A chromism-based assay (CHROBA) technique for in situ detection of protein kinase activity

A unique chromism-based assay technique (CHROBA) using photochromic spiropyran-containing peptides has been firstly established for detection of protein kinase A-catalyzed phosphorylation. The alternative method has advantages that avoid isolation and/or immobilization of kinase substrates to remove excess reagents including nonreactive isotope-labeled ATP or fluorescently-labeled anti-phosphoamino acid antibodies from the reaction mixture. Such a novel protocol based on thermocoloration of the spiropyran moiety in the peptide can offer not only an efficient screening method of potent kinase substrates but also a versatile analytical tool for monitoring other post-translational modification activities.     

The product-selective blot: a technique for measuring enzyme activities in large numbers of samples and in native electrophoresis gels

A method termed "product-selective" blotting has been developed for screening large numbers of samples for enzyme activity. The technique is particularly well suited to detection of enzymes in native electrophoresis gels. The principle of the method was demonstrated by blotting samples from glutaminase (EC 3.5.1.2) or glutamate synthase (EC 1.4.7.1) reactions into an agarose gel embedded with ion-exchange resin under conditions favoring binding of product (glutamate) over substrates and other substances in the reaction mixture. After washes to remove these unbound substances, the product was measured using either fluorometric staining or radiometric techniques. Glutaminase activity in native electrophoresis gels was visualized by a related procedure in which substrates and products from reactions run in the electrophoresis gel were blotted directly into a resin-containing "image gel." Considering the selective-binding materials available for use in the image gel, along with the possible detection systems, this method has potentially broad application.     

A new approach to the use of fluorogenic dinitrophenyl-containing substrates for determining the proteolytic activity of aspartyl proteinases

A method for the determination of proteolytic activity of aspartyl proteinases using known colored fluorogenic substrates was developed. The technique utilizes the chromophore properties of the dinitrophenyl (DNP) group. The approach proposed comprises separation of the initial peptide and subsequent measurement of absorption of the solution of the DNP-containing C-terminal fragment, produced by its enzymatic cleavage, at 360 nm. This method was used to determine the activity of calf chymosin, the pepsins from various sources, and the commercial preparations containing a mixture of enzymes without preliminary desalting. The method is simple and applicable under plant conditions.     

A mass spectrometry-based strategy for detecting and characterizing endogenous proteinase activities in complex biological samples

Endogenous proteinases in biological fluids such as human saliva produce a rich peptide repertoire that reflects a unique combination of enzymes, substrates, and inhibitors/activators. Accordingly, this subproteome is an interesting source of biomarkers for disease processes that either directly or indirectly involve proteolysis. However, the relevant proteinases, typically very low abundance molecules, are difficult to classify and identify. We hypothesized that a sensitive technique for monitoring accumulated peptide products in an unbiased, global manner would be very useful for detecting and profiling proteolytic activities in complex biological samples. Building on the longstanding use of 18O isotope-based approaches for the classification of proteolytic and other enzymatic processes we devised a new method for evaluating endogenous proteinases. Specifically, we showed that upon ex vivo incubation endogenous proteinases in human parotid saliva introduced 18O from isotopically enriched water into the C-terminal carboxylic groups of their peptide products. Subsequent peptide sequence determination and inhibitor profiling enabled the detection of discrete subsets of proteolytic products that were generated by different enzymes. As a proof-of-principle we used one of these fingerprints to identify the relevant activity as tissue kallikrein. We termed this technique PALeO. Our results suggest that PALeO is a rapid and highly sensitive method for globally assessing proteinase activities in complex biological samples.     

A new approach to the use of fluorogenic dinitrophenyl-containing substrates for determining the proteolytic activity of aspartyl proteinases

A method for the determination of proteolytic activity of aspartyl proteinases using known colored fluorogenic substrates was developed. The technique utilizes the chromophore properties of the dinitrophenyl (DNP) group. The approach proposed comprises separation of the initial peptide and subsequent measurement of absorption of the solution of the DNP-containing C-terminal fragment, produced by its enzymatic cleavage, at 360 nm. This method was used to determine the activity of calf chymosin, the pepsins from various sources, and the commercial preparations containing a mixture of enzymes without preliminary desalting. The method is simple and applicable under plant conditions.     

