Identification of residues critical for metallo-β-lactamase function by codon randomization and selection

IMP-1 beta-lactamase is a zinc metallo-enzyme encoded by the transferable bla(IMP-1) gene, which confers resistance to virtually all beta-lactam antibiotics including carbapenems. To understand how IMP-1 recognizes and hydrolyzes beta-lactam antibiotics it is important to determine which amino acid residues are critical for catalysis and which residues control substrate specificity. We randomized 27 individual codons in the bla(IMP-1) gene to create libraries that contain all possible amino acid substitutions at residue positions in and near the active site of IMP-1. Mutants from the random libraries were selected for the ability to confer ampicillin resistance to Escherichia coli. Of the positions randomized, >50% do not tolerate amino acid substitutions, suggesting they are essential for IMP-1 function. The remaining positions tolerate amino acid substitutions and may influence the substrate specificity of the enzyme. Interestingly, kinetic studies for one of the functional mutants, Asn233Ala, indicate that an alanine substitution at this position significantly increases catalytic efficiency as compared with the wild-type enzyme.     

Specificity of the deoxyhypusine hydroxylase-eukaryotic translation initiation factor (eIF5A) interaction: identification of amino acid residues of the enzyme required for binding of its substrate, deoxyhypusine-containing eIF5A

Deoxyhypusine hydroxylase (DOHH) is a novel metalloenzyme that catalyzes the final step of the post-translational synthesis of hypusine (Nepsilon-(4-amino-2-hydroxybutyl)lysine) in the eukaryotic translation initiation factor 5A (eIF5A). Hypusine synthesis is unique in that it occurs in only one protein, denoting the strict specificity of the modification enzymes toward the substrate protein. The specificity of the interaction between eIF5A and DOHH was investigated using human eIF5A (eIF5A-1 isoform) and human recombinant DOHH. DOHH displayed a strong preference for binding the deoxyhypusine-containing form of eIF5A, over the eIF5A precursor or the hypusine-containing eIF5A, indicating a role for the deoxyhypusine residue in binding. In addition to the deoxyhypusine residue, a large portion of the eIF5A polypeptide (>20-90 amino acids) is required for effective modification by DOHH. We have identified the amino acid residues of DOHH that are critical for substrate binding by alanine substitution of 36 conserved amino acid residues. Of these, alanine substitution at Glu57, Glu90, Glu208, Glu241, Gly63, or Gly214 caused a severe impairment in eIF5A(Dhp) binding, with a complete loss of binding and activity in the E57A and E208A mutant enzymes. Only aspartate substitution mutants, E57D or E208D, retained partial activity and substrate binding, whereas alanine, glutamine, or asparagine mutants did not. These findings support a proposed model of DOHH-eIF5A binding in which the amino group(s) of the deoxyhypusine side chain of the substrate is primarily anchored by gamma-carboxyl groups of Glu57 and Glu208 at the DOHH active site.     

Structural basis for a change in substrate specificity: crystal structure of S113E isocitrate dehydrogenase in a complex with isopropylmalate, Mg2+, and NADP

Isocitrate dehydrogenase (IDH) catalyzes the oxidative decarboxylation of isocitrate and has negligible activity toward other (R)-malate-type substrates. The S113E mutant of IDH significantly improves its ability to utilize isopropylmalate as a substrate and switches the substrate specificity (k(cat)/K(M)) from isocitrate to isopropylmalate. To understand the structural basis for this switch in substrate specificity, we have determined the crystal structure of IDH S113E in a complex with isopropylmalate, NADP, and Mg(2+) to 2.0 A resolution. On the basis of a comparison with previously determined structures, we identify distinct changes caused by the amino acid substitution and by the binding of substrates. The S113E complex exhibits alterations in global and active site conformations compared with other IDH structures that include loop and helix conformational changes near the active site. In addition, the angle of the hinge that relates the two domains was altered in this structure, which suggests that the S113E substitution and the binding of substrates act together to promote catalysis of isopropylmalate. Ligand binding results in reorientation of the active site helix that contains residues 113 through 116. E113 exhibits new interactions, including van der Waals contacts with the isopropyl group of isopropylmalate and a hydrogen bond with N115, which in turn forms a hydrogen bond with NADP. In addition, the loop and helix regions that bind NADP are altered, as is the loop that connects the NADP binding region to the active site helix, changing the relationship between substrates and enzyme. In combination, these interactions appear to provide the basis for the switch in substrate specificity.     

