glucosyl-1,4-diaminoanthraquinone and N1-ß-glucosyl-1,4-diaminoanthraquinone. Based on UV and MS data, U3DG is a N1,N4-diglucosyl-1,4-diaminoanthraquinone. In order to find the responsible glycosyltransferase, gene deletion experiments were performed and we identified the glycosyltransferase Sace_3599, which belongs to the CAZy family 1. When Streptomyces albus J1074, containing the dTDP-d-glucose synthase gene oleS and the plasmid pUWL-A-sace_3599, was used as host, U3 was converted to the same compounds. Protein production in Escherichia coli and purification of Sace_3599 was carried out. The enzyme showed glycosyl hydrolase activity and was able to produce mono- and di-N-glycosylated products in vitro. When UDP-α-d-glucose was used as a sugar donor, U3 was stereoselective converted to N1-ß-glucosyl-1,4-diaminoanthraquinone and N1,N4-diglucosyl-1,4-diaminoanthraquinone. The use of 1,4-dihydroxyanthraquinone as a substrate in in vitro experiments also led to the formation of mono-glucosylated and di-glucosylated products, but in lower amounts. Overall, we identified and characterized a novel glycosyltransferase which shows glycohydrolase activity and the ability to glycosylate "drug like" structures forming N- and O-glycosidic bonds.

Crystal structure of ErmE - 23S rRNA methyltransferase in macrolide resistance.

Pathogens often receive antibiotic resistance genes through horizontal gene transfer from bacteria that produce natural antibiotics. ErmE is a methyltransferase (MTase) from Saccharopolyspora erythraea that dimethylates A2058 in 23S rRNA using S-adenosyl methionine (SAM) as methyl donor, protecting the ribosomes from macrolide binding. To gain insights into the mechanism of macrolide resistance, the crystal structure of ErmE was determined to 1.75 Å resolution. ErmE consists of an N-terminal Rossmann-like α/ß catalytic domain and a C-terminal helical domain. Comparison with ErmC' that despite only 24% sequence identity has the same function, reveals highly similar catalytic domains. Accordingly, superposition with the catalytic domain of ErmC' in complex with SAM suggests that the cofactor binding site is conserved. The two structures mainly differ in the C-terminal domain, which in ErmE contains a longer loop harboring an additional 310 helix that interacts with the catalytic domain to stabilize the tertiary structure. Notably, ErmE also differs from ErmC' by having long disordered extensions at its N- and C-termini. A C-terminal disordered region rich in arginine and glycine is also a present in two other MTases, PikR1 and PikR2, which share about 30% sequence identity with ErmE and methylate the same nucleotide in 23S rRNA.

Two amino acids missing of MtrA resulted in increased erythromycin level and altered phenotypes in Saccharopolyspora erythraea.

The MtrA-MtrB two-component regulatory system is highly conserved in Actinobacteria and plays crucial roles in cell cycle progression, cell morphology, antibiotic resistance, and osmoprotection. Previously, we revealed that the MtrA protein of Saccharopolyspora erythraea E3 strain (a high erythromycin-producing strain) had a two amino acid (H197 and V198) deletion in the DNA recognition helices of the C-terminal domain compared to the wild type S. erythraea strain NRRL2338. Here, we identified mepA (encoding a membrane protein related to metalloendopeptidases) as an MtrA target gene, and found that deleting the two amino acids in MtrA (MtrAdel) resulted in the loss of its DNA-binding activity for the mepA gene. The mutant MtrAdel lost its regulatory activity and affected various physiological functions consistent with mtrA deletion, including increased erythromycin biosynthesis, enhanced antibiotic resistance, deregulated osmoprotection, and improved transport of substances. The introduction of the wild type mtrA gene into the S. erythraea E3 strain with the mtrAdel gene decreased the erythromycin yield by approximately 50%, confirming that MtrA repressed erythromycin production. These findings demonstrate that MtrA is an important pleiotropic regulator of erythromycin biosynthesis, antibiotic resistance, osmoprotection, and substance transport in S. erythraea and provide new insights for improving erythromycin production. Future studies linking the molecular effects of MtrA to these phenotypes will improve our understanding of the MtrA-MtrB two-component regulatory system in Actinobacteria.