ClpP hydrolyzes a protein substrate processively in the absence of the ClpA ATPase: mechanistic studies of ATP-independent proteolysis

ATP-dependent proteases are processive, meaning that they degrade full-length proteins into small peptide products without releasing large intermediates along the reaction pathway. In the case of the bacterial ATP-dependent protease ClpAP, ATP hydrolysis by the ClpA component has been proposed to be required for processive proteolysis of full-length protein substrates. We present here data showing that in the absence of the ATPase subunit ClpA, the protease subunit ClpP can degrade full-length protein substrates processively, albeit at a greatly reduced rate. Moreover, the size distribution of peptide products from a ClpP-catalyzed digest is remarkably similar to the size distribution of products from a ClpAP-catalyzed digest. The ClpAP- and ClpP-generated peptide product size distributions are fitted well by a sum of multiple underlying Gaussian peaks with means at integral multiples of approximately 900 Da (7-8 amino acids). Our results are consistent with a mechanism in which ClpP controls product sizes by alternating between translocation in steps of 7-8 (+/-2-3) amino acid residues and proteolysis. On the structural and molecular level, the step size may be controlled by the spacing between the ClpP active sites, and processivity may be achieved by coupling peptide bond hydrolysis to the binding and release of substrate and products in the protease chamber.     

Determination of enzyme specificity in a complex mixture of peptide substrates by N-terminal sequence analysis.

A method has been developed to determine preferred residue substitutions in the P' position of peptide substrates for proteolytic enzymes. The method has been validated with four different enzymes; the angiotensin I-converting enzyme, atrial dipeptidyl carboxyhydrolase, bacterial dipeptidyl carboxyhydrolase, and meprin A. A mixture of N-acylated potential peptide-substrates for each of the enzymes was prepared in a single synthesis procedure on the same solid-phase synthesis resin. The peptides were identical in all residue positions except the P' position to be studied, into which numerous amino acid residues were incorporated on a theoretical equimolar basis. After cleavage and extraction of the peptides from the resin, no attempt was made to purify them individually; the exact concentration of each peptide in the mixture was determined by quantitative amino acid analysis. Incubation of an enzyme with its peptide-substrate mixture at [S] much less than Km yielded peptide hydrolytic products with newly exposed N-termini. The identity and amount of each hydrolysis product was determined by automated N-terminal sequence analysis. One cycle of sequencing revealed preferred amino acid substitutions in the P'1 position, two cycles the P'2 position, and so forth. Comparison of the rates of production of the various products indicates the preferred substitution in that particular P' position. New information on the substrate specificities of each of the enzymes tested was obtained and it is clear that this approach can be applied to any protease with a defined (or suspected) point of cleavage in a peptide substrate.     

Identification of the C-terminally alpha-amidated amino acid in peptides by high-performance liquid chromatography

A sensitive method for the rapid identification of the C-terminally amidated amino acid in peptides is described. Peptides containing the alpha-amide group at the C-terminus were cleaved with endopeptidases. The fragments released (oligopeptides, amino acids and the C-terminally amidated residue) are coupled to phenylisothiocyanate. The phenylthiocarbamoyl derivative of the amino acid alpha-amide is selectively extracted from the mixture by alkaline butyl acetate and identified by a high-performance liquid chromatography system that enables rapid and complete separation of the derivatives of 17 amino acid amides at a detection limit of 20-50 pmol. The C-terminal alpha-amides of neurokinin-A (Met-NH2), mammalian secretin (Val-NH2), pancreatic polypeptide (Tyr-NH2) and peptide HI (Ile-NH2) are unequivocally determined at a level of 0.5-2 nmol per peptide. This method was used to characterize a crude peptide fraction prepared from porcine brain. Cholecystokinin-58 was identified in this fraction by detection of phenylthiocarbamoyl-phenylalaninamide. The method is suitable for the identification of the C-terminal alpha-amidated residue of purified peptides, but can also be used as a screening strategy to isolate from complex biological extracts novel peptides containing an alpha-amidated amino acid at the C-terminus.     

Improved detection of botulinum neurotoxin type A in stool by mass spectrometry

Botulinum neurotoxins (BoNTs) are the most toxic substances known to humankind. Rapid and sensitive detection of BoNTs is necessary for timely clinical confirmation of the disease state in botulism. BoNTs cleave proteins and peptide mimics at specific sites. A mass spectrometry (MS)-based method, Endopep–MS, can detect these cleavages and has detection limits of 0.05–0.5 mouse LD₅₀ (U) in serum, depending on the BoNT serotypes. In this method, the products generated from cleavage of peptide substrates using antibody affinity-purified toxins are detected by MS. Nonspecific bound endogenous proteases or peptidases in stool can coextract with the toxin, cleaving the peptide substrates and reducing the sensitivity of the method. Here we report a method to reduce nonspecific substrate cleavage by reducing stool protease coextraction in the Endopep–MS assay.     