Site-directed mutagenesis of human membrane-associated ganglioside sialidase: identification of amino-acid residues contributing to substrate specificity.

Unlike microbial sialidases, mammalian sialidases possess strict substrate specificity, for example the human membrane-associated sialidase, which hydrolyzes only gangliosides. To cast light on the molecular basis of this narrow substrate preference, predicted active site amino-acid residues of the human membrane sialidase were altered by site-directed mutagenesis. When compared with the active site amino-acid residues proposed for Salmonella typhimurium sialidase, only five out of 13 residues were found to be different to the human enzyme, these being located upstream of the putative transmembrane region. Alteration of seven residues, including these five, was followed by transient expression of the mutant enzymes in COS-1 cells and characterization of their kinetic properties using various substrates. Substitution of glutamic acid (at position 51) by aspartic acid and of arginine (at position 114) by glutamine or alanine resulted in retention of good catalytic efficiency toward ganglioside substrates, whereas other substitutions caused a marked reduction. The mutant enzyme E51D exhibited an increase in hydrolytic activity towards GM2 as well as sialyllactose (which are poor substrates for the wild-type) with change to a lower Km and a higher Vmax. R114Q demonstrated a substrate specificity shift in the same direction as E51D, whereas R114A enhanced the preference for gangliosides GD3 and GD1a that are effectively hydrolyzed by the wild-type. The inhibition experiments using 2-deoxy-2,3-didehydro-N-acetylneuraminic acid were consistent with the results in the alteration of substrate specificity. The findings suggest that putative active-site residues of the human membrane sialidase contribute to its substrate specificity.     

Substrate specificities of family 1 UGTs gained by domain swapping

Family 1 glycosyltransferases are a group of enzymes known to embrace a large range of different substrates. This study devises a method to enhance the range of substrates even further by combining domains from different glycosyltransferases to gain improved substrate specificity and catalytic efficiency. Chimeric glycosyltransferases were made by combining domains from seven different family 1 glycosyltransferases, UGT71C1, UGT71C2, UGT71E1, UGT85C1, UGT85B1, UGT88B1 and UGT94B1. Twenty different chimeric glycosyltransferases were formed of which twelve were shown to be catalytically active. The chimeric enzymes of Arabidopsis thaliana UGT71C1 and UGT71C2 showed major changes in acceptor substrate specificity and were able to glycosylate etoposide significantly better than the parental UGT71C1 and UGT71C2 enzymes, with K_cat and efficiency coefficients 3.0 and 2.6 times higher, respectively. Chimeric glycosyltransferases of UGT71C1 combined with Stevia rebaudiana UGT71E1, also afforded enzymes with high catalytic efficiency, even though the two enzymes only display 38% amino acid sequence identity. These chimeras show a significantly altered regiospecificity towards especially trans-resveratrol, enabling the production of trans-resveratrol-β-4′-O-glucoside (resveratroloside). The study demonstrates that it is possible to obtain improved catalytic properties by combining domains from both closely as well as more distantly related glycosyltransferases. The substrate specificity gained by the chimeras is difficult to predict because factors determining the acceptor specificity reside in the N- terminal as well as the C-terminal domains.     

