Replacement of Active-Site Residues of Quinoline 2-Oxidoreductase Involved in Substrate Recognition and Specificity

Amino acid residues in the active site of quinoline 2-oxidoreductase (Qor) that are deemed important for substrate binding and turnover were replaced by site-directed mutagenesis. The apparent k_cat values for quinoline were reduced 2.4-, 38-, 40-, and 199-fold in the protein variants QorA259G, QorW331G, QorV373A, and QorA546G, respectively. The substitution A259G did not significantly alter K_{m app}. Despite the presumed crucial role of W331 and V373 in substrate positioning, the replacements W331G (K_{m app}: 0.33 mM) and V373A (K_{m app}: 0.41 mM) only slightly affected affinity for quinoline (K_{m app} of Qor: 0.12 mM). QorA546G showed an increased affinity for quinoline and quinoxaline, as suggested by its 4.3- and 7.5-fold decrease in K_{m app (quinoline)} and K_{m app (quinoxaline)}, respectively, compared with Qor. The relative activities of the protein variants towards substituted quinolines differed from those of Qor. QorW331G, for example, may be suitable for hydroxylation of quinoxaline and C4-substituted quinolines.     

Molecular Characterization and Substrate Specificity of Nitrobenzene Dioxygenase from Comamonas sp. Strain JS765

Comamonas sp. strain JS765 can grow with nitrobenzene as the sole source of carbon, nitrogen, and energy. We report here the sequence of the genes encoding nitrobenzene dioxygenase (NBDO), which catalyzes the first step in the degradation of nitrobenzene by strain JS765. The components of NBDO were designated Reductase_NBZ, Ferredoxin_NBZ, Oxygenase_NBZα, and Oxygenase_NBZβ, with the gene designations nbzAa, nbzAb, nbzAc, and nbzAd, respectively. Sequence analysis showed that the components of NBDO have a high level of homology with the naphthalene family of Rieske nonheme iron oxygenases, in particular, 2-nitrotoluene dioxygenase from Pseudomonas sp. strain JS42. The enzyme oxidizes a wide range of substrates, and relative reaction rates with partially purified Oxygenase_NBZ revealed a preference for 3-nitrotoluene, which was shown to be a growth substrate for JS765. NBDO is the first member of the naphthalene family of Rieske nonheme iron oxygenases reported to oxidize all of the isomers of mono- and dinitrotoluenes with the concomitant release of nitrite.     

Alteration of the Substrate Specificity of the Angular Dioxygenase Carbazole 1,9a-Dioxygenase

Carbazole 1,9a-dioxygenase (CARDO) consists of terminal oxygenase (CARDO-O) and electron transport components. CARDO can catalyze specific oxygenation for various substrates: angular dioxygenation for carbazole and dibenzo-p-dioxin, lateral dioxygenation for anthracene, and monooxygenation for methylene carbon of fluorene and sulfide sulfur of dibenzothiophene. To elucidate the molecular mechanism determining its unique substrate specificity, 17 CARDO-O site-directed mutants at amino acid residues I262, F275, Q282, and F329, which form the substrate-interacting wall around the iron active site by CARDO-O crystal structure, were generated and characterized. F329 replacement dramatically reduced oxygenation activity. However, several mutants produced different products from the wild-type enzyme to a large extent: I262V and Q282Y (1-hydroxycarbazole), F275W (4-hydroxyfluorene), F275A (unidentified cis-dihydrodiol of fluoranthene), and I262A and I262W (monohydroxydibenzothiophenes). These results suggest the possibility that the respective substrates bind to the active sites of CARDO-O mutants in a different orientation from that of the wild-type enzyme.     

Bacillus sphaericus Penicillin V Acylase: Purification,Substrate Specificity,and Active-Site Characterization

Penicillin V acylase from Bacillus sphaericus was purified to homogeneity with an overall yield of 15%. The enzyme exhibited comparatively high specificity for penicillin V, penicillin G, and other related compounds being hydrolyzed at less than 10% of the rate of penicillin V. Moreover, the high rate of hydrolysis was observed when the side chain of the substrate molecule was unsubstituted. Lysine-modifying reagents inactivated the enzyme rapidly. Kinetics and titration studies indicated the involvement of lysine in the catalytic activity of the enzyme. Received: 10 July 1996 / Accepted: 26 August 1996     

