A microplate assay specific for the enzyme aggrecanase

We have identified a 41-residue peptide, bracketing the aggrecanase cleavage site of aggrecan, that serves as a specific substrate for this enzyme family. Biotinylation of the peptide allowed its immobilization onto streptavidin-coated plates. Aggrecanase-mediated hydrolysis resulted in an immobilized product that reveals an N-terminal neoepitope, recognized by the specific antibody BC-3. This assay is highly specific for aggrecanases; MMPs were inactive in this assay. Reduction of the peptide size below 30 amino acids resulted in a significant diminution of activity. Using the immobilized 41-residue peptide as a substrate, we have developed a 96-well microplate-based assay that can be conveniently used for high-throughput screening of samples for aggrecanase activity and for discovery of inhibitors of aggrecanase activity.     

Microsphere-based protease assays and screening application for lethal factor and factor Xa.

BACKGROUND: Proteases regulate many biological pathways in humans and are components of several bacterial toxins. Protease studies and development of protease inhibitors do not follow a single established methodology and are mostly protease specific. METHODS: We have created recombinant fusion proteins consisting of a biotinylated attachment sequence linked to a GFP via a protease cleavage site to develop a multiplexable microsphere-based protease assay system. Using the proteases lethal factor and factor Xa, we performed kinetic experiments to determine optimal conditions for inhibitor screens and detect known inhibitors using the HyperCyt flow cytometry system. RESULTS: We have demonstrated specific cleavage of lethal factor and factor Xa substrates, optimized screening conditions for these substrates, shown specific inhibition of the proteases, and demonstrated high throughput detection of these inhibitors. CONCLUSIONS: The assay developed here is adaptable to any site-specific protease, compatible with high throughput flow cytometry systems, and multiplexable. Coupled with flow cytometry, which provides continuous time resolution and intrinsic resolution of free vs. bound fluorophores, this assay will be useful for high throughput screening of protease inhibitors in general and could simplify assays designed to determine protease mechanism.     

A radiometric assay for HIV-1 protease

A rapid, high-throughput radiometric assay for HIV-1 protease has been developed using ion-exchange chromatography performed in 96-well filtration plates. The assay monitors the activity of the HIV-1 protease on the radiolabeled form of a heptapeptide substrate, [tyrosyl-3,5-3H]Ac-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2, which is based on the p17-p24 cleavage site found in the viral polyprotein substrate Pr55gag. Specific cleavage of this uncharged heptapeptide substrate by HIV-1 protease releases the anionic product [tyrosyl-3,5-3H]Ac-Ser-Gln-Asn-Tyr, which is retained upon minicolumns of the anion-exchange resin AG1-X8. Protease activity is determined from the recovery of this radiolabeled product following elution with formic acid. This facile and highly sensitive assay may be utilized for steady-state kinetic analysis of the protease, for measurements of enzyme activity during its purification, and as a routine assay for the evaluation of protease inhibitors from natural product or synthetic sources.     

Beta galactosidase enzyme fragment complementation as a high-throughput screening protease technology

The authors describe a homogeneous, high-throughput screening (HTS) assay for measuring protease activity and detection of inhibitors. The assay comprises a cyclic beta-galactosidase (beta-gal) enzyme donor peptide (ED) containing a protease-selective cleavage sequence. Alone, the cyclic peptide is inactive, but when linearized following protease cleavage, ED complements with beta-gal enzyme acceptor forming active beta-gal enzyme. This then catalyzes the formation of either fluorescent or chemiluminescent products, with beta-gal turnover providing a highly amplified signal, and thus an assay technology of high sensitivity. To demonstrate the utility of the technology, an EFC assay was developed to measure the activity of 2, caspase 3 and beta-secretase. Using a cyclic ED containing the caspase 3 substrate sequence, DEVD, the EFC assay signal was linear with respect to caspase 3 concentration. The assay was very sensitive, being able to detect activity at low picogram amounts of caspase 3. For the beta-secretase (BACE) EFC assay, a cyclic ED containing the Swedish mutant cleavage site of amyloid precursor protein (APP), SEVNLDAEFK, was used. In a similar fashion to the caspase 3 assay, the signal induced by BACE activity was linear with respect to enzyme concentration and was highly sensitive, being able to detect nanogram quantities of BACE. The assay was also more sensitive than a commercially available FRET-based assay of BACE activity. It is concluded that the EFC protease assay is a simple, flexible, and sensitive technology for HTS of proteases.     