Single amino acid substitution in Bacillus sphaericus phenylalanine dehydrogenase dramatically increases its discrimination between phenylalanine and tyrosine substrates

Homology-based modeling of phenylalanine dehydrogenases (PheDHs) from various sources, using the structures of homologous enzymes Clostridium symbiosum glutamate dehydrogenase and Bacillus sphaericus leucine dehydrogenase as a guide, revealed that an asparagine residue at position 145 of B. sphaericus PheDH was replaced by valine or alanine in PheDHs from other sources. This difference was proposed to be the basis for the poor discrimination by the B. sphaericus enzyme between the substrates L-phenylalanine and L-tyrosine. Residue 145 of this enzyme was altered, by site-specific mutagenesis, to hydrophobic residues alanine, valine, leucine, and isoleucine, respectively. The resultant mutants showed a high discrimination, above 50-fold, between L-phenylalanine and L-tyrosine. This higher specificity toward L-phenylalanine was due to K(m) values for L-phenylalanine lowered more than 20-fold compared to the values for L-tyrosine. The greater specificity for L-phenylalanine in the wild-type Bacillus badius enzyme, which has a valine residue in the corresponding position, was also found to be largely due to a lower K(m) for this substrate. Activities were also measured with a range of six amino acids with aliphatic, nonpolar side chains, and with the corresponding oxoacids, and in all cases the specificity constants for these substrates were increased in the mutant enzymes. As with phenylalanine, these increases are mainly attributable to large decreases in K(m) values.     

Site Directed Mutagenesis of Amino Acid Residues at the Active Site of Mouse Aldehyde Oxidase AOX1

Mouse aldehyde oxidase (mAOX1) forms a homodimer and belongs to the xanthine oxidase family of molybdoenzymes which are characterized by an essential equatorial sulfur ligand coordinated to the molybdenum atom. In general, mammalian AOs are characterized by broad substrate specificity and an yet obscure physiological function. To define the physiological substrates and the enzymatic characteristics of mAOX1, we established a system for the heterologous expression of the enzyme in Eschericia coli. The recombinant protein showed spectral features and a range of substrate specificity similar to the native protein purified from mouse liver. The EPR data of recombinant mAOX1 were similar to those of AO from rabbit liver, but differed from the homologous xanthine oxidoreductase enzymes. Site-directed mutagenesis of amino acids Val806, Met884 and Glu1265 at the active site resulted in a drastic decrease in the oxidation of aldehydes with no increase in the oxidation of purine substrates. The double mutant V806E/M884R and the single mutant E1265Q were catalytically inactive enzymes regardless of the aldehyde or purine substrates tested. Our results show that only Glu1265 is essential for the catalytic activity by initiating the base-catalyzed mechanism of substrate oxidation. In addition, it is concluded that the substrate specificity of molybdo-flavoenzymes is more complex and not only defined by the three characterized amino acids in the active site.     

Metabolism of dehydroepiandrosterone sulfate and estrone-sulfate by human platelets

The aim of the present research was to study the uptake of DHEAS, and to establish the intracrine capacity of human platelets to produce sex steroid hormones. The DHEAS transport was evaluated through the uptake of [(3)H]-DHEAS in the presence or absence of different substrates through the organic anion transporting polypeptide (OATP) family. The activity of sulfatase enzyme was evaluated, and the metabolism of DHEAS was measured by the conversion of [(3)H]-DHEAS to [(3)H]-androstenedione, [(3)H]-testosterone, [(3)H]-estrone and [(3)H]-17beta-estradiol. Results indicated the existence in the plasma membrane of an OATP with high affinity for DHEAS and estrone sulphate (E(1)S). The platelets showed the capacity to convert DHEAS to active DHEA by the steroid-sulfatase activity. The cells resulted to be a potential site for androgens production, since they have the capacity to produce androstenedione and testosterone; in addition, they reduced [(3)H]-estrone to [(3)H]-17beta-estradiol. This is the first demonstration that human platelets are able to import DHEAS and E(1)S using the OATP family and to convert DHEAS to active DHEA, and to transform E(1)S to 17beta-estradiol.     