Determination of Residues Responsible for Substrate and Product Specificity of Solanum habrochaites Short-Chain cis-Prenyltransferases

Prenyl residues confer divergent biological activities such as antipathogenic and antiherbivorous activities on phenolic compounds, including flavonoids, coumarins, and xanthones. To date, about 1,000 prenylated phenolics have been isolated, with these compounds containing various prenyl residues. However, all currently described plant prenyltransferases (PTs) have been shown specific for dimethylallyl diphosphate as the prenyl donor, while most of the complementary DNAs encoding these genes have been isolated from the Leguminosae. In this study, we describe the identification of a novel PT gene from lemon (Citrus limon), ClPT1, belonging to the homogentisate PT family. This gene encodes a PT that differs from other known PTs, including flavonoid-specific PTs, in polypeptide sequence. This membrane-bound enzyme was specific for geranyl diphosphate as the prenyl donor and coumarin as the prenyl acceptor. Moreover, the gene product was targeted to plastid in plant cells. To our knowledge, this is the novel aromatic PT specific to geranyl diphosphate from citrus species.Prenylation is an important derivatization of plant aromatics, contributing to the chemical diversification of phenolic secondary metabolites in plants due to differences in prenylation positions, prenyl chain lengths, and further modifications of prenyl chains. To date, about 1,000 prenylated aromatic compounds have been isolated as biologically active substances from various plant species, including many medicinal plants.Coumarins (α-benzopyrones) are a large group of plant secondary metabolites. Many biologically active coumarins are prenylated, with the prenyl residue enhancing the biological activities of the aromatic core compound. For example, imperatorin (dimethylallylated xanthotoxol), a strong inhibitor of a Manduca sexta midgut cytochrome P450, has 100-fold greater activity than the nonprenylated coumarin compound, suggesting that prenylation is involved in chemoprevention against biotic stress in plants (Neal and Wu, 1994). Prenylated compounds are also beneficial for human health. For example, geranylation of umbelliferone at the OH position to form auraptene results in a 25-fold enhancement of the inhibition of Epstein Barr virus activity, a test used to screen antitumor compounds (Murakami et al., 1997). Moreover, in tuberculosis, 8-geranyloxypsoralen was reported to decrease the growth rate of Mycobacterium smegmatis (Adams et al., 2006).There are many reports on the detection of prenyltransferase (PT) activities for coumarins in various plant species. For example, umbelliferone-dimethylallyltransferase activities were reported in cultured parsley (Petroselinum crispum) cells, Ruta graveolens, and Ammi majus, and plastidial localization of the enzyme activity is also reported (Ellis and Brown, 1974; Dhillon and Brown, 1976; Tietjen and Matern, 1983; Hamerski and Matern, 1988; Hamerski et al., 1990). In addition, bergaptol 5-O-geranyltransferase activity, which yields bergamottin, a major coumarin derivative, was characterized using the microsomal fraction of lemon (Citrus limon) peel flavedo, the outer part of the lemon fruit (Frérot and Decorzant, 2004; Munakata et al., 2012). In the lemon flavedo, 8-geranyltransferase activity for umbelliferone was also detected (Munakata et al., 2012). To date, only one gene encoding these enzymes has been described; this gene, which encodes a parsley PT (PcPT), was very recently isolated (Karamat et al., 2014).The first flavonoid-specific PT identified was naringenin 8-dimethylallyltransferase (SfN8DT1) from a leguminous medicinal plant, Sophora flavescens (Sasaki et al., 2008). Since then, genes encoding various flavonoid PTs have been identified in Leguminosae (Akashi et al., 2009; Sasaki et al., 2011; Shen et al., 2012). Although other prenylated aromatic compounds, including coumarins, xanthons, phenylpropanoids, and phloroglucinols, have been isolated from many plant species, no gene encoding a PT for those aromatics has been isolated, except for the gene encoding a phloroglucinol-specific enzyme (HlPT1) from hops (Humulus lupulus) and a the recently isolated coumarin dimethylallyltransferase from parsley (Tsurumaru et al., 2010, 2012; Karamat et al., 2014). These isolated plant aromatic PTs show strong preference for dimethylallyl diphosphate (DMAPP) as the prenyl donor substrate, although in nature, many geranylated phenolics and less farnesylated phenolics have been described. This raises questions about the enzymes and reaction mechanisms involved in the synthesis of these phenolic compounds, such as substrate specificity and prenylation sites. Better understanding of these reactions requires the identification of PTs with other enzymatic activities. It is also necessary to identify PTs producing prenylated phenolics in nonleguminosaeous plants. Four different tracks should be explored to identify enzymes that (1) recognize nonflavonoid substrates, e.g. coumarins, phenylpropanoids, and xanthons, (2) are specific for longer chain prenyl diphosphates such as geranyl diphosphate (GPP) and farnesyl diphosphate (FPP), (3) are from nonlegume origins, and (4) catalyze O-prenylation.Citrus species, including lemons, contain large quantities of geranylated coumarins. We therefore isolated a complementary DNA (cDNA) encoding a PT from lemon peel, identifying the novel PT-encoding gene ClPT1. Phylogenetic analysis showed that this enzyme shares homologies with homogentisate PTs involved in vitamin E and plastoquinone biosynthesis but is located in a new clade. We provide evidence showing that this unique enzyme is highly specific for GPP as a prenyl donor and coumarin as a prenyl acceptor. We also show that the gene product is targeted to plastid in plant cells.     