A high throughput assay for inhibitors of HIV-1 protease. Screening of microbial metabolites

A novel method for discovery of HIV-1 protease inhibitors in complex biological samples has been developed. The assay is based on two specific reagents: a recombinant protein constituted by a portion of the HIV-1 Gag polyprotein comprising the p17-p24 cleavage site, fused to E. coli beta-galactosidase, and a monoclonal antibody which binds the fusion protein in the Gag region. Binding occurs only if the fusion protein has not been cleaved by the HIV-1 protease. The assay has been adapted for the screening of large numbers of samples in standard 96-well microtiter plates. Using this method about 12000 microbial fermentation broths have been tested and several HIV-1 protease inhibitory activities have been detected. One of these has been studied in detail.     

Bioluminescence detection of proteolytic bond cleavage by using recombinant aequorin

Detection of proteolytic bond cleavage was achieved by taking advantage of the bioluminescence emission generated by the photoprotein aequorin. A genetically engineered HIV-1 protease substrate was coupled with a cysteine-free mutant of aequorin by employing the polymerase chain reaction to produce a fusion protein that incorporates an optimum natural protease cleavage site. The fusion protein was immobilized on a solid phase and employed as the substrate for the HIV-1 protease. Proteolytic bond cleavage was detected by a decrease in the bioluminescence generated by the aequorin fusion protein on the solid phase. A dose-response curve for HIV-1 protease was constructed by relating the decrease in bioluminescence signal with varying amounts of the protease. The system was also used to evaluate two competitive and one noncompetitive inhibitor of the HIV-1 protease. Among the advantages of this assay is that by using recombinant methods a complete bioluminescently labeled protease recognition site can be designed and produced. The assay yields very sensitive detection limits, which are inherent to bioluminescence-based methods. An application of this system may be in the high-throughput screening of biopharmaceutical drugs that are potential inhibitors of a target protease.     

A cleavage enzyme-cytometric bead array provides biochemical profiling of resistance mutations in HIV-1 Gag and protease

Most protease-substrate assays rely on short, synthetic peptide substrates consisting of native or modified cleavage sequences. These assays are inadequate for interrogating the contribution of native substrate structure distal to a cleavage site that influences enzymatic cleavage or for inhibitor screening of native substrates. Recent evidence from HIV-1 isolates obtained from individuals resistant to protease inhibitors has demonstrated that mutations distal to or surrounding the protease cleavage sites in the Gag substrate contribute to inhibitor resistance. We have developed a protease-substrate cleavage assay, termed the cleavage enzyme- cytometric bead array (CE-CBA), which relies on native domains of the Gag substrate containing embedded cleavage sites. The Gag substrate is expressed as a fluorescent reporter fusion protein, and substrate cleavage can be followed through the loss of fluorescence utilizing flow cytometry. The CE-CBA allows precise determination of alterations in protease catalytic efficiency (k(cat)/K(M)) imparted by protease inhibitor resistance mutations in protease and/or gag in cleavage or noncleavage site locations in the Gag substrate. We show that the CE-CBA platform can identify HIV-1 protease present in cellular extractions and facilitates the identification of small molecule inhibitors of protease or its substrate Gag. Moreover, the CE-CBA can be readily adapted to any enzyme-substrate pair and can be utilized to rapidly provide assessment of catalytic efficiency as well as systematically screen for inhibitors of enzymatic processing of substrate.     

Luminometric method for screening retroviral protease inhibitors

We have developed a sensitive luminometric assay for determining the activity of retroviral proteases that uses proteolytic cleavage of polypeptide substrate immobilized on Ni-NTA HisSorb Strips microplates. The protease substrate derived from the Gag precursor protein of Mason-Pfizer monkey virus (M-PMV) was conjugated with horseradish peroxidase (HRP), which catalyzes oxidation of luminol in the assay. The cleavage of the substrate was monitored as a decrease in luminescent signal caused by the release of the cleavage product conjugated to HRP. Testing of a set of M-PMV protease inhibitors confirmed that this method is sufficiently sensitive and specific for high-throughput screening of retroviral protease inhibitors.     