Studies of specificity and catalysis in trypsin by structural analysis of site-directed mutants

We are probing the determinants of catalytic function and substrate specificity in serine proteases by kinetic and crystallographic characterization of genetically engineered site-directed mutants of rat trypsin. The role of the aspartyl residue at position 102, common to all members of the serine protease family, has been tested by substitution with asparagine. In the native enzyme, Asp102 accepts a hydrogen bond from the catalytic base His57, which facilitates the transfer of a proton from the enzyme nucleophile Ser195 to the substrate leaving group. At neutral pH, the mutant is four orders of magnitude less active than the naturally occurring enzyme, but its binding affinity for model substrates is virtually undiminished. Crystallographic analysis reveals that Asn102 donates a hydrogen bond to His57, forcing it to act as donor to Ser195. Below pH 6, His57 becomes statistically disordered. Presumably, the di-protonated population of histidyl side chains are unable to hydrogen bond to Asn102. Steric conflict may cause His57 to rotate away from the catalytic site. These results suggest that Asp102 not only provides inductive and orientation effects, but also stabilizes the productive tautomer of His57. Three experiments were carried out to alter the substrate specificity of trypsin. Glycine residues at positions 216 and 226 in the substrate-binding cavity were replaced by alanine residues in order to differentially affect lysine and arginine substrate binding. While the rate of catalysis by the mutant enzymes was reduced in the mutant enzymes, their substrate specificity was enhanced relative to trypsin. The increased specificity was caused by differential effects on the catalytic activity towards arginine and lysine substrates. The Gly----Ala substitution at 226 resulted in an altered conformation of the enzyme which is converted to an active trypsin-like conformation upon binding of a substrate analog. In a third experiment, Lys189, at the bottom of the specificity pocket, was replaced with an aspartate with the expectation that specificity of the enzyme might shift to aspartate. The mutant enzyme is not capable of cleaving at Arg and Lys or Asp, but shows an enhanced chymotrypsin-like specificity. Structural investigations of these mutants are in progress.     

An amino acid at position 142 in nitrilase from Rhodococcus rhodochrous ATCC 33278 determines the substrate specificity for aliphatic and aromatic nitriles

Nitrilase from Rhodococcus rhodochrous ATCC 33278 hydrolyses both aliphatic and aromatic nitriles. Replacing Tyr-142 in the wild-type enzyme with the aromatic amino acid phenylalanine did not alter specificity for either substrate. However, the mutants containing non-polar aliphatic amino acids (alanine, valine and leucine) at position 142 were specific only for aromatic substrates such as benzonitrile, m-tolunitrile and 2-cyanopyridine, and not for aliphatic substrates. These results suggest that the hydrolysis of substrates probably involves the conjugated pi-electron system of the aromatic ring of substrate or Tyr-142 as an electron acceptor. Moreover, the mutants containing charged amino acids such as aspartate, glutamate, arginine and asparagine at position 142 displayed no activity towards any nitrile, possibly owing to the disruption of hydrophobic interactions with substrates. Thus aromaticity of substrate or amino acid at position 142 in R. rhodochrous nitrilase is required for enzyme activity.     

Shape and specificity in mammalian 15-lipoxygenase active site. The functional interplay of sequence determinants for the reaction specificity