Amino Acid Residues Contributing to the Substrate Specificity of the Influenza A Virus Neuraminidase

Influenza A viruses possess two glycoprotein spikes on the virion surface: hemagglutinin (HA), which binds to oligosaccharides containing terminal sialic acid, and neuraminidase (NA), which removes terminal sialic acid from oligosaccharides. Hence, the interplay between these receptor-binding and receptor-destroying functions assumes major importance in viral replication. In contrast to the well-characterized role of HA in host range restriction of influenza viruses, there is only limited information on the role of NA substrate specificity in viral replication among different animal species. We therefore investigated the substrate specificities of NA for linkages between N-acetyl sialic acid and galactose (NeuAcalpha2-3Gal and NeuAcalpha2-6Gal) and for different molecular species of sialic acids (N-acetyl and N-glycolyl sialic acids) in influenza A viruses isolated from human, avian, and pig hosts. Substrate specificity assays showed that all viruses had similar specificities for NeuAcalpha2-3Gal, while the activities for NeuAcalpha2-6Gal ranged from marginal, as represented by avian and early N2 human viruses, to high (although only one-third the activity for NeuAcalpha2-3Gal), as represented by swine and more recent N2 human viruses. Using site-specific mutagenesis, we identified in the earliest human virus with a detectable increase in NeuAcalpha2-6Gal specificity a change at position 275 (from isoleucine to valine) that enhanced the specificity for this substrate. Valine at position 275 was maintained in all later human viruses as well as swine viruses. A similar examination of N-glycolylneuraminic acid (NeuGc) specificity showed that avian viruses and most human viruses had low to moderate activity for this substrate, with the exception of most human viruses isolated between 1967 and 1969, whose NeuGc specificity was as high as that of swine viruses. The amino acid at position 431 was found to determine the level of NeuGc specificity of NA: lysine conferred high NeuGc specificity, while proline, glutamine, and glutamic acid were associated with lower NeuGc specificity. Both residues 275 and 431 lie close to the enzymatic active site but are not directly involved in the reaction mechanism. This finding suggests that the adaptation of NA to different substrates occurs by a mechanism of amino acid substitutions that subtly alter the conformation of NA in and around the active site to facilitate the binding of different species of sialic acid.     

Substrate Binding Mechanism of a Type I Extradiol Dioxygenase

A meta-cleavage pathway for the aerobic degradation of aromatic hydrocarbons is catalyzed by extradiol dioxygenases via a two-step mechanism: catechol substrate binding and dioxygen incorporation. The binding of substrate triggers the release of water, thereby opening a coordination site for molecular oxygen. The crystal structures of AkbC, a type I extradiol dioxygenase, and the enzyme substrate (3-methylcatechol) complex revealed the substrate binding process of extradiol dioxygenase. AkbC is composed of an N-domain and an active C-domain, which contains iron coordinated by a 2-His-1-carboxylate facial triad motif. The C-domain includes a β-hairpin structure and a C-terminal tail. In substrate-bound AkbC, 3-methylcatechol interacts with the iron via a single hydroxyl group, which represents an intermediate stage in the substrate binding process. Structure-based mutagenesis revealed that the C-terminal tail and β-hairpin form part of the substrate binding pocket that is responsible for substrate specificity by blocking substrate entry. Once a substrate enters the active site, these structural elements also play a role in the correct positioning of the substrate. Based on the results presented here, a putative substrate binding mechanism is proposed.     

