Structural characteristics and catalytic mechanism of <Emphasis Type="Italic">Bacillus</Emphasis> β-propeller phytases

ß-Propeller phytases of Bacillus are unique highly conservative and highly specific enzymes capable of cleaving insoluble phytate compounds. In this review, we analyzed data on the properties of these enzymes, their differences from other phytases, and their unique spatial structures and substrate specificities. We considered influences of different factors on the catalytic activity and thermostability of these enzymes. There are few data on the hydrolysis mechanism of these enzymes, which makes it difficult to analyze their mechanism of action and their final products. We analyzed the available data on hydrolysis by ß-propeller phytases of calcium complexes with myo-inositol hexakisphosphate.     

Are there non‐catalytic functions of acetylcholinesterases? Lessons from mutant animal models

Acetylcholinesterase (AChE) hydrolyses acetylcholine (ACh) ensuring the fast clearance of released neurotransmitter at cholinergic synapses. Many studies led to the hypothesis that AChE and the closely related enzyme butyrylcholinesterase (BChE) may play other, non-hydrolytic roles during development. In this review, we compare data from in vivo studies performed on invertebrate and vertebrate genetic models. The loss of function of ache in these systems is responsible for the appearance of several phenotypes. In all aspects so far studied, the phenotypes can be explained by an excess of the undegraded substrate, ACh, leading to misfunction and pathological alterations. Thus, the lack of AChE catalytic activity in the mutants appears to be solely responsible for the observed phenotypes. None of them appears to require the postulated adhesive or other non-hydrolytic functions of AChE.     

Molecular engineering of <Emphasis Type="SmallCaps">l</Emphasis>-aspartate-α-decarboxylase for improved activity and catalytic stability

β-Alanine is an important precursor for the production of food additives, pharmaceuticals, and nitrogen-containing chemicals. Compared with the conventional chemical routes for β-alanine production, the biocatalytic routes using l-aspartate-α-decarboxylase (ADC) are more attractive when energy and environment are concerned. However, ADC’s poorly understood properties and its inherent mechanism-based inactivation significantly limited the application of this enzyme. In this study, three genes encoding the ADC enzymes from Escherichia coli, Corynebacterium glutamicum, and Bacillus subtilis were overexpressed in E. coli. Their properties including specific activity, thermostability, and mechanism-based inactivation were characterized. The ADC enzyme from B. subtilis, which had higher specific activity and thermostability than the others, was selected for further study. In order to improve its activity and relieve its mechanism-based inactivation by molecular engineering so as to improve its catalytic stability, a high-throughput fluorometric assay of β-alanine was developed. From a library of 4000 mutated enzymes, two variants with 18–22% higher specific activity and 29–64% higher catalytic stability were obtained. The best variant showed 50% higher β-alanine production than the wild type after 8 h of conversion of l-aspartate, showing great potential for industrial biocatalytic production of β-alanine.     

A DFT study of the catalytic pyrolysis of benzaldehyde on ZnO, γ-Al<Subscript>2</Subscript>O<Subscript>3</Subscript>, and CaO models

The catalytic pyrolysis pathways of carbonyl compounds in coal were systematically studied using density functional theory (DFT), with benzaldehyde (C₆H₅CHO) employed as a coal-based model compound and ZnO, γ-Al₂O₃, and CaO as catalysts. The results show that the products of both pyrolysis and catalytic pyrolysis are C₆H₆ and CO. However, the presence of any of the catalysts changes the reaction pathway and reduces the energy barrier, indicating that these catalysts promote C₆H₅CHO decomposition.

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Graphical abstract The presence of catalysts changes the reaction pathway and the energy barrier decreases in the order Ea (no catalyst)> Ea (CaO)> Ea (γ-Al₂O₃)> Ea (ZnO), indicating that these catalysts promote C₆H₅CHO decomposition.