De Novo Design and Implementation of a Tandem Acyl Carrier Protein Domain in a Type I Modular Polyketide Synthase.

During polyketide and fatty acid biosynthesis, the growing acyl chain is attached to the acyl carrier protein via a thioester linkage. The acyl carrier protein interacts with other enzymes that perform chain elongation and chain modification on the bound acyl chain. Most type I polyketide synthases and fatty acid synthases contain only one acyl carrier protein. However, polyunsaturated fatty acid synthases from deep-sea bacteria contain anywhere from two to nine acyl carrier proteins. Recent studies have shown that this tandem acyl carrier protein feature is responsible for the unusually high fatty acid production rate of deep-sea bacteria. To investigate if a similar strategy can be used to increase the production rate of type I polyketide synthases, a 3×ACP domain was rationally designed and genetically installed in module 6 of 6-deoxyerythronolide B synthase, which is a prototypical type I modular polyketide synthase that naturally harbors just one acyl carrier protein. This modification resulted in an ∼2.5-fold increase in the total amount of polyketide produced in vitro, demonstrating that installing a tandem acyl carrier domain in a type I polyketide synthase is an effective strategy for enhancing the rate of polyketide natural product biosynthesis.

Impact on strain growth and butenyl-spinosyn biosynthesis by overexpression of polynucleotide phosphorylase gene in Saccharopolyspora pogona.

Polynucleotide phosphorylase is a highly conserved protein found in bacteria and fungi that can regulate the transcription of related enzymes involved in amino acid metabolism, organic acid metabolism, and cell biosynthesis. We studied the effect of polynucleotide phosphorylase on Saccharopolyspora pogona (S. pogona) growth and the synthesis of secondary metabolites. First, we generated the overexpression vector pOJ260-PermE-pnp via overlap extension PCR. The vector pOJ260-PermE-pnp was then introduced into S. pogona by conjugal transfer, thereby generating the recombination strain S. pogona-Pnp. Results showed that engineering strains possessed higher biomass than those of the wild-type strains. Moreover, the ability of these strains to produce spores on solid medium was stronger than that of the wild-type strains. HPLC results revealed that the butenyl-spinosyn yield in S. pogona-Pnp increased by 1.92-fold compared with that of S. pogona alone. These findings revealed that overexpression of polynucleotide phosphorylase effectively promoted butenyl-spinosyn biosynthesis in S. pogona. This result may be extended to other Streptomyces for strain improvement.

Protein Acylation is a General Regulatory Mechanism in Biosynthetic Pathway of Acyl-CoA-Derived Natural Products.

Coenzyme A (CoA) esters of short fatty acids (acyl-CoAs) function as key precursors for the biosynthesis of various natural products and the dominant donors for lysine acylation. Herein, we investigated the functional interplay between beneficial and adverse effects of acyl-CoA supplements on the production of acyl-CoA-derived natural products in microorganisms by using erythromycin-biosynthesized Saccharopolyspora erythraea as a model: accumulation of propionyl-CoA benefited erythromycin biosynthesis, but lysine propionylation inhibited the activities of important enzymes involved in biosynthetic pathways of erythromycin. The results showed that the overexpression of NAD+-dependent deacylase could circumvent the inhibitory effects of high acyl-CoA concentrations. In addition, we demonstrated the similar lysine acylation mechanism in other acyl-CoA-derived natural product biosynthesis, such as malonyl-CoA-derived alkaloid and butyryl-CoA-derived bioalcohol. These observations systematically uncovered the important role of protein acylation on interaction between the accumulation of high concentrations of acyl-CoAs and the efficiency of their use in metabolic pathways.

Eis, a novel family of arylalkylamine N-acetyltransferase (EC 2.3.1.87).