Previous mutagenesis studies along with molecular modeling using the x-ray coordinates of the rabbit 15-lipoxygenase have led to the suggestion that the size of the substrate binding pocket may play an essential role in determining the oxygenation specificity of 5-, 12-, and 15-lipoxygenases. Based on the x-ray crystal structure of rabbit 15-lipoxygenase, Ile(593) appeared to be important in defining size and shape of the substrate-binding site in 15-lipoxygenases. We found that substitution of Ile(593) with alanine shifted the positional specificity of this enzyme toward 12-lipoxygenation. To compare the importance of position 593 with previously defined determinants for the oxygenation specificity, we introduced small (alanine-scan) or large amino acids (phenylalanine-scan) at critical positions surrounding the putative fatty acid-binding site, so that the volume of the pocket was either increased or decreased. Enlargement or alteration in packing density within the substrate binding pocket in the rabbit 15-lipoxygenase increased the share of 12-lipoxygenase products, whereas a smaller active site favored 15-lipoxygenation. Simultaneous substitution of both large and small residues in the context of either a 15- or 12-lipoxygenase indicated that there is a functional interplay of the sequence determinants for lipoxygenation specificity. If the 15-lipoxygenase active site is enlarged excessively, however, no lipoxygenation was observed anymore. Together these results indicate the importance of the overall size and shape of the arachidonic acid binding pocket in defining the specificity of lipoxygenase reaction.     

Altered Substrate Specificity of Drug-Resistant Human Immunodeficiency Virus Type 1 Protease

Resistance to human immunodeficiency virus type 1 protease (HIV PR) inhibitors results primarily from the selection of multiple mutations in the protease region. Because many of these mutations are selected for the ability to decrease inhibitor binding in the active site, they also affect substrate binding and potentially substrate specificity. This work investigates the substrate specificity of a panel of clinically derived protease inhibitor-resistant HIV PR variants. To compare protease specificity, we have used positional-scanning, synthetic combinatorial peptide libraries as well as a select number of individual substrates. The subsite preferences of wild-type HIV PR determined by using the substrate libraries are consistent with prior reports, validating the use of these libraries to compare specificity among a panel of HIV PR variants. Five out of seven protease variants demonstrated subtle differences in specificity that may have significant impacts on their abilities to function in viral maturation. Of these, four variants demonstrated up to fourfold changes in the preference for valine relative to alanine at position P2 when tested on individual peptide substrates. This change correlated with a common mutation in the viral NC/p1 cleavage site. These mutations may represent a mechanism by which severely compromised, drug-resistant viral strains can increase fitness levels. Understanding the altered substrate specificity of drug-resistant HIV PR should be valuable in the design of future generations of protease inhibitors as well as in elucidating the molecular basis of regulation of proteolysis in HIV.     

Analysis of the plasticity of location of the Arg244 positive charge within the active site of the TEM‐1 β‐lactamase

A large number of β‐lactamases have emerged that are capable of conferring bacterial resistance to β‐lactam antibiotics. Comparison of the structural and functional features of this family has refined understanding of the catalytic properties of these enzymes. An arginine residue present at position 244 in TEM‐1 β‐lactamase interacts with the carboxyl group common to penicillin and cephalosporin antibiotics and thereby stabilizes both the substrate and transition state complexes. A comparison of class A β‐lactamase sequences reveals that arginine at position 244 is not conserved, although a positive charge at this structural location is conserved and is provided by an arginine at positions 220 or 276 for those enzymes lacking arginine at position 244. The plasticity of the location of positive charge in the β‐lactamase active site was experimentally investigated by relocating the arginine at position 244 in TEM‐1 β‐lactamase to positions 220, 272, and 276 by site‐directed mutagenesis. Kinetic analysis of the engineered β‐lactamases revealed that removal of arginine 244 by alanine mutation reduced catalytic efficiency against all substrates tested and restoration of an arginine at positions 272 or 276 partially suppresses the catalytic defect of the Arg244Ala substitution. These results suggest an evolutionary mechanism for the observed divergence of the position of positive charge in the active site of class A β‐lactamases.     