Fluorescence anisotropy assay for proteolysis of specifically labeled fusion proteins

A cloning method and plasmid vectors that permit fluorescence-anisotropy-based measurement of proteolysis are reported. The recombinant protein substrates produced by this method contain a tetracysteine motif that can be site-specifically labeled with bis-arsenical fluorophore [Science 281 (1998) 269]. Six protein substrates with an N-terminal fusion of the tetracysteine motif and different protease recognition sites were created and tested for reaction with commercial proteases commonly used to process recombinant fusion proteins. In each case, proteolysis of a single susceptible peptide bond could be monitored in real time and with sufficient data quality to allow numerical analysis of proteolysis reaction kinetics. Measurement of proteolysis extent using fluorescence anisotropy is shown to be comparable to densitometry measurements made on denaturing polyacrylamide gels but with the added advantages implicit in a time-resolved measurement, quantification by a spectroscopic measurement, and facile extensibility to high-throughput formats. The assay was also demonstrated as a general tool for monitoring proteolysis of multidomain fusion proteins containing an internal protease site such as are being created in structural genomics studies worldwide.     

High-sensitivity determination of tyrosine-phosphorylated peptides by on-line enzyme reactor and electrospray ionization mass spectrometry.

We describe a simple, fast, sensitive, and nonisotopic bioanalytical technique for the detection of tyrosine-phosphorylated peptides and the determination of sites of protein tyrosine phosphorylation. The technique employs a protein tyrosine phosphatase micro enzyme reactor coupled on-line to either capillary electrophoresis or liquid chromatography and electrospray ionization mass spectrometry instruments. The micro enzyme reactor was constructed by immobilizing genetically engineered, metabolically biotinylated human protein tyrosine phosphatase beta onto the inner surface of a small piece of a 50-microns inner diameter, 360-microns outer diameter fused silica capillary or by immobilization of the phosphatase onto 40-90-microns avidin-activated resins. By coupling these reactors directly to either a capillary electrophoresis column or a liquid chromatography column, we were able to rapidly perform enzymatic dephosphorylation and separation of the reaction products. Detection and identification of the components of the reaction mixture exiting these reactors were done by mass analysis with an on-line electrospray ionization mass spectrometer. Tyrosine-phosphorylated peptides, even if present in a complex peptide mixture, were identified by subtractive analysis of peptide patterns generated with or without phosphatase treatment. Two criteria, namely a phosphatase-induced change in hydropathy and charge, respectively, and a change in molecular mass by 80 Da, were used jointly to identify phosphopeptides. We demonstrate that, with this technique, low picomole amounts of a tyrosine-phosphorylated peptide can be detected in a complex peptide mixture generated by proteolysis of a protein and that even higher sensitivities can be realized if more sensitive detection systems are applied.     

Temperature dependence of the thrombin-catalyzed proteolysis of prothrombin

Measurement of the temperature-dependence of thrombin-catalyzed cleavage of the Arg(155)-Ser(156) and Arg(284)-Thr(285) peptide bonds in prothrombin and prothrombin-derived substrates has yielded Arrhenius parameters that are far too large for classical mechanistic interpretation in terms of a simple hydrolytic reaction. Such a difference from the kinetic behavior exhibited in trypsin- and chymotrypsin-catalyzed proteolysis of peptide bonds is attributed to contributions by enzyme exosite interactions as well as enzyme conformational equilibria to the magnitudes of the experimentally determined Arrhenius parameters. Although the pre-exponential factor and the energy of activation deduced from the temperature-dependence of rate constants for proteolysis by thrombin cannot be accorded the usual mechanistic significance, their evaluation serves a valuable role by highlighting the existence of contributions other than those emanating from simple peptide hydrolysis to the kinetics of proteolysis by thrombin and presumably other enzymes of the blood coagulation system.     

Pericellular proteolysis by leukocytes and tumor cells on substrates: focal activation and the role of urokinase-type plasminogen activator

Previous studies have shown that the urokinase-type plasminogen activator receptor (uPAR) is localized to the adherence sites of leukocytes and tumor cells suggesting that pericellular proteolysis may accompany focal activation of adherence. To assess for focused pericellular proteolytic activity, we prepared two-dimensional substrates coated with FITC-casein or Bodipy FL-BSA. These molecules are poorly fluorescent, but become highly fluorescent after proteolytic degradation. Fluorescent peptide products were observed at adherence sites of stationary human neutrophils and at lamellipodia of polarized neutrophils. During