Comparison of the substrate specificity of two potyvirus proteases

The substrate specificity of the nuclear inclusion protein a (NIa) proteolytic enzymes from two potyviruses, the tobacco etch virus (TEV) and tobacco vein mottling virus (TVMV), was compared using oligopeptide substrates. Mutations were introduced into TEV protease in an effort to identify key determinants of substrate specificity. The specificity of the mutant enzymes was assessed by using peptides with complementary substitutions. The crystal structure of TEV protease and a homology model of TVMV protease were used to interpret the kinetic data. A comparison of the two structures and the experimental data suggested that the differences in the specificity of the two enzymes may be mainly due to the variation in their S4 and S3 binding subsites. Two key residues predicted to be important for these differences were replaced in TEV protease with the corresponding residues of TVMV protease. Kinetic analyses of the mutants confirmed that these residues play a role in the specificity of the two enzymes. Additional residues in the substrate-binding subsites of TEV protease were also mutated in an effort to alter the specificity of the enzyme.     

Tobacco Etch Virus Protease: Crystal Structure of the Active Enzyme and Its Inactive Mutant

Tobacco Etch Virus Protease (TEV protease) is widely used as a tool for separation of recombinant target proteins from their fusion partners. The crystal structures of two mutants of TEV protease, the active autolysis-resistant mutant TEV-S219D in complex with the proteolysis product, and the inactive mutant TEV-C151A in complex with a substrate, have been determined at 1.8 and 2.2 Å resolution, respectively. The active sites of both mutants, including their oxyanion holes, have identical structures. The C-terminal residues 217–221 of the enzyme are involved in formation of the binding pockets S ₃–S ₆. This indicates that the autolysis of the peptide bond Met218–Ser219 exerts a strong effect on the fine-tuning of the substrate in the enzyme active site, which results in a considerable decrease in the enzymatic activity.     

Efficient site-specific processing of fusion proteins by tobacco vein mottling virus protease in vivo and in vitro

Affinity tags are widely used as vehicles for the production of recombinant proteins. Yet, because of concerns about their potential to interfere with the activity or structure of proteins, it is almost always desirable to remove them from the target protein. The proteases that are most often used to cleave fusion proteins are factor Xa, enterokinase, and thrombin, yet the literature is replete with reports of fusion proteins that were cleaved by these proteases at locations other than the designed site. It is becoming increasingly evident that certain viral proteases have more stringent sequence specificity. These proteases adopt a trypsin-like fold but possess an unconventional catalytic triad in which Cys replaces Ser. The tobacco etch virus (TEV) protease is the best-characterized enzyme of this type. TEV protease cleaves the sequence ENLYFQG/S between QG or QS with high specificity. The tobacco vein mottling virus (TVMV) protease is a close relative of TEV protease with a distinct sequence specificity (ETVRFQG/S). We show that, like TEV protease, TVMV protease can be used to cleave fusion proteins with high specificity in vitro and in vivo. We compared the catalytic activity of the two enzymes as a function of temperature and ionic strength, using an MBP-NusG fusion protein as a model substrate. The behavior of TVMV protease was very similar to that of TEV protease. Its catalytic activity was greatest in the absence of NaCl, but diminished only threefold with increasing salt up to 200 mM. We found that the optimum temperatures of the two enzymes are nearly the same and that they differ only two-fold in catalytic efficiency, both at room temperature and 4 degrees C. Hence, TVMV protease may be a useful alternative to TEV protease when a recombinant protein happens to contain a sequence that is similar to a TEV protease recognition site or for protein expression strategies that involve the use of more than one protease.     

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.     

Expression,purification and molecular modeling of the NIa protease of Cardamom mosaic virus

The NIa protease of Potyviridae is the major viral protease that processes potyviral polyproteins. The NIa protease coding region of Cardamom mosaic virus (CdMV) is amplified from the viral cDNA, cloned and expressed in Escherichia coli. NIa protease forms inclusion bodies in E.coli. The inclusion bodies are solubilized with 8?M urea, refolded and purified by Nickel-Nitrilotriacetic acid affinity chromatography. Three-dimensional modeling of the CdMV NIa protease is achieved by threading approach using the homologous X-ray crystallographic structure of Tobacco etch mosaic virus NIa protease. The model gave an insight in to the substrate specificities of the NIa proteases and predicted the complementation of nearby residues in the catalytic triad (H42, D74 and C141) mutants in the cis protease activity of CdMV NIa protease.     