Characterization of the structure-activity relationships of rat types I and II 3 beta-hydroxysteroid dehydrogenase/delta 5 -delta 4 isomerase by site-directed mutagenesis and expression in HeLa cells

The membrane-bound enzyme 3 beta-hydroxysteroid dehydrogenase/delta 5 -delta 4 isomerase (3 beta-HSD) catalyzes the conversion of delta 5 -3 beta-hydroxysteroid precursors into delta 4-ketosteroids, thus representing an essential step in the biosynthesis of all classes of hormonal steroids. We have recently characterized two types of cDNA clones encoding rat 3 beta-HSD proteins, the rat type I protein being much more active than type II. In order to characterize further the functional difference between these two 3 beta-HSD types, transient expression of type I and type II 3 beta-HSD cDNAs was performed in HeLa human cervical carcinoma cells. The present study demonstrates that the type I 3 beta-HSD protein has a relative specificity 64- and 46-fold higher than type II protein for pregnenolone (PREG) and dehydroepiandrosterone (DHEA) as substrates, respectively. The Km values of type I and type II enzymes were calculated at 0.74 and 14.3 microM, respectively, using PREG as substrate whereas the respective Km values were 0.68 and 12.9 microM when DHEA was used, thus showing that their different relative specificity results largely from a different affinity for substrates. Since the change of 4 amino acid residues in type II could prevent the formation of a putative membrane-spanning domain (MSD) predicted between amino acid residues 75 and 91, chimeric cDNAs containing either type I MSD in type II (II + MSD) or an absence of this MSD in type I (I-MSD) were constructed and transiently expressed. The addition of MSD intype II 3 beta-HSD markedly increased the affinity leading to Km values similar to those found in type I 3 beta-HSD, namely 0.36 and 0.40 microM for PREG and DHEA, respectively. II + MSD chimera thus encodes a protein having a relative specificity for PREG and DHEA of 58 and 73%, respectively, to that of native type I 3 beta-HSD. Moreover, removal of MSD in the type I protein (I-MSD chimera) decreased the relative specificity of type I 3 beta-HSD protein for PREG and DHEA to only 0.37 and 0.48%, with respective Km values of 11.7 and 11.0 microM, thus strongly indicating the functional importance of this putative MSD which is predicted in wild type rat type I as well as in macaque and human 3 beta-HSD proteins.     

Characterization of the role of polar amino acid residues within predicted transmembrane helix 17 in determining the substrate specificity of multidrug resistance protein 3

Human multidrug resistance protein (MRP) 3 is the most closely related homologue of MRP1. Like MRP1, MRP3 confers resistance to etoposide (VP-16) and actively transports 17 beta-estradiol 17-(beta-D-glucuronide) (E(2)17 beta G), cysteinyl leukotriene 4 (LTC(4)), and methotrexate, although with generally lower affinity. Unlike MRP1, MRP3 also transports monovalent bile salts. We have previously demonstrated that hydrogen-bonding residues predicted to be in the inner-leaflet spanning segment of transmembrane (TM) 17 of MRP1 are important for drug resistance and E(2)17 beta G transport. We have now examined the importance of the hydrogen-bonding potential of residues in TM17 of MRP3 on both substrate specificity and overall activity. Mutation S1229A reduced only methotrexate transport. Mutations S1231A and N1241A decreased resistance to VP-16 and transport of E(2)17 beta G and methotrexate but not taurocholate. Mutation Q1235A also reduced resistance to VP-16 and transport of E(2)17beta G but increased taurocholate transport without affecting transport of methotrexate. Mutations Y1232F and S1233A reduced resistance to VP-16 and the transport of all three substrates tested. In contrast, mutation T1237A markedly increased VP-16 resistance and transport of all substrates. On the basis of the substrates analyzed, residues Ser(1229), Ser(1231), Gln(1235), and Asn(1241) play an important role in determining the specificity of MRP3, while mutation of Tyr(1232), Ser(1233), and Thr(1237) affects overall activity. Unlike MRP1, the involvement of polar residues in determining substrate specificity extends throughout the TM helix. Furthermore, elimination of the hydrogen-bonding potential of a single amino acid, Thr(1237), markedly enhanced the ability of the protein to confer drug resistance and to transport all substrates examined.     