In vivo selection of protease cleavage sites by using chimeric Sindbis virus libraries

Identifying protease cleavage sites contributes to our understanding of their specificity and biochemical properties and can help in designing specific inhibitors. One route to this end is the generation and screening of random libraries of cleavage sites. Both synthetic and phage-displayed libraries have been extensively used in vitro. We describe a novel system based on recombinant Sindbis virus which can be used to identify cleavage sites in vivo, thus eliminating the need for a purified enzyme and overcoming the problem of choosing the correct in vitro conditions. As a model we used the serine protease of the hepatitis C virus (HCV). We engineered the gene coding for this enzyme and two specific cleavage sites in the Sindbis virus structural gene and constructed libraries of viral genomes with a random sequence at either of the cleavage sites. The system was designed so that only viral genomes coding for sequences cleaved by the protease would produce viable viruses. With this system we selected viruses containing sequences mirroring those of the natural HCV protease substrates which were cleaved with comparable efficiencies.     

An immunoenzymatic solid-phase assay for quantitative determination of HIV-1 protease activity

A novel immunoenzymatic procedure for the quantitative determination of HIV protease activity is provided. An N-terminal biotinylated peptide (DU1) that comprises an HIV-1 protease (HIV-PR) cleavage sequence was bound to streptavidin-coated microtiter plates. The bound peptide can be quantified by an immunoenzymatic procedure (enzyme-linked immunosorbent assay, ELISA) that includes a monoclonal antibody (Mab 332) against the peptide (DU1) C-terminal. The incubation of the bound peptide with HIV-PR in solution resulted in a signal decrement, as the peptide was hydrolyzed and the released C-terminal segment washed away. An equation that relates the amount of added enzyme to the kinetics of the reaction was written in order to describe this heterogeneous enzyme-quasi-saturable system. This equation allows quantitative determination of protease activity, a feature widely underrated in previous similar assays. The assay also allows evaluation of the inhibitory activity of HIV-PR inhibitors. Due to the intrinsic advantages of the ELISA format, this method could be used in high-throughput screening of HIV protease inhibitors. The assay can be extended to other proteolytic enzymes.     

Chemical synthesis and expression of the HIV-1 protease gene in E. coli

The 297bp HIV-1 protease gene was constructed from five discrete synthetic fragments and expressed in E. coli. A soluble protein product of 11.5 Kd was detected by immunoblotting using protease specific antisera. A quantitative assay system, utilizing a synthetic nonapeptide spanning the cleavage site between p17-p24 in the gag polyprotein, was used to measure the specific protease activity in crude extracts. The protease hydrolyzed tyrosyl-proline bonds with an approximate specific activity of 43 pmoles/min/micrograms of total protein. The chemical synthesis of the protease gene and it's expression provides a feasible method for rapid mutant analysis, important for structure-function studies and rational design of potential inhibitors.     

Sensitive genetic screen for protease activity based on a cyclic AMP signaling cascade in Escherichia coli

We describe a genetic system that allows in vivo screening or selection of site-specific proteases and of their cognate-specific inhibitors in Escherichia coli. This genetic test is based on the specific proteolysis of a signaling enzyme, the adenylate cyclase (AC) of Bordetella pertussis. As a model system we used the human immunodeficiency virus (HIV) protease. When an HIV protease processing site, p5, was inserted in frame into the AC polypeptide, the resulting ACp5 protein retained enzymatic activity and, when expressed in an E. coli cya strain, restored the Cya(+) phenotype. The HIV protease coexpressed in the same cells resulted in cleavage and inactivation of ACp5; the cells became Cya(-). When the entire HIV protease, including its adjacent processing sites, was inserted into the AC polypeptide, the resulting AC-HIV-Pr fusion protein, expressed in E. coli cya, was autoproteolysed and inactivated: the cells displayed Cya(-) phenotype. In the presence of the protease inhibitor indinavir or saquinavir, AC-HIV-Pr autoproteolysis was inhibited and the AC activity of the fusion protein was preserved; the cells were Cya(+). Protease variants resistant to particular inhibitors could be easily distinguished from the wild type, as the cells displayed a Cya(-) phenotype in the presence of these inhibitors. This genetic test could represent a powerful approach to screen for new proteolytic activities and for novel protease inhibitors. It could also be used to detect in patients undergoing highly active antiretroviral therapy the emergence of HIV variants harboring antiprotease-resistant proteases.     

In vitro study of the NS2-3 protease of hepatitis C virus.