     

Rubisco activase – Rubisco's catalytic chaperone

The current status of research on the structure, regulation, mechanism and importance of Rubisco activase is reviewed. The activase is now recognized to be a member of the AAA⁺ family, whose members participate in macromolecular complexes that perform diverse chaperone-like functions. The conserved nucleotide-binding domain of AAA⁺ family members appears to have a common fold that when applied to the activase is generally consistent with previous site-directed mutagenesis studies of the activase. Regulation of the activase in species containing both isoforms can occur via redox changes in the carboxy-terminus of the larger isoform, mediated by thioredoxin-f, which alters the response of activase to the ratio of ADP to ATP in the stroma. Studies of Rubisco activation in transgenic Arabidopsis plants demonstrated that light modulation is dependent on redox regulation of the larger isoform, providing a model for the regulation in other species. Further insights into the mechanism of the activase have emerged from an analysis of the crystal structures of Rubisco conformational variants and the identification of Rubisco residues that confer specificity in its interaction with the activase. The physiological importance of the activase is reinforced by recent studies indicating that it plays a vital role in the response of photosynthesis to temperature. Rubisco activase is one of a new type of chaperone, which in this case functions to promote and maintain the catalytic activity of Rubisco.This revised version was published online in October 2005 with corrections to the Cover Date.     

Expression of the catalytic subunits of pol α and pol δ from fission yeast<Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>

This paper reports on expression and posttranslational modifications of the catalytic subunits of pol α and pol δ from fission yeastSchizosaccharomyces pombe. Okadaic acid treatment ofS. pombe spheroplasts in amounts known to inhibit phosphatases, 1 and 2A resulted in decreased proteolysis of both pol α and pol δ. Computer analysis of pol α and pol δ sequences confirmed the presence of consensus motifs for protein phosphorylation. Indirect immunofluorescence microscopy ofS. pombe cells showed nuclear location of both proteins in wild type cells. However, whereas cells transformed with a vector expressing pol α produced a clear increase of the nuclear signal no increase was detectable in cells transformed with pol δ. This observation suggests the existence of a mechanism limiting thecell concentration of pol δ in the cell. Constitutive expression ofS. pombe pol δ inE. coli was possible only with vectors containing truncated forms of its gene, indicating a toxic effect of pol δ onE. coli growth.     

Effect of the cellulose-binding domain on the catalytic activity of a β-glucosidase from <Emphasis Type="Italic">Saccharomycopsis fibuligera</Emphasis>

Enzyme engineering was performed to link the β-glucosidase enzyme (BGL1) from Saccharomycopsis fibuligera to the cellulose-binding domain (CBD2) of Trichoderma reesei cellobiohydrolase (CBHII) to investigate the effect of a fungal CBD on the enzymatic characteristics of this non-cellulolytic yeast enzyme. Recombinant enzymes were constructed with single and double copies of CBD2 fused at the N-terminus of BGL1 to mimic the two-domain organization displayed by cellulolytic enzymes in nature. The engineered S. fibuligera β-glucosidases were expressed in Saccharomyces cerevisiae under the control of phosphoglycerate-kinase-1 promoter (PGK1 _P ) and terminator (PGK1 _T ) and yeast mating pheromone α-factor secretion signal (MFα1 _S ). The secreted enzymes were purified and characterized using a range of cellulosic and non-cellulosic substrates to illustrate the effect of the CBD on their enzymatic activity. The results indicated that the recombinant enzymes of BGL1 displayed a 2–4-fold increase in their hydrolytic activity toward cellulosic substrates like avicel, amorphous cellulose, bacterial microcrystalline cellulose, and carboxy methyl cellulose in comparison with the native enzyme. The organization of the CBD in these recombinant enzymes also resulted in enhanced substrate affinity, molecular flexibility and synergistic activity, thereby improving the ability of the enzymes to act on and hydrolyze cellulosic substrates, as characterized by adsorption, kinetics, thermal stability, and scanning electron microscopic analyses.     