Control of Substrate Gating and Translocation into ClpP by Channel Residues and ClpX Binding

ClpP is a self-compartmentalized protease, which has very limited degradation activity unless it associates with ClpX to form ClpXP or with ClpA to form ClpAP. Here, we show that ClpX binding stimulates ClpP cleavage of peptides larger than a few amino acids and enhances ClpP active-site modification. Stimulation requires ATP binding but not hydrolysis by ClpX. The magnitude of this enhancement correlates with increasing molecular weight of the molecule entering ClpP. Amino-acid substitutions in the channel loop or helix A of ClpP enhance entry of larger substrates into the free enzyme, eliminate ClpX binding in some cases, and are not further stimulated by ClpX binding in other instances. These results support a model in which the channel residues of free ClpP exclude efficient entry of all but the smallest peptides into the degradation chamber, with ClpX binding serving to relieve these inhibitory interactions. Specific ClpP channel variants also prevent ClpXP translocation of certain amino-acid sequences, suggesting that the wild-type channel plays an important role in facilitating broad translocation specificity. In combination with previous studies, our results indicate that collaboration between ClpP and its partner ATPases opens a gate that functions to exclude larger substrates from isolated ClpP.     

Substrate Specificity of Cytoplasmic N-Glycosyltransferase

N-Linked protein glycosylation is a very common post-translational modification that can be found in all kingdoms of life. The classical, highly conserved pathway entails the assembly of a lipid-linked oligosaccharide and its transfer to an asparagine residue in the sequon NX(S/T) of a secreted protein by the integral membrane protein oligosaccharyltransferase. A few species in the class of γ-proteobacteria encode a cytoplasmic N-glycosylation system mediated by a soluble N-glycosyltransferase (NGT). This enzyme uses nucleotide-activated sugars to modify asparagine residues with single monosaccharides. As these enzymes are not related to oligosaccharyltransferase, NGTs constitute a novel class of N-glycosylation catalyzing enzymes. To characterize the NGT-catalyzed reaction, we developed a sensitive and quantitative in vitro assay based on HPLC separation and quantification of fluorescently labeled substrate peptides. With this assay we were able to directly quantify glycopeptide formation by Actinobacillus pleuropneumoniae NGT and determine its substrate specificities: NGT turns over a number of different sugar donor substrates and allows for activation by both UDP and GDP. Quantitative analysis of peptide substrate turnover demonstrated a strikingly similar specificity as the classical, oligosaccharyltransferase-catalyzed N-glycosylation, with NX(S/T) sequons being the optimal NGT substrates.     

Role of the Residues of the 39-Loop in Determining the Substrate and Inhibitor Specificity of Factor IXa

The activation of antithrombin (AT) by heparin facilitates the exosite-dependent interaction of the serpin with factors IXa (FIXa) and Xa (FXa), thereby improving the rate of reactions by 300- to 500-fold. Relative to FXa, AT inhibits FIXa with ∼40-fold slower rate constant. Structural data suggest that differences in the residues of the 39-loop (residues 31–41) may partly be responsible for the differential reactivity of the two proteases with AT. This loop is highly acidic in FXa, containing three Glu residues at positions 36, 37, and 39. By contrast, the loop is shorter by one residue in FIXa (residue 37 is missing), and it contains a Lys and an Asp at positions 36 and 39, respectively. To determine whether differences in the residues of this loop contribute to the slower reactivity of FIXa with AT, we prepared an FIXa/FXa chimera in which the 39-loop of the protease was replaced with the corresponding loop of FXa. The chimeric mutant cleaved a FIXa-specific chromogenic substrate with normal catalytic efficiency, however, the mutant exhibited ∼5-fold enhanced reactivity with AT specifically in the absence of the cofactor, heparin. Further studies revealed that the FIXa mutant activates factor X with ∼4-fold decreased k_cat and ∼2-fold decreased K_m, although the mutant interacted normally with factor VIIIa. Based on these results we conclude that residues of the 39-loop regulate the cofactor-independent interaction of FIXa with its physiological inhibitor AT and substrate factor X.     