Processing at the C terminus of the NS2 protein of hepatitis C virus (HCV) is mediated by a virus-encoded protease which spans most of the NS2 protein and part of the NS3 polypeptide. In vitro cotranslational cleavage at the 2-3 junction is stimulated by the presence of microsomal membranes and ultimately results in the membrane insertion of the NS2 polypeptide. To characterize the biochemical properties of this viral protease, we have established an in vitro assay whereby the NS2-3 protease of HCV BK can be activated posttranslationally by the addition of detergents. The cleavage proficiency of several deletion and single point mutants was the same as that observed with microsomal membranes, indicating that the overall sequence requirements for proper cleavage at this site are maintained even under these artificial conditions. The processing efficiency of the NS2-3 protease varied according to the type of detergent used and its concentration. Also, the incubation temperature affected the cleavage at the 2-3 junction. The autoproteolytic activity of the NS2-3 protease could be inhibited by alkylating agents such as iodoacetamide and N-ethylmaleimide. Metal chelators such as EDTA and phenanthroline also inhibited the viral enzyme. The EDTA inhibition of NS2-3 cleavage could be reversed, at least in part, by the addition of ZnCl2 and CdCl2. Among the common protease inhibitors tested, tosyl phenylalanyl chloromethyl ketone and soybean trypsin inhibitor inactivated the NS2-3 protease. By means of gel filtration analysis, it was observed that the redox state of the reaction mixture greatly influenced the processing efficiency at the 2-3 site and that factors present in the rabbit reticulocyte lysate, wheat germ extract, and HeLa cell extract were required for efficient processing at this site. Thus, the in vitro assay should allow further characterization of the biochemical properties of the NS2-3 protease of HCV and the identification of host components that contribute to the efficient processing at the 2-3 junction.     

Molecular characterization of the protease from Clostridium botulinum serotype C responsible for nicking in botulinum neurotoxin complex

A protease was purified from the culture medium of Clostridium botulinum serotype C strain Stockholm (C-St). The purified protease belonged to the cysteine protease family based on assays for enzyme inhibitors, activators and kinetic parameters. The protease formed a binary complex consisting of 41- and 17-kDa proteins held together non-covalently. The DNA sequence encoding the protease gene was shown to be a single open reading frame of 1593 nucleotides, predicting 530 amino acid residues including a signal peptide. The N-terminal region of the native enzyme underwent further proteolytic modification after processing by a signal peptidase. The protease introduced intermolecular cleavage into an intact single chain botulinum neurotoxin (BoNT) at a specific site. Homology modeling and docking simulation of C-St BoNT and C-St protease demonstrated that the specific nicking-site of the BoNT appears to fit into the deep pocket in the active site of the protease.     

Competitive inhibition of the dengue virus NS3 serine protease by synthetic peptides representing polyprotein cleavage sites

The NS3 serine protease of dengue virus is required for the maturation of the viral polyprotein and consequently represents a promising target for the development of antiviral inhibitors. However, the substrate specificity of this enzyme has been characterized only to a limited extent. In this study, we have investigated product inhibition of the NS3 protease by synthetic peptides derived from the P6-P1 and the P1'-P5' regions of the natural polyprotein substrate. N-terminal cleavage site peptides corresponding to the P6-P1 region of the polyprotein were found to act as competitive inhibitors of the enzyme with K(i) values ranging from 67 to 12 microM. The lowest K(i) value was found for the peptide representing the NS2A/NS2B cleavage site, RTSKKR. Inhibition by this cleavage site sequence was analyzed by using shorter peptides, SKKR, KKR, KR, AGRR, and GKR. With the exception of the peptide AGRR which did not inhibit the protease at a concentration of 1mM, all other peptides displayed K(i) values in the range from 188 to 22 microM. Peptides corresponding to the P1'-P5' region of the polyprotein cleavage sites had no effect on enzymatic activity at a concentration of 1mM. Molecular docking data of peptide inhibitors to a homology-based model of the dengue virus type 2 NS2B(H)-NS3p co-complex indicate that binding of the non-prime site product inhibitors is similar to ground-state binding of the corresponding substrates.     

Molecular and enzymatic characterization of the porcine endogenous retrovirus protease

The protease of the porcine endogenous retrovirus (PERV) subtypes A/B and C was recombinantly expressed in Escherichia coli as proteolytically active enzyme and characterized. The PERV Gag precursor was also recombinantly produced and used as the substrate in an in vitro enzyme assay in parallel with synthetic nonapeptide substrates designed according to cleavage site sequences identified in the PERV Gag precursor. The proteases of all PERV subtypes consist of 127 amino acid residues with an M(r) of 14,000 as revealed by determining the protease N and C termini. The PERV proteases have a high specificity for PERV substrates and do not cleave human immunodeficiency virus (HIV)-specific substrates, nor are they inhibited by specific HIV protease inhibitors. Among the known retroviral proteases, the PERV proteases resemble most closely the protease of the murine leukemia retrovirus.     