Enhanced intracellular survival (Eis) proteins were found to enhance the intracellular survival of mycobacteria in macrophages by acetylating aminoglycoside antibiotics to confer resistance to these antibiotics and by acetylating DUSP16/MPK-7 to suppress host innate immune defenses. Eis homologs composing of two GCN5 N-acetyltransferase regions and a sterol carrier protein fold are found widely in gram-positive bacteria. In this study, we found that Eis proteins have an unprecedented ability to acetylate many arylalkylamines, are a novel type of arylalkylamine N-acetyltransferase AANAT (EC 2.3.1.87). Sequence alignment and phyletic distribution analysis confirmed Eis belongs to a new aaNAT-like cluster. Among the cluster, we studied three typical Eis proteins: Eis_Mtb from Mycobacterium tuberculosis, Eis_Msm from Mycobacterium smegmatis, and Eis_Sen from Saccharopolyspora erythraea. Eis_Mtb prefers to acetylate histamine and octopamine, while Eis_Msm uses tyramine and octopamine as substrates. Unlike them, Eis_Sen exihibits good catalytic efficiencies for most tested arylalkylamines. Considering arylalkylamines such as histamine plays a fundamental role in immune reactions, future work linking of AANAT activity of Eis proteins to their physiological function will broaden our understanding of gram-positive pathogen-host interactions. These findings shed insights into the molecular mechanism of Eis, and reveal potential clinical implications for many gram-positive pathogens.

Influence of water and enzyme SpnF on the dynamics and energetics of the ambimodal [6+4]/[4+2] cycloaddition.

SpnF is the first monofunctional Diels-Alder/[6+4]-ase that catalyzes a reaction leading to both Diels-Alder and [6+4] adducts through a single transition state. The environment-perturbed transition-state sampling method has been developed to calculate free energies, kinetic isotope effects, and quasi-classical reaction trajectories of enzyme-catalyzed reactions and the uncatalyzed reaction in water. Energetics calculated in this way reproduce the experiment and show that the normal Diels-Alder transition state is stabilized by H bonds with water molecules, while the ambimodal transition state is favored in the enzyme SpnF by both intramolecular hydrogen bonding and hydrophobic binding. Molecular dynamics simulations show that trajectories passing through the ambimodal transition state bifurcate to the [6+4] adduct and the Diels-Alder adduct with a ratio of 1:1 in the gas phase, 1:1.6 in water, and 1:11 in the enzyme. This example shows how an enzyme acts on a vibrational time scale to steer post-transition state trajectories toward the Diels-Alder adduct.

Identification of (R)-selective ω-aminotransferases by exploring evolutionary sequence space.

Several (R)-selective ω-aminotransferases (R-ωATs) have been reported. The existence of additional R-ωATs having different sequence characteristics from previous ones is highly expected. In addition, it is generally accepted that R-ωATs are variants of aminotransferase group III. Based on these backgrounds, sequences in RefSeq database were scored using family profiles of branched-chain amino acid aminotransferase (BCAT) and d-alanine aminotransferase (DAT) to predict and identify putative R-ωATs. Sequences with two profile analysis scores were plotted on two-dimensional score space. Candidates with relatively similar scores in both BCAT and DAT profiles (i.e., profile analysis score using BCAT profile was similar to profile analysis score using DAT profile) were selected. Experimental results for selected candidates showed that putative R-ωATs from Saccharopolyspora erythraea (R-ωAT_Sery), Bacillus cellulosilyticus (R-ωAT_Bcel), and Bacillus thuringiensis (R-ωAT_Bthu) had R-ωAT activity. Additional experiments revealed that R-ωAT_Sery also possessed DAT activity while R-ωAT_Bcel and R-ωAT_Bthu had BCAT activity. Selecting putative R-ωATs from regions with similar profile analysis scores identified potential R-ωATs. Therefore, R-ωATs could be efficiently identified by using simple family profile analysis and exploring evolutionary sequence space.

Overproduction of Erythromycin by Ultraviolet Mutagenesis and Expression of ermE Gene in Saccharopolyspora erythraea.

Erythromycin is a macrolide antibiotic with broad-spectrum activity against gram-positive bacteria that stops protein synthesis by binding to 50s ribosomal subunit. Classical and recombinant strain improvement, such as application of ultraviolet (UV) mutagenesis and selection of overproduction mutant, is the most important and convenient method in enhancement of antibiotic production. In the present study, Saccharopolyspora erythraea was mutagenized using UV lights and selection by tylosin resistance mutant to improve yield of erythromycin. In other sides, to improve the erythromycin yield in mutant, effects of various parameters such as carbon concentration and ermE gene expression were analyzed. In primary selection, high erythromycin producing strains and high erythromycin producer mutant were isolated by plaque agar, and an increase of 87% was observed in tylosin resistance mutant compared to wild-type strain. In secondary selection, a mutant strain (RHU233) with a production of 1.39 mg erythromycin per mL was isolated in fermentation process, which was 20 times more productive than the wild type. In contrast, it was found that glycerol can be used as an alternate carbon source in enhancement of erythromycin production. Comparison of ermE gene expression in mutants RHU233 high producer mutant RHU233 and wild type in Escherichia coli detected in accumulation of soluble hexahistidine-ermE was up to 45% of total cell protein after 18 h in mutants RHU233. Metal-chelation chromatography yielded 126 mg of hexahistidine-ermE per liter of culture with a purity slightly >95% in mutants RHU233. Finally, these optimized conditions could be used for the commercial production of this unique antibiotic.