A chimeric α-amylase engineered from <Emphasis Type="Italic">Bacillus acidicola</Emphasis> and G<Emphasis Type="Italic">eobacillus thermoleovorans</Emphasis> with improved thermostability and catalytic efficiency

The α-amylase (Ba-amy) of Bacillus acidicola was fused with DNA fragments encoding partial N- and C-terminal region of thermostable α-amylase gene of Geobacillus thermoleovorans (Gt-amy). The chimeric enzyme (Ba-Gt-amy) expressed in Escherichia coli displays marked increase in catalytic efficiency [K _cat: 4 × 10⁴ s^?1 and K _cat/K _m: 5 × 10⁴ mL^?1 mg^?1 s^?1] and higher thermostability than Ba-amy. The melting temperature (T _m) of Ba-Gt-amy (73.8 °C) is also higher than Ba-amy (62 °C), and the CD spectrum analysis revealed the stability of the former, despite minor alteration in secondary structure. Langmuir–Hinshelwood kinetic analysis suggests that the adsorption of Ba-Gt-amy onto raw starch is more favourable than Ba-amy. Ba-Gt-amy is thus a suitable biocatalyst for raw starch saccharification at sub-gelatinization temperatures because of its acid stability, thermostability and Ca²⁺ independence, and better than the other known bacterial acidic α-amylases.     

Improved catalytic efficiency of Endo-β-1,4-glucanase from <Emphasis Type="Italic">Bacillus subtilis</Emphasis> BME-15 by directed evolution

Bacillus subtilis endo-β-1,4-glucanase (Cel5A) hydrolyzes cellulose by cleavage of the internal bonds in the glucose chains, producing new ends randomly. Using directed evolution techniques of error-prone polymerase chain reaction (PCR) and DNA shuffling, several Cel5A variants with improved catalytic activity had been screened from the mutant library, which contained 71,000 colonies. Compared with the wild-type enzyme, the variants (M44-11, S75 and S78) showed 2.03 to 2.68-fold increased activities toward sodium carboxymethyl cellulose (CMC), while the M44-11 also exhibited a wider pH tolerance and higher thermostability. Structural models of M44-11, S75, S78, and WT proteins revealed that most of the substitutions were not located in the strictly conserved regions, except the mutation V255A of S75, which was closed to the nucleophile Glu257 in the catalytic center of the enzyme. Moreover, V74A and D272G of M44-11, which were not located in the substrate binding sites and the catalytic center, might result in improved stability and catalytic activity. These results provided useful references for directed evolution of the enzymes that belonged to the glycoside hydrolase family 5 (GH5).     

Domain structures of chlorophyllide<Emphasis Type="Italic"> a</Emphasis> oxygenase of green plants and<Emphasis Type="Italic"> Prochlorothrix hollandica</Emphasis> in relation to catalytic functions

Chlorophyll b is a photosynthetic antenna pigment found in prochlorophytes and chlorophytes. In chlorophytes, its biosynthesis regulates the photosynthetic antenna size. Chlorophyll b is synthesized from chlorophyll a in a two-step oxygenation reaction by chlorophyllide a oxygenase (CAO). In this study, we first identified the entire sequence of a prochlorophyte CAO gene from Prochlorothrix hollandica to compare it with those from chlorophytes, and we examined the catalytic activity of the gene product. Southern blot analysis showed that the CAO gene is presented in one copy in the P. hollandica genome. The P. hollandica CAO gene (PhCAO) has a coding capacity for 367 amino acids, which is much smaller than that of Arabidopsis thaliana (537 amino acids) and Oryza sativa (542 amino acids) CAO genes. In spite of the small size, PhCAO catalyzed the formation of chlorophyll b. By comparing these sequences, we classified the land-plant sequences into four parts: the N-terminal sequence predicted to be a transit peptide, the successive conserved sequence unique in land plants (A-domain, 134 amino acids), a less-conserved sequence (B-domain, 30 amino acids) and the C-terminal conserved sequence common in chlorophytes and prochlorophytes (C-domain, 337 to 344 amino acids). We demonstrated that the C-domain is sufficient for catalytic activity by transforming the cyanobacterium Synechocystis sp. PCC6803 with the C-domain from A. thaliana. In this paper, the role of the A-domain is discussed in relation to the formation of light-harvesting chlorophyll a/b–protein complexes in land plants.Abbreviations CAO Chlorophyllide a oxygenase - CP Chlorophyll protein - HPLC High-performance liquid chromatography - LHC Light-harvesting complex - PCR Polymerase chain reaction - PS Photosystem     