Molecular Cloning, Expression, and Purification of Nuclear Inclusion A Protease from Tobacco Vein Mottling Virus

The gene encoding the C-terminal protease domain of the nuclear inclusion protein a (NIa) of tobacco vein mottling virus (TVMV) was cloned from an isolated virus particle and expressed as a fusion protein with glutathione S-transferase in Escherichia coli XL1-blue. The 27-kDa protease was purified from the fusion protein by glutathione affinity chromatography and Mono S chromatography. The purified protease exhibited the specific proteolytic activity towards the nonapeptide substrates, Ac-Glu-Asn-Asn-Val-Arg-Phe-Gln-Ser-Leu-amide and Ac-Arg-Glu-Thr-Val-Arg-Phe-Gln-Ser-Asp-amide, containing the junction sequences between P3 protein and cylindrical inclusion protein and between nuclear inclusion protein b and capsid protein, respectively. The K_m and k_cat values were about 0.2 mM and 0.071 s^–1, respectively, which were approximately five-fold lower than those obtained for the NIa protease of turnip mosaic potyvirus (TuMV), suggesting that the TVMV NIa protease is different in the binding affinity as well as in the catalytic power from the TuMV NIa protease. In contrast to the NIa proteases from TuMV and tobacco etch virus, the TVMV NIa protease was not autocatalytically cleaved into smaller proteins, indicating that the C-terminal truncation is not a common phenomenon occurring in all potyviral NIa proteases. These results suggest that the TVMV NIa protease has a unique biochemical property distinct from those of other potyviral proteases.     

Crystal structure of tobacco etch virus protease shows the protein C terminus bound within the active site

Tobacco etch virus (TEV) protease is a cysteine protease exhibiting stringent sequence specificity. The enzyme is widely used in biotechnology for the removal of the affinity tags from recombinant fusion proteins. Crystal structures of two TEV protease mutants as complexes with a substrate and a product peptide provided the first insight into the mechanism of substrate specificity of this enzyme. We now report a 2.7A crystal structure of a full-length inactive C151A mutant protein crystallised in the absence of peptide. The structure reveals the C terminus of the protease bound to the active site. In addition, we determined dissociation constants of TEV protease substrate and product peptides using isothermal titration calorimetry for various forms of this enzyme. Data suggest that TEV protease could be inhibited by the peptide product of autolysis. Separate modes of recognition for native substrates and the site of TEV protease self-cleavage are proposed.     

The structure of S. lividans acetoacetyl‐CoA synthetase shows a novel interaction between the C‐terminal extension and the N‐terminal domain

The adenosine monoposphate‐forming acyl‐CoA synthetase enzymes catalyze a two‐step reaction that involves the initial formation of an acyl adenylate that reacts in a second partial reaction to form a thioester between the acyl substrate and CoA. These enzymes utilize a Domain Alternation catalytic mechanism, whereby a ～110 residue C‐terminal domain rotates by 140° to form distinct catalytic conformations for the two partial reactions. The structure of an acetoacetyl‐CoA synthetase (AacS) is presented that illustrates a novel aspect of this C‐terminal domain. Specifically, several acetyl‐ and acetoacetyl‐CoA synthetases contain a 30‐residue extension on the C‐terminus compared to other members of this family. Whereas residues from this extension are disordered in prior structures, the AacS structure shows that residues from this extension may interact with key catalytic residues from the N‐terminal domain. Proteins 2015; 83:575–581. © 2014 Wiley Periodicals, Inc.     

Field resistance of transgenic burley tobacco lines and hybrids expressing the tobacco vein mottling virus coat protein gene

Fifty transgenic lines expressing the tobacco vein mottling virus (TVMV) coat protein (CP) gene in five genetic backgrounds were evaluated under field conditions for response to mechanic inoculation with TVMV, tobacco etch virus (TEV) and potato virus Y (PVY). TVMV CP transgenic lines conferred resistance to TVMV, TEV and PVY under field conditions. Combining two strategies, coat protein-mediated resistance (CPMR) coupled with an endogenous resistance gene (Virgin A Mutant, VAM) significantly extended the range and magnitude of virus resistance and provided a potential valuable new source of protection against potyviruses. CP transgenic lines lacking the VAM gene had high resistance to TEV, medium resistance to PVY, and a recovery phenotype to TVMV. A series of hybrids involving transgenic lines were generated and tested under field conditions for response to virus inoculation. One copy of TVMV-CP gene presented in lines homozygous for the VAM gene provided effective resistance to all three potyviruses. These studies also suggested that selection of a suitable recipient genotype was critical and that field evaluation was necessary in order to select elite resistant transgenic lines. Engineering viral CP genes into genotypes possessing some level of virus resistance could be critical to achieve an effective level of resistance.     