Insight into the Role of Substrate-binding Residues in Conferring Substrate Specificity for the Multifunctional Polysaccharide Lyase Smlt1473

Anionic polysaccharides are of growing interest in the biotechnology industry due to their potential pharmaceutical applications in drug delivery and wound treatment. Chemical composition and polymer length strongly influence the physical and biological properties of the polysaccharide and thus its potential industrial and medical applications. One promising approach to determining monomer composition and controlling the degree of polymerization involves the use of polysaccharide lyases, which catalyze the depolymerization of anionic polysaccharides via a β-elimination mechanism. Utilization of these enzymes for the production of custom-made oligosaccharides requires a high degree of control over substrate specificity. Previously, we characterized a polysaccharide lyase (Smlt1473) from Stenotrophomonas maltophilia k279a, which exhibited significant activity against hyaluronan (HA), poly-β-d-glucuronic acid (poly-GlcUA), and poly-β-d-mannuronic acid (poly-ManA) in a pH-regulated manner. Here, we utilize a sequence structure guided approach based on a homology model of Smlt1473 to identify nine putative substrate-binding residues and examine their effect on substrate specificity via site-directed mutagenesis. Interestingly, single point mutations H221F and R312L resulted in increased activity and specificity toward poly-ManA and poly-GlcUA, respectively. Furthermore, a W171A mutant nearly eliminated HA activity, while increasing poly-ManA and poly-GlcUA activity by at least 35%. The effect of these mutations was analyzed by comparison with the high resolution structure of Sphingomonas sp. A1-III alginate lyase in complex with poly-ManA tetrasaccharide and by taking into account the structural differences between HA, poly-GlcUA, and poly-ManA. Overall, our results demonstrate that even minor changes in active site architecture have a significant effect on the substrate specificity of Smlt1473, whose structural plasticity could be applied to the design of highly active and specific polysaccharide lyases.     

Characterization of Active-Site Residues of the NIa Protease from Tobacco Vein Mottling Virus

Nuclear inclusion a (NIa) protease of tobacco vein mottling virus is responsible for the processing of the viral polyprotein into functional proteins. In order to identify the active-site residues of the TVMV NIa protease, the putative active-site residues, His-46, Asp-81 and Cys-151, were mutated individually to generate H46R, H46A, D81E, D81N, C151S, and C151A, and their mutational effects on the proteolytic activities were examined. Proteolytic activity was completely abolished by the mutations of H46R, H46A, D81N, and C151A, suggesting that the three residues are crucial for catalysis. The mutation of D81E decreased k_cat marginally by about 4.7-fold and increased K_m by about 8-fold, suggesting that the aspartic acid at position 81 is important for substrate binding but can be substituted by glutamate without any significant decrease in catalysis. The replacement of Cys-151 by Ser to mimic the catalytic triad of chymotrypsin-like serine protease resulted in the drastic decrease in k_cat by about 1,260-fold. This result might be due to the difference of the active-site geometry between the NIa protease and chymotrypsin. The protease exhibited a bell-shaped pH-dependent profile with a maximum activity approximately at pH 8.3 and with the abrupt changes at the respective pK_m values of approximately 6.6 and 9.2, implying the involvement of a histidine residue in catalysis. Taken together, these results demonstrate that the three residues, His-46, Asp-81, and Cys-151, play a crucial role in catalysis of the TVMV NIa protease.     

Kinetic Origin of Substrate Specificity in Post-Transfer Editing by Leucyl-tRNA Synthetase

The intrinsic editing capacities of aminoacyl-tRNA synthetases ensure a high-fidelity translation of the amino acids that possess effective non-cognate aminoacylation surrogates. The dominant error-correction pathway comprises deacylation of misaminoacylated tRNA within the aminoacyl-tRNA synthetase editing site. To assess the origin of specificity of Escherichia coli leucyl-tRNA synthetase (LeuRS) against the cognate aminoacylation product in editing, we followed binding and catalysis independently using cognate leucyl- and non-cognate norvalyl-tRNA^Leu and their non-hydrolyzable analogues. We found that the amino acid part (leucine versus norvaline) of (mis)aminoacyl-tRNAs can contribute approximately 10-fold to ground-state discrimination at the editing site. In sharp contrast, the rate of deacylation of leucyl- and norvalyl-tRNA^Leu differed by about 10⁴-fold. We further established the critical role for the A76 3′-OH group of the tRNA^Leu in post-transfer editing, which supports the substrate-assisted deacylation mechanism. Interestingly, the abrogation of the LeuRS specificity determinant threonine 252 did not improve the affinity of the editing site for the cognate leucine as expected, but instead substantially enhanced the rate of leucyl-tRNA^Leu hydrolysis. In line with that, molecular dynamics simulations revealed that the wild-type enzyme, but not the T252A mutant, enforced leucine to adopt the side-chain conformation that promotes the steric exclusion of a putative catalytic water. Our data demonstrated that the LeuRS editing site exhibits amino acid specificity of kinetic origin, arguing against the anticipated prominent role of steric exclusion in the rejection of leucine. This feature distinguishes editing from the synthetic site, which relies on ground-state discrimination in amino acid selection.     