Investigation of the mechanism of the SpnF-catalyzed [4+2]-cycloaddition reaction in the biosynthesis of spinosyn A.

The Diels-Alder reaction is one of the most common methods to chemically synthesize a six-membered carbocycle. While it has long been speculated that the cyclohexene moiety found in many secondary metabolites is also introduced via similar chemistry, the enzyme SpnF involved in the biosynthesis of the insecticide spinosyn A in Saccharopolyspora spinosa is the first enzyme for which catalysis of an intramolecular [Formula: see text]-cycloaddition has been experimentally verified as its only known function. Since its discovery, a number of additional standalone [Formula: see text]-cyclases have been reported as potential Diels-Alderases; however, whether their catalytic cycles involve a concerted or stepwise cyclization mechanism has not been addressed experimentally. Here, we report direct experimental interrogation of the reaction coordinate for the [Formula: see text]-carbocyclase SpnF via the measurement of [Formula: see text]-secondary deuterium kinetic isotope effects (KIEs) at all sites of [Formula: see text] rehybridization for both the nonenzymatic and enzyme-catalyzed cyclization of the SpnF substrate. The measured KIEs for the nonenzymatic reaction are consistent with previous computational results implicating an intermediary state between formation of the first and second carbon-carbon bonds. The KIEs measured for the enzymatic reaction suggest a similar mechanism of cyclization within the enzyme active site; however, there is evidence that conformational restriction of the substrate may play a role in catalysis.

Inversion of Extender Unit Selectivity in the Erythromycin Polyketide Synthase by Acyltransferase Domain Engineering.

Acyltransferase (AT) domains of polyketide synthases (PKSs) select extender units for incorporation into polyketides and dictate large portions of the structures of clinically relevant natural products. Accordingly, there is significant interest in engineering the substrate specificity of PKS ATs in order to site-selectively manipulate polyketide structure. However, previous attempts to engineer ATs have yielded mutant PKSs with relaxed extender unit specificity, rather than an inversion of selectivity from one substrate to another. Here, by directly screening the extender unit selectivity of mutants from active site saturation libraries of an AT from the prototypical PKS, 6-deoxyerythronolide B synthase, a set of single amino acid substitutions was discovered that dramatically impact the selectivity of the PKS with only modest reductions of product yields. One particular substitution (Tyr189Arg) inverted the selectivity of the wild-type PKS from its natural substrate toward a non-natural alkynyl-modified extender unit while maintaining more than twice the activity of the wild-type PKS with its natural substrate. The strategy and mutations described herein form a platform for combinatorial biosynthesis of site-selectively modified polyketide analogues that are modified with non-natural and non-native chemical functionality.

Acetyl-CoA synthetases of Saccharopolyspora erythraea are regulated by the nitrogen response regulator GlnR at both transcriptional and post-translational levels.

Saccharopolyspora erythraea has three AMP-forming acetyl-CoA synthetases (Acs) encoded by acsA1, acsA2, and acsA3. In this work, we found that nitrogen response regulator GlnR can directly interact with the promoter regions of all three genes and can activate their transcription in response to nitrogen availability. The typical GlnR-binding boxes were identified in the promoter regions. Moreover, the activities of three Acs enzymes were modulated by the reversible lysine acetylation (RLA) with acetyltransferase AcuA and NAD+ -dependent deacetylase SrtN. Interestingly, GlnR controlled the RLA by directly activating the expression of acuA and srtN. A glnR-deleted mutant (ΔglnR) caused a growth defect in 10 mM acetate minimal medium, a condition under which RLA function is critical to control Acs activity. Overexpression of acuA reversed the growth defect of ΔglnR mutant. Total activity of Acs in cell-free extracts from ΔglnR strain had a 4-fold increase relative to that of wildtype strain. Western Blotting showed that in vivo acetylation levels of Acs were influenced by nitrogen availability and lack of glnR. These results demonstrated that GlnR regulated acetyl-CoA synthetases at transcriptional and post-translational levels, and mediated the interplay between nitrogen and carbon metabolisms by integrating nitrogen signals to modulate the acetate metabolism.