Nitroreductase activity of ferredoxin reductase BphA4 from <Emphasis Type="Italic">Dyella ginsengisoli</Emphasis> LA−4 by catalytic and structural properties analysis

Ferredoxin reductase BphA4 was well known as a component of biphenyl dioxygenase. However, there was little information about whether it could utilize nonphysiological oxidants as electron acceptors. In the present study, we reported the novel nitroreductase activity of BphA4_LA−4. The homology model of ferredoxin reductase BphA4 from Dyella ginsengisoli LA−4 was constructed. According to the alignment of three-dimensional structures, it was supposed that BphA4_LA−4 could function as nitroreductase. Recombinant His-tagged BphA4_LA−4 was purified with a molecular mass of 49.6 ± 1 kDa. Biochemical characterization of purified BphA4_LA−4 possessed the nitroreductase activity with the optimal temperature 50°C and pH 8.0. The substrate spectrum and kinetics indicated BphA4_LA−4 could reduce several nitroaromatics with different apparent K _m values: m-dinitrobenzene (560 μM), o-dinitrobenzene (1,060 μM), o-nitroaniline (1,570 μM), m-nitrobenzoic acid (1,300 μM) and m-nitrophenol (67 μM). The nitroreductase activity was further explained by docking studies, which was indicated that Arg 288 should play an important role in binding nitroaromatics. Moreover, there existed a good linear correlation between lnK _m and calculated binding energy.     

Site-directed mutational analysis of the novel catalytic domains of <Emphasis Type="Italic">α</Emphasis>-aminoadipate reductase (Lys2p) from <Emphasis Type="Italic"> Candida albicans</Emphasis>

The alpha-aminoadipate reductase, a novel enzyme in the alpha-aminoadipic acid pathway for the biosynthesis of lysine in fungi, catalyzes the conversion of alpha-aminoadipic acid to alpha-aminoadipic-delta-semialdehyde in the presence of ATP, NADPH and MgCl(2). This reaction requires two distinct gene products, Lys2p and Lys5p. In the presence of CoA, Lys5p posttranslationally activates Lys2p for the alpha-aminoadipate reductase activity. Sequence alignments indicate the presence of all functional domains required for the activation, adenylation, dehydrogenation and alpha-aminoadipic acid binding in the Lys2p. In this report we present the results of site-directed mutational analysis of the conserved amino acid residues in the catalytic domains of Lys2p from the pathogenic yeast Candida albicans. Mutants were generated in the LYS2 sequence of pCaLYS2SEI by PCR mutagenesis and expressed in E. coli BL21 cells. Recombinant mutants and the wild-type Lys2p were analyzed for their alpha-aminoadipate reductase activity. Substitution of threonine 416, glycine 418, serine 419, and lysine 424 of the adenylation domain (TXGSXXXXK, residues 416-424) resulted in a significant reduction in alpha-aminoadipate reductase activity compared to the unmutagenized Lys2p control. Similarly replacement of glycine 978, threonine 980, glycine 981, phenylalanine 982, leucine 983 and glycine 984 of the NADPH binding domain (GXTGFLG, residues 978-984) caused a drastic decrease in alpha-aminoadipate reductase activity. Finally, substitution of histidine 460, aspartic acid 461, proline 462, isoleucine 463, glutamine 464, arginine 465, and aspartic acid 466 of the putative alpha-aminoadipic acid binding domain (HDPIQRD, residues 460-466) resulted in a highly reduced alpha-aminoadipate reductase activity. These results confirm the hypothesis that specific amino acid residues in highly conserved catalytic domains of Lys2p are essential for the alpha-aminoadipate reductase activity.     

Structure and catalytic mechanism of the β-carbonic anhydrases

The β-carbonic anhydrases (β-CAs) are a diverse but structurally related group of zinc-metalloenzymes found in eubacteria, plant chloroplasts, red and green algae, and in the Archaea. The enzyme catalyzes the rapid interconversion of CO₂ and H₂O to HCO₃⁻ and H⁺, and is believed to be associated with metabolic enzymes that consume or produce CO₂ or HCO₃⁻. For many organisms, β-CA is essential for growth at atmospheric concentrations of CO₂. Of the five evolutionarily distinct classes of carbonic anhydrase, β-CA is the only one known to exhibit allosterism. Here we review the structure and catalytic mechanism of β-CA, including the structural basis for allosteric regulation.     