Identification of Residues Involved in Substrate Specificity and Cytotoxicity of Two Closely Related Cutinases from Mycobacterium tuberculosis

The enzymes belonging to the cutinase family are serine enzymes active on a large panel of substrates such as cutin, triacylglycerols, and phospholipids. In the M. tuberculosis H37Rv genome, seven genes coding for cutinase-like proteins have been identified with strong immunogenic properties suggesting a potential role as vaccine candidates. Two of these enzymes which are secreted and highly homologous, possess distinct substrates specificities. Cfp21 is a lipase and Cut4 is a phospholipase A₂, which has cytotoxic effects on macrophages. Structural overlay of their three-dimensional models allowed us to identify three areas involved in the substrate binding process and to shed light on this substrate specificity. By site-directed mutagenesis, residues present in these Cfp21 areas were replaced by residues occurring in Cut4 at the same location. Three mutants acquired phospholipase A₁ and A₂ activities and the lipase activities of two mutants were 3 and 15 fold greater than the Cfp21 wild type enzyme. In addition, contrary to mutants with enhanced lipase activity, mutants that acquired phospholipase B activities induced macrophage lysis as efficiently as Cut4 which emphasizes the relationship between apparent phospholipase A₂ activity and cytotoxicity. Modification of areas involved in substrate specificity, generate recombinant enzymes with higher activity, which may be more immunogenic than the wild type enzymes and could therefore constitute promising candidates for antituberculous vaccine production.     

表面电荷突变与胰蛋白酶底物专一性的改造

分别利用酶切重组和“３＋１”引物ＰＣＲ定点突变的方法构建了三个胰蛋白酶表面电荷双突变体：Ｒ６２Ｄ＋Ｋ９７Ｅ、Ｒ６２Ｄ＋Ｋ１７５Ｅ和Ｋ９７Ｅ＋Ｋ１７５Ｅ．对三者在Ｅ．ｃｏｌｉＸ－９０菌中的表达产物进行了动力学测定,分别得到了三种双突变体在两种ｐＨ条件下,水解ＴＡＭＥ、ＴＬＭＥ两种底物的动力学数据．结果表明,Ｒ６２Ｄ＋Ｋ１７５Ｅ和Ｋ９７Ｅ＋Ｋ１７５Ｅ在ｐＨ６．８５时,对两种底物的催化活性与野生型相比下降了２～３个数量级,当ｐＨ升高至８．８５时,它们的活性基本丧失;双突变体Ｒ６２Ｄ＋Ｋ９７Ｅ虽然催化活性也有所降低,但随着ｐＨ的升高,它对Ｌｙｓ底物的特异性（选择性系数２５倍于Ａｒｇ底物）转变为对Ａｒｇ底物略高的特异性,基本符合分子设计．实验结果还表明,各种双突变体催化活性的降低主要是由于酶和底物的亲和力降低引起的．     

Cloning and Molecular Modeling of Duodenase with Respect to Evolution of Substrate Specificity within Mammalian Serine Proteases That Have Lost a Conserved Active-Site Disulfide Bond