On the phosphorylase activity of GH3 enzymes: A ß-N-acetylglucosaminidase from Herbaspirillum seropedicae SmR1 and a glucosidase from Saccharopolyspora erythraea.

A phosphorolytic activity has been reported for beta-N-acetylglucosaminidases from glycoside hydrolase family 3 (GH3) giving an interesting explanation for an unusual histidine as catalytic acid/base residue and suggesting that members from this family may be phosphorylases [J. Biol. Chem. 2015, 290, 4887]. Here, we describe the characterization of Hsero1941, a GH3 beta-N-acetylglucosaminidase from the endophytic nitrogen-fixing bacterium Herbaspirillum seropedicae SmR1. The enzyme has significantly higher activity against pNP-beta-D-GlcNAcp (Km = 0.24 mM, kcat = 1.2 s-1, kcat/Km = 5.0 mM-1s-1) than pNP-beta-D-Glcp (Km = 33 mM, kcat = 3.3 × 10-3 s-1, kcat/Km = 9 × 10-4 mM-1s-1). The presence of phosphate failed to significantly modify the kinetic parameters of the reaction. The enzyme showed a broad aglycone site specificity, being able to hydrolyze sugar phosphates beta-D-GlcNAc 1P and beta-D-Glc 1P, albeit at a fraction of the rate of hydrolysis of aryl glycosides. GH3 beta-glucosidase EryBI, that does not have a histidine as the general acid/base residue, also hydrolyzed beta-D-Glc 1P, at comparable rates to Hsero1941. These data indicate that Hsero1941 functions primarily as a hydrolase and that phosphorolytic activity is likely adventitious. The prevalence of histidine as a general acid/base residue is not predictive, nor correlative, with GH3 beta-N-acetylglucosaminidases having phosphorolytic activity.

Lysine ε-aminotransferases: kinetic constants, substrate specificities, and the variation in active site residues.

L-Lysine ε-aminotransferase (lysAT) is an important enzyme in tailoring the terminal amino group of L-lysine or L-ornithine and can be directed to the synthesis of various value-added chemicals such as adipic acid. Three lysATs, lysAT from Saccharopolyspora erythraea NRRL 2338 (lysAT_Sery), lysAT from Nocardia farcinica IFM 10152, and lysAT from Rhodococcus jostii RHA1, were cloned, and their kinetic values and substrate specificities were investigated. In the reaction using 5mM L-lysine and 10mM α-ketoglutarate, lysAT_Sery from S. erythraea NRRL 2338 showed 72% higher specific activity than lysAT from Nocardia farcinica IFM 10152 and 42% higher specific activity than lysAT from R. jostii RHA1. More interesting result was that lysAT Sery, exhibiting the highest activity among three lysATs, did not show any activity to L-ornithine. The alignment of 146 lysAT sequences from RefSeq database was searched by the EC number of lysAT to compare the active site residues among the lysAT sequences. The sequence alignment showed that only two residues, corresponding to Ala129 and Asn328 of lysAT from Mycobacterium tuberculosis H37Rv (lysAT_Mtub), showed variations among the active site residues. All the active site residues except those two residues were completely conserved throughout 145 lysAT sequences. lysAT from S. erythraea NRRL 2338 has A129T and N328S variations (residue numbers are those of the crystal structure of lysAT_Mtub). The structural analysis by the homology model indicate that Thr126 by A129T variation in lysAT_Sery is appeared to interact more tightly with the phosphate group of PLP than alanine (the distance between Thr126 and the phosphate group of PLP was 2.92Å). In addition, Ser328 is located at the substrate recognition site of active site and, therefore, N328S variation may be connected to the substrate specificity of lysAT.