Identification of Amino Acids Conferring Chain Length Substrate Specificities on Fatty Alcohol-forming Reductases FAR5 and FAR8 from Arabidopsis thaliana

Fatty alcohols play a variety of biological roles in all kingdoms of life. Fatty acyl reductase (FAR) enzymes catalyze the reduction of fatty acyl-coenzyme A (CoA) or fatty acyl-acyl carrier protein substrates to primary fatty alcohols. FAR enzymes have distinct substrate specificities with regard to chain length and degree of saturation. FAR5 (At3g44550) and FAR8 (At3g44560) from Arabidopsis thaliana are 85% identical at the amino acid level and are of equal length, but they possess distinct specificities for 18:0 or 16:0 acyl chain length, respectively. We used Saccharomyces cerevisiae as a heterologous expression system to assess FAR substrate specificity determinants. We identified individual amino acids that affect protein levels or 16:0-CoA versus 18:0-CoA specificity by expressing in yeast FAR5 and FAR8 domain-swap chimeras and site-specific mutants. We found that a threonine at position 347 and a serine at position 363 were important for high FAR5 and FAR8 protein accumulation in yeast and thus are likely important for protein folding and stability. Amino acids at positions 355 and 377 were important for dictating 16:0-CoA versus 18:0-CoA chain length specificity. Simultaneously converting alanine 355 and valine 377 of FAR5 to the corresponding FAR8 residues, leucine and methionine, respectively, almost fully converted FAR5 specificity from 18:0-CoA to 16:0-CoA. The reciprocal amino acid conversions, L355A and M377V, made in the active FAR8-S363P mutant background converted its specificity from 16:0-CoA to 18:0-CoA. This study is an important advancement in the engineering of highly active FAR proteins with desired specificities for the production of fatty alcohols with industrial value.     

Role for the P4 amino acid residue in substrate utilization by the poliovirus 3CD proteinase.

Amino acid insertions or substitutions were introduced into the poliovirus P1 capsid precursor at locations proximal to the two known Q-G cleavage sites to examine the role of the P4 residue in substrate processing by proteinase 3CD. Analysis of the processing profile of P1 precursors containing four-amino-acid insertions into the carboxy terminus of VP3 or a single-amino-acid substitution at the P4 position of the VP3-VP1 cleavage site demonstrates that substitution of the alanine residue in the P4 position of the VP3-VP1 cleavage site significantly affects cleavage at that site by proteinase 3CD. A single-amino-acid substitution at the P4 position of the VP0-VP3 cleavage site, on the other hand, has only a slight effect on 3CD-mediated processing at this cleavage site. Finally, analysis of six amino acid insertion mutations containing Q-G amino acid pairs demonstrates that the in vitro and in vivo selection of a cleavage site from two adjacent Q-G amino acid pairs depends on the presence of an alanine in the P4 position of the cleaved site. Our data provide genetic and biochemical evidence that the alanine residue in the P4 position of the VP3-VP1 cleavage site is a required substrate determinant for the recognition and cleavage of that site by proteinase 3CD and suggest that the P4 alanine residue may be specifically recognized by proteinase 3CD.     

A novel approach to the characterization of substrate specificity in short/branched chain Acyl-CoA dehydrogenase

Rat and human short/branched chain acyl-CoA dehydrogenases exhibit key differences in substrate specificity despite an overall amino acid identity of 85% between them. Rat short/branched chain acyl-CoA dehydrogenases (SBCAD) are more active toward substrates with longer carbon side chains than human SBCAD, whereas the human enzyme utilizes substrates with longer primary carbon chains. The mechanism underlying this difference in substrate specificity was investigated with a novel surface plasmon resonance assay combined with absorbance and circular dichroism spectroscopy, and kinetics analysis of wild type SBCADs and mutants with altered amino acid residues in the substrate binding pocket. Results show that a relatively few amino acid residues are critical for determining the difference in substrate specificity seen between the human and rat enzymes and that alteration of these residues influences different portions of the enzyme mechanism. Molecular modeling of the SBCAD structure suggests that position 104 at the bottom of the substrate binding pocket is important in determining the length of the primary carbon chain that can be accommodated. Conformational changes caused by alteration of residues at positions 105 and 177 directly affect the rate of electron transfer in the dehydrogenation reactions, and are likely transmitted from the bottom of the substrate binding pocket to beta-sheet 3. Differences between the rat and human enzyme at positions 383, 222, and 220 alter substrate specificity without affecting substrate binding. Modeling predicts that these residues combine to determine the distance between the flavin ring of FAD and the catalytic base, without changing the opening of the substrate binding pocket.     