Glycogen synthase: towards a minimum catalytic unit?

Classically, alpha-1,4-glucan synthases have been divided into two families, animal/fungal glycogen synthases (GS) and bacterial/plant starch synthases (G(S)S), according to differences in sequence, sugar donor specificity and regulatory mechanisms. Detailed sequence analysis, predicted secondary structure comparison and threading analysis show that these two families are structurally related and that some domains of GSs were acquired to meet regulatory requirements. Archaeal G(S)S present structural and functional features that are conserved in one, the other or both families. Therefore, they are the link between GS and G(S)S and harbor the minimal sequence and structural features that constitute the minimum catalytic unit of the alpha-1,4-glucan synthase superfamily.     

Do bacterial L-asparaginases utilize a catalytic triad Thr-Tyr-Glu?

The structures of Erwinia chrysanthemi L-asparaginase (ErA) complexed with the L- and D-stereoisomers of the suicide inhibitor, 6-diazo-5-oxy-norleucine, have been solved using X-ray crystallography and refined with data extending to 1.7 A. The distances between the Calpha atoms of the inhibitor molecules and the hydroxyl oxygen atoms of Thr-15 and Tyr-29 (1.20 and 1.60 A, respectively) clearly indicate the presence of covalent bonds between these moieties, confirming the nucleophilic role of Thr-15 during the first stage of enzymatic reactions and also indicating direct involvement of Tyr-29. The factors responsible for activating Tyr-29 remain unclear, although some structural changes around Ser-254', Asp-96, and Glu-63, common to both complexes, suggest that those residues play a function. The role of Glu-289' as the activator of Tyr-29, previously postulated for the closely related Pseudomonas 7A L-glutaminase-asparaginase, is not confirmed in this study, due to the lack of interactions between these residues in these complexes and in holoenzymes. The results reported here are consistent with previous reports that mutants of Escherichia coli L-asparaginase lacking Glu-289 remain catalytically active and prove the catalytic roles of both Thr-15 and Tyr-29, while still leaving open the question of the exact mechanism resulting in the unusual chemical properties of these residues.     

Essential cysteine residues for human RNase κ catalytic activity

Human RNase κ is an endoribonuclease expressed in almost all tissues and organs and belongs to a highly conserved protein family bearing representatives in all metazoans. To gain insight into the role of cysteine residues in the enzyme activity or structure, a recombinant active form of human RNase κ expressed in Pichia pastoris was treated with alkylating agents and dithiothreitol (DTT). Our results showed that the human enzyme is inactivated by DDT, while it remains fully active in the presence of alkylating agents. The unreduced recombinant protein migrates on SDS/PAGE faster than the reduced form. This observation in combination with the above findings indicated that human RNase κ does not form homodimers through disulfide bridges, and cysteine residues are not implicated in RNA catalysis but participate in the formation of intramolecular disulfide bond(s) essential for its ribonucleolytic activity. The role of the cysteine residues was further investigated by expression and study of Cys variants. Ribonucleolytic activity experiments and SDS/PAGE analysis of the wild-type and mutant proteins under reducing and non-reducing conditions demonstrated that Cys7, Cys14 and Cys85 are not essential for RNase activity. On the other hand, replacement of Cys6 or Cys69 with serine led to a complete loss of catalytic activity, indicating the necessity of these residues for maintaining an active conformation of human RNase κ by forming a disulfide bond. Due to the absolute conservation of these cysteine residues, the Cys6-Cys69 disulfide bond is likely to exist in all RNase κ family members.     

High-yield production,refolding and a molecular modelling of the catalytic module of (1,3)-β-<Emphasis Type="SmallCaps">d</Emphasis>-glucan (curdlan) synthase from <Emphasis Type="Italic">Agrobacterium</Emphasis> sp.