Evolutionary optimization of peptide substrates for proteases that exhibit rapid hydrolysis kinetics

Protease cleavage site recognition motifs can be identified using protease substrate discovery methodologies, but typically exhibit non‐optimal specificity and activity. To enable evolutionary optimization of substrate cleavage kinetics, a two‐color cellular library of peptide substrates (CLiPS) methodology was developed. Two‐color CLiPS was applied to identify peptide substrates for the tobacco etch virus (TEV) protease from a random pentapeptide library, which were then optimized by screening of a focused, extended substrate library. Quantitative library screening yielded seven amino acid substrates exhibiting rapid hydrolysis by TEV protease and high sequence similarity to the native seven‐amino‐acid substrate, with a strong consensus of EXLYΦQG. Comparison of hydrolysis rates for a family of closely related substrates indicates that the native seven‐residue TEV substrate co‐evolved with TEV protease to facilitate highly efficient hydrolysis. Consensus motifs revealed by screening enabled database identification of a family of related, putative viral protease substrates. More generally, our results suggest that substrate evolution using CLiPS may be useful for optimizing substrate selectivity and activity to enable the design of more effective protease activity probes, molecular imaging agents, and prodrugs. Biotechnol. Bioeng. 2010; 106: 339–346. © 2010 Wiley Periodicals, Inc.     

Revealing the dimer dissociation and existence of a folded monomer of the mature HIV‐2 protease

Purification and in vitro protein‐folding schemes were developed to produce monodisperse samples of the mature wild‐type HIV‐2 protease (PR2), enabling a comprehensive set of biochemical and biophysical studies to assess the dissociation of the dimeric protease. An E37K substitution in PR2 significantly retards autoproteolytic cleavage during expression. Furthermore, it permits convenient measurement of the dimer dissociation of PR2_E37K (elevated K_d ～20 nM) by enzyme kinetics. Differential scanning calorimetry reveals a T_m of 60.5 for PR2 as compared with 65.7°C for HIV‐1 protease (PR1). Consistent with weaker binding of the clinical inhibitor darunavir (DRV) to PR2, the T_m of PR2 increases by 14.8°C in the presence of DRV as compared with 22.4°C for PR1. Dimer interface mutations, such as a T26A substitution in the active site (PR2_T26A) or a deletion of the C‐terminal residues 96–99 (PR2_1–95), drastically increase the K_d (>10⁵‐fold). PR2_T26A and PR2_1–95 consist predominantly of folded monomers, as determined by nuclear magnetic resonance (NMR) and size‐exclusion chromatography coupled with multiangle light scattering and refractive index measurements (SMR), whereas wild‐type PR2 and its active‐site mutant PR2_D25N are folded dimers. Addition of twofold excess active‐site inhibitor promotes dimerization of PR2_T26A but not of PR2_1–95, indicating that subunit interactions involving the C‐terminal residues are crucial for dimer formation. Use of SMR and NMR with PR2 facilitates probing for potential inhibitors that restrict protein folding and/or dimerization and, thus, may provide insights for the future design of inhibitors to circumvent drug resistance.     

Tobacco etch virus proteinase: crystal structure of the active enzyme and its inactive mutant

Tobacco Etch Virus Protease (TEV protease) is widely used as a tool for separation of recombinant target proteins from their fusion partners. The crystal structures of two mutants of TEV protease, active autolysis-resistant mutant TEV-S219D in complex with the proteolysis product, and inactive mutant TEV-C151A in complex with a substrate, have been determined at 1.8 and 2.2 A resolution, respectively. The active sites of both mutants, including their oxyanion holes, have identical structures. The C-terminal residues 217-221 of the enzyme are involved in formation of the binding pockets S3-S6. This indicates that the autolysis of the peptide bond Met218-Ser219 exerts a strong effect on the fine-tuning of the substrate in the enzyme active site, which results in considerable decrease in the enzymatic activity.     

Crystal structures of α‐dioxygenase from Oryza sativa: Insights into substrate binding and activation by hydrogen peroxide

α‐Dioxygenases (α‐DOX) are heme‐containing enzymes found predominantly in plants and fungi, where they generate oxylipins in response to pathogen attack. α‐DOX oxygenate a variety of 14–20 carbon fatty acids containing up to three unsaturated bonds through stereoselective removal of the pro‐R hydrogen from the α‐carbon by a tyrosyl radical generated via the oxidation of the heme moiety by hydrogen peroxide (H₂O₂). We determined the X‐ray crystal structures of wild type α‐DOX from Oryza sativa, the wild type enzyme in complex with H₂O₂, and the catalytically inactive Y379F mutant in complex with the fatty acid palmitic acid (PA). PA binds within the active site cleft of α‐DOX such that the carboxylate forms ionic interactions with His‐311 and Arg‐559. Thr‐316 aids in the positioning of carbon‐2 for hydrogen abstraction. Twenty‐five of the twenty eight contacts made between PA and residues lining the active site occur within the carboxylate and first eight carbons, indicating that interactions within this region of the substrate are responsible for governing selectivity. Comparison of the wild type and H₂O₂ structures provides insight into enzyme activation. The binding of H₂O₂ at the distal face of the heme displaces residues His‐157, Asp‐158, and Trp‐159 ～2.5 Å from their positions in the wild type structure. As a result, the Oδ2 atom of Asp‐158 interacts with the Ca atom in the calcium binding loop, the side chains of Trp‐159 and Trp‐213 reorient, and the guanidinium group of Arg‐559 is repositioned near Tyr‐379, poised to interact with the carboxylate group of the substrate.     

Development of [Ile40]HTLV‐I protease inhibition assay using novel fluorogenic and chromogenic substrate

HTLV‐I is a debilitating and/or lethal retrovirus that causes HTLV‐I‐associated myelopathy/tropical spastic paraparesis, adult T‐cell leukemia and several inflammatory diseases. HTLV‐I protease is an aspartic retropepsin involved in HTLV‐I replication and its inhibition could treatHTLV‐I infection. A recombinant L40I mutant HTLV‐I protease was designed and obtained from Escherichia coli, self‐processingand purification by ion‐exchange chromatography. The protease was refolded by a one‐step dialysis and recovered activity. The cleavage efficiency of the [Ile⁴⁰]HTLV‐I protease was at least 300 times higher for a fluorescent substratethan that of our previously reported recombinant His‐tagged non‐mutated HTLV‐I protease. In addition, we designed and synthesized a substrate containing a highly fluorescent Mca moiety in the fragment before the scissile bond, and a chromogenic p‐nitrophenylalanine moiety after the scissile bond that greatly amplified spectrometry detection and improved the HTLV‐I protease inhibition potency assay. The HTLV‐I protease inhibition assay with the [Ile⁴⁰]HTLV‐I protease and fluorogenic substrate requires distinctively less protease, substrate, inhibitor and assay time than our previous methods. This means our new assay is more cost‐effective and more time‐efficient while being reproducible and less labor‐intensive. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Structure of the N‐terminal domain of the metalloprotease PrtV from Vibrio cholerae

The metalloprotease PrtV from Vibrio cholerae serves an important function for the ability of bacteria to invade the mammalian host cell. The protein belongs to the family of M6 proteases, with a characteristic zinc ion in the catalytic active site. PrtV constitutes a 918 amino acids (102 kDa) multidomain pre‐pro‐protein that undergoes several N‐ and C‐terminal modifications to form a catalytically active protease. We report here the NMR structure of the PrtV N‐terminal domain (residues 23–103) that contains two short α‐helices in a coiled coil motif. The helices are held together by a cluster of hydrophobic residues. Approximately 30 residues at the C‐terminal end, which were predicted to form a third helical structure, are disordered. These residues are highly conserved within the genus Vibrio, which suggests that they might be functionally important.     

Specific and efficient cleavage of fusion proteins by recombinant plum pox virus NIa protease

Site-specific proteases are the most popular kind of enzymes for removing the fusion tags from fused target proteins. Nuclear inclusion protein a (NIa) proteases obtained from the family Potyviridae have become promising due to their high activities and stringencies of sequences recognition. NIa proteases from tobacco etch virus (TEV) and tomato vein mottling virus (TVMV) have been shown to process recombinant proteins successfully in vitro. In this report, recombinant PPV (plum pox virus) NIa protease was employed to process fusion proteins with artificial cleavage site in vitro. Characteristics such as catalytic ability and affecting factors (salt, temperature, protease inhibitors, detergents, and denaturing reagents) were investigated. Recombinant PPV NIa protease expressed and purified from Escherichia coli demonstrated efficient and specific processing of recombinant GFP and SARS-CoV nucleocapsid protein, with site F (N V V V H Q black triangle down A) for PPV NIa protease artificially inserted between the fusion tags and the target proteins. Its catalytic capability is similar to those of TVMV and TEV NIa protease. Recombinant PPV NIa protease reached its maximal proteolytic activity at approximately 30 degrees C. Salt concentration and only one of the tested protease inhibitors had minor influences on the proteolytic activity of PPV NIa protease. Recombinant PPV NIa protease was resistant to self-lysis for at least five days.     

采用TEV酶法进行整合膜蛋白拓扑学分析

为了研究膜蛋白的跨膜结构,进行拓扑学分析是十分重要的.有许多分析膜蛋白拓扑结构的方法,本文采用烟草蚀斑病毒（TEV）酶特异性切割测试蛋白中跨膜片段的前段或后端所插入的tev识别序列EXXYXQ(S/G),如果TEV酶能够切割,表明该序列位于目标蛋白的细胞 质外.将Tev识别序列ENLYFQG 分别插入到拟南芥整合膜蛋白的的跨膜区域,然后转化进入酿酒酵母中. 消解酶(zymolyase)酶破除酵母的细胞壁后,TEV酶消化球状体,最后通过Western免疫印迹法来分析结果.有关该方法的注意事项在结果中进行了讨论.     

Human enteropeptidase light chain: Bioengineering of recombinants and kinetic investigations of structure and function

The serine protease enteropeptidase exhibits a high level of substrate specificity for the cleavage sequence DDDDK～ X, making this enzyme a useful tool for the separation of recombinant protein fusion domains. In an effort to improve the utility of enteropeptidase for processing fusion proteins and to better understand its structure and function, two substitution variants of human enteropeptidase, designated R96Q and Y174R, were created and produced as active (>92%) enzymes secreted by Pichia pastoris with yields in excess of 1.7 mg/Liter. The Y174R variant showed improved specificities for substrates containing the sequences DDDDK (k_cat/K_M = 6.83 × 10⁶ M^?1 sec^?1) and DDDDR (k_cat/K_M = 1.89 × 10⁷ M^?1 sec^?1) relative to all other enteropeptidase variants reported to date. BPTI inhibition of Y174R was significantly decreased. Kinetic data demonstrate the important contribution of the positively charged residue 96 to extended substrate specificity in human enteropeptidase. Modeling shows the importance of the charge–charge interactions in the extended substrate binding pocket.     

Refined structures of mouse P‐glycoprotein

The recently determined C. elegans P‐glycoprotein (Pgp) structure revealed significant deviations compared to the original mouse Pgp structure, which suggested possible misinterpretations in the latter model. To address this concern, we generated an experimental electron density map from single‐wavelength anomalous dispersion phasing of an original mouse Pgp dataset to 3.8 Å resolution. The map exhibited significantly more detail compared to the original MAD map and revealed several regions of the structure that required de novo model building. The improved drug‐free structure was refined to 3.8 Å resolution with a 9.4 and 8.1% decrease in R_work and R_free, respectively, (R_work = 21.2%, R_free = 26.6%) and a significant improvement in protein geometry. The improved mouse Pgp model contains ～95% of residues in the favorable Ramachandran region compared to only 57% for the original model. The registry of six transmembrane helices was corrected, revealing amino acid residues involved in drug binding that were previously unrecognized. Registry shifts (rotations and translations) for three transmembrane (TM)4 and TM5 and the addition of three N‐terminal residues were necessary, and were validated with new mercury labeling and anomalous Fourier density. The corrected position of TM4, which forms the frame of a portal for drug entry, had backbone atoms shifted >6 Å from their original positions. The drug translocation pathway of mouse Pgp is 96% identical to human Pgp and is enriched in aromatic residues that likely play a collective role in allowing a high degree of polyspecific substrate recognition.