Rapid peptide-based screening on the substrate specificity of severe acute respiratory syndrome (SARS) coronavirus 3C-like protease by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Severe acute respiratory syndrome coronavirus (SARS-CoV) 3C-like protease (3CL(pro)) mediates extensive proteolytic processing of replicase polyproteins, and is considered a promising target for anti-SARS drug development. Here we present a rapid and high-throughput screening method to study the substrate specificity of SARS-CoV 3CL(pro). Six target amino acid positions flanking the SARS-CoV 3CL(pro) cleavage site were investigated. Each batch of mixed peptide substrates with defined amino acid substitutions at the target amino acid position was synthesized via the "cartridge replacement" approach and was subjected to enzymatic cleavage by recombinant SARS-CoV 3CL(pro). Susceptibility of each peptide substrate to SARS-CoV 3CL(pro) cleavage was monitored simultaneously by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). The hydrophobic pocket in the P2 position at the protease cleavage site is crucial to SARS-CoV 3CL(pro)-specific binding, which is limited to substitution by hydrophobic residue. The binding interface of SARS-CoV 3CL(pro) that is facing the P1' position is suggested to be occupied by acidic amino acids, thus the P1' position is intolerant to acidic residue substitution, owing to electrostatic repulsion. Steric hindrance caused by some bulky or beta-branching amino acids in P3 and P2' positions may also hinder the binding of SARS-CoV 3CL(pro). This study generates a comprehensive overview of SARS-CoV 3CL(pro) substrate specificity, which serves as the design basis of synthetic peptide-based SARS-CoV 3CL(pro) inhibitors. Our experimental approach is believed to be widely applicable for investigating the substrate specificity of other proteases in a rapid and high-throughput manner that is compatible for future automated analysis.     

Control of Substrate Specificity by Active-Site Residues in Nitrobenzene Dioxygenase

Nitrobenzene 1,2-dioxygenase from Comamonas sp. strain JS765 catalyzes the initial reaction in nitrobenzene degradation, forming catechol and nitrite. The enzyme also oxidizes the aromatic rings of mono- and dinitrotoluenes at the nitro-substituted carbon, but the basis for this specificity is not understood. In this study, site-directed mutagenesis was used to modify the active site of nitrobenzene dioxygenase, and the contribution of specific residues in controlling substrate specificity and enzyme performance was evaluated. The activities of six mutant enzymes indicated that the residues at positions 258, 293, and 350 in the α subunit are important for determining regiospecificity with nitroarene substrates and enantiospecificity with naphthalene. The results provide an explanation for the characteristic specificity with nitroarene substrates. Based on the structure of nitrobenzene dioxygenase, substitution of valine for the asparagine at position 258 should eliminate a hydrogen bond between the substrate nitro group and the amino group of asparagine. Up to 99% of the mononitrotoluene oxidation products formed by the N258V mutant were nitrobenzyl alcohols rather than catechols, supporting the importance of this hydrogen bond in positioning substrates in the active site for ring oxidation. Similar results were obtained with an I350F mutant, where the formation of the hydrogen bond appeared to be prevented by steric interference. The specificity of enzymes with substitutions at position 293 varied depending on the residue present. Compared to the wild type, the F293Q mutant was 2.5 times faster at oxidizing 2,6-dinitrotoluene while retaining a similar K_m for the substrate based on product formation rates and whole-cell kinetics.