Biosynthesis of the (1,3)-β-d-glucan (curdlan) in Agrobacterium sp., is believed to proceed by the repetitive addition of glucosyl residues from UDP-glucose by a membrane-embedded curdlan synthase (CrdS) [UDP-glucose: (1,3)-β-d-glucan 3-β-d-glucosyltransferase; EC 2.4.1.34]. The catalytic module of CrdS (cm-CrdS) was expressed in good yield from a cDNA encoding cm-CrdS cloned into the pET-32a(+) vector, containing a coding region for thioredoxin, and from the Champion™ pET SUMO system that possesses a coding region of a small ubiquitin-related modifier (SUMO) partner protein. The two DNA fusions, designated pET-32a_cm-CrdS and SUMO_cm-CrdS were expressed as chimeric proteins. High yields of inclusion bodies were produced in E. coli and these could be refolded to form soluble proteins, using a range of buffers and non-detergent sulfobetaines. A purification protocol was developed, which afforded a one-step on-column refolding and simultaneous purification of the recombinant 6xHis-tagged SUMO_cm-CrdS protein. The latter protein was digested by a specific protease to yield intact cm-CrdS in high yields. The refolded SUMO_cm-CrdS protein did not exhibit curdlan synthase activity, but showed a circular dischroism spectrum, which had an α/β-type-like conformation. Amino acid sequences of tryptic fragments of the SUMO_cm-CrdS fusion and free cm-CrdS proteins, determined by MALDI/TOF confirmed that the full-length proteins were synthesized by E. coli, and that no alterations in amino acid sequences occurred. A three-dimensional model of cm-CrdS predicted the juxtaposition of highly conserved aspartates D156, D208, D210 and D304, and the QRTRW motif, which are likely to play roles in donor and acceptor substrate binding and catalysis.     

γ-Glutamyl transpeptidase: catalytic,structural and functional aspects

Summary -Glutamyl transpeptidase catalyzes transfer of the -glutamyl moiety of glutathione to amino acids, dipeptides, and to glutathione itself; the enzyme also catalyzes the hydrolysis of glutathione to glutamate and cysteinyl-glycine. This review deals with the tissue distribution and localization of the enzyme in mammals, the catalytic properties of the enzyme (including its inhibition by reversible and irreversible inhibitors), structural studies on the enzyme, and new findings about its physiological function.     

At what temperature can enzymes maintain their catalytic activity?

It was shown by the combination of thermogravimetric analysis and Karl Fisher titrations that temperatures in excess of 200 degrees C are required to remove tightly bound water from proteins. The heating of enzymes to this temperature caused no cleavage of the polypeptide chains and very little, if any, chemical degradation of particular amino acid residues as judged by electrophoretic and amino acid analysis respectively. It was hypothesised that those enzymes that require very little water for their catalytic activity, should remain active at such elevated temperatures provided that they can be stabilised against thermodenaturation. This conclusion has been verified by the observation that immobilised Candida antarctica lipase catalysed transesterification of octadecanol with palmityl stearate at 130 degrees C for a considerable period of time.     

Fusion of <Emphasis Type="Italic">Bacillus stearothermophilus</Emphasis> leucine aminopeptidase II with the raw-starch-binding domain of <Emphasis Type="Italic">Bacillus</Emphasis> sp. strain TS-23 α-amylase generates a chimeric enzyme with enhanced thermostability and catalytic activity

Bacillus stearothermophilus leucine aminopeptidase II (LAPII) was fused at its C-terminal end with the raw-starch-binding domain of Bacillus sp. strain TS-23 -amylase. The chimeric enzyme (LAPsbd), with an apparent molecular mass of approximately 61 kDa, was overexpressed in IPTG-induced Escherichia coli cells and purified to homogeneity by nickel-chelate chromatography. The purified enzyme retained LAP activity and adsorbed raw starch. LAPsbd was stable at 70°C for 10 min, while the activity of wild-type enzyme was completely abolished under the same environmental condition. Compared with the wild-type enzyme, the twofold increase in the catalytic efficiency for LAPsbd was due to a 218% increase in the k _cat value.