Mammalian serine proteases such as the chromosome 14 (Homo sapiens, Mus musculus) located granzymes, chymases, cathepsin G, and related enzymes including duodenase collectively represent a special group within the chymotrypsin family which we refer to here as "granases". Enzymes of this group have lost the ancient active-site disulfide bond Cys191-Cys220 (bovine chymotrypsinogen A numbering) which is strongly conserved in classic serine proteases such as pancreatic, blood coagulation, and fibrinolysis proteases and others (granzymes A, M, K and leukocyte elastases). We sequenced the cDNA encoding bovine (Bos taurus) duodenase, a granase with unusual dual trypsin-like and chymotrypsin-like specificity. The sequence revealed a 17-residue signal peptide and two-residue (GlyLys) activation peptide typical for granases. Production of the mature enzyme is apparently accompanied by further proteolytic processing of the C-terminal pentapeptide extension of duodenase. Similar C-terminal processing is known for another dual-specific granase, human cathepsin G. Using phylogenetic analysis based on 39 granases we retraced the evolution of residues 189 and 226 crucial for serine protease primary specificity. The analysis revealed that while there is no obvious link between mutability of residue 189 and the appearance of novel catalytic properties in granases, the mutability of residue 226 evidently gives rise to different specificity subgroups within this enzyme group. The architecture of the extended substrate-binding site of granases and structural basis of duodenase dual specificity based on molecular dynamic method are discussed. We conclude that the marked selectivity of granases that is crucial to their role as regulatory proteases has evolved through the fine-tuning of specificity at three levels--primary, secondary, and conformational.     

Substrate Specificity of Nuclease P1

Nuclease P₁ cleaved substantially all phosphodiester bonds in rRNA, tRNA, poly(I), poly(U), poly(A), poly(C), poly(G), poly(I)·poly(C), native DNA and heat-denatured DNA to produce exclusively 5′-mononucleotides. Single-stranded polynucleotides were much more susceptible than double-stranded ones. Influence of pH and ionic strength on the hydrolysis rate significantly varied with the kind of polynucleotides. The enzyme also hydrolyzed 3′-phosphomonoester bonds in 3′-AMP, 3′-GMP, 3′-UMP, 3′-CMP, 3′-dAMP, 3′-dGMP, 3′-dCMP and 3′-dTMP. Ribonucleoside 3′-monophosphates were hydrolyzed 20 to 50 times faster than the corresponding 3′-deoxyribonucleotides. Base preference of the enzyme for 3′-ribonucleotides was in the order of G>A>C≧U, whereas that for 3′-deoxyribo-nucleotides was in the order of C≧T>A≧G. The 3′-phosphomonoester bonds in nucleoside 3′, 5′-diphosphates, coenzyme A and dinucleotides bearing 3′-phosphate were hydrolyzed at a rate similar to that for the corresponding 3′-mononucleotides. Adenosine 2′-monophosphate was highly resistant, being split at less than 1/3,000 the rate at which 3′-AMP was split.     

Substrate Specificities of Hybrid Naphthalene and 2,4-Dinitrotoluene Dioxygenase Enzyme Systems

Bacterial three-component dioxygenase systems consist of reductase and ferredoxin components which transfer electrons from NAD(P)H to a terminal oxygenase. In most cases, the oxygenase consists of two different subunits (α and β). To assess the contributions of the α and β subunits of the oxygenase to substrate specificity, hybrid dioxygenase enzymes were formed by coexpressing genes from two compatible plasmids in Escherichia coli. The activities of hybrid naphthalene and 2,4-dinitrotoluene dioxygenases containing four different β subunits were tested with four substrates (indole, naphthalene, 2,4-dinitrotoluene, and 2-nitrotoluene). In the active hybrids, replacement of small subunits affected the rate of product formation but had no effect on the substrate range, regiospecificity, or enantiomeric purity of oxidation products with the substrates tested. These studies indicate that the small subunit of the oxygenase is essential for activity but does not play a major role in determining the specificity of these enzymes.     

Purification and Substrate Specificity of Yeast Isoamylase

Yeast isoamylase was highly purified by means of salting-out with ammonium sulfate, chromatography on DEAE-cellulose, and gel filtration on Sephadex G-100. More than 200-fold purification was achieved through these procedures from crude yeast extract. While the purified enzyme did not attack α-1, 6-glucosidic linkages in panose, isopanose (6-malto-sylglucose), branched triose (4,6-diglucosylglucose), and isomaltosylmaltose (6³-α-glucosylmaltotriose), it acted on α,β-limit dextrin to liberate glucose as well as maltose and higher oligosaccharides. Substrate specificity of the yeast isoamylase was discussed in comparison with that of plant and bacterial isoamylases (R-enzvme and pullulanase), and the mechanism of debranching of glycogen by yeast enzymes was also discussed.