Identification of inhibitors using a cell-based assay for monitoring Golgi-resident protease activity

Noninvasive real-time quantification of cellular protease activity allows monitoring of enzymatic activity and identification of activity modulators within the protease's natural milieu. We developed a protease activity assay based on differential localization of a recombinant reporter consisting of a Golgi retention signal and a protease cleavage sequence fused to alkaline phosphatase (AP). When expressed in mammalian cells, this protein localizes to Golgi bodies and, on protease-mediated cleavage, AP translocates to the extracellular medium where its activity is measured. We used this system to monitor the Golgi-associated protease furin, a pluripotent enzyme with a key role in tumorigenesis, viral propagation of avian influenza, ebola, and HIV as well as in activation of anthrax, pseudomonas, and diphtheria toxins. This technology was adapted for high-throughput screening of 39,000-compound small molecule libraries, leading to identification of furin inhibitors. Furthermore, this strategy was used to identify inhibitors of another Golgi protease, the beta-site amyloid precursor protein (APP)-cleaving enzyme (BACE). BACE cleavage of the APP leads to formation of the Abeta peptide, a key event that leads to Alzheimer's disease. In conclusion, we describe a customizable noninvasive technology for real-time assessment of Golgi protease activity used to identify inhibitors of furin and BACE.     

Compensatory substitutions in the HCV NS3/4A protease cleavage sites are not observed in patients treated unsuccessfully with telaprevir combination treatment

ABSTRACT: BACKGROUND: Development of compensatory mutations within the HIV p7/p1 and p1/p6 protease cleavage site region has been observed in HIV-infected patients treated with protease inhibitors. Mechanisms of fitness compensation may occur in HCV populations upon treatment of HCV protease inhibitors as well. FINDINGS: In this study, we investigated whether substitutions in protease cleavage site regions of HCV occur in response to a treatment regimen containing the NS3/4A protease inhibitor telaprevir (TVR). Evaluation of viral populations from 569 patients prior to treatment showed that the four NS3/4A cleavage sites were well conserved. Few changes in the cleavage site regions were observed in the 159 patients who failed TVR combination treatment, and no residues displayed evidence of directional selection after the acquisition of TVR-resistance. CONCLUSIONS: Cleavage site mutations did not occur after treatment with the HCV protease inhibitor telaprevir.     

Notch and the amyloid precursor protein are cleaved by similar gamma-secretase(s)

Gamma-secretase is an intramembrane-cleaving protease whose substrates include Notch and the amyloid precursor protein (APP). On the basis of initial genetic and pharmacologic data, the gamma-secretase activity responsible for cleavage of both proteins appears to be identical. However, apparent differences in the cleavage site and in sequence specificity raise questions about the degree of similarity between Notch and APP gamma-like proteolysis. In an effort to resolve this issue directly, we established an in vitro gamma-secretase activity assay that cleaves both APP- and Notch-based substrates, C100Flag and N100Flag. Analysis with specific gamma-secretase inhibitors, dominant-negative gamma-secretase preparations, and antibody co-immunoprecipitations all demonstrated identical cleavage of these substrates. Most importantly, we found that these substrates prevented cleavage of each other, indicating that the same gamma-secretase complex can cleave either protein. Finally, we provide evidence that both substrates are cut at two distinct regions in the transmembrane domain. These data resolve some of the apparent conflicts and strongly indicate that Notch and APP are proteolyzed by the same enzyme(s).     

Substrate screening identifies a novel target sequence for the proteasomal activity regulated by ionizing radiation

The screening for treatment‐induced enzyme activities offers the opportunity to discover important regulatory mechanisms and the identification of potential targets for anti‐cancer therapies. A novel screening technique was applied to screen substrate peptide sequences for proteolytic activities up‐ or down‐regulated by ionizing radiation in tumor cells. One specific substrate sequence was cleaved in control cell extracts but to a smaller extent in irradiated cell extracts and investigated in detail. Based on protease‐class‐specific inhibitory studies and cleavage site analysis a potent warhead‐inhibitor was synthesized and used to identify the proteasome as the protease of interest. The investigated sequence shows high homology to a regulatory site of nucleoporin 50, an element of the nuclear pore complex, and site specific cleavage of nucleoporin 50 was determined in vitro suggesting a novel link between the ionizing radiation‐regulated proteasome and nuclear protein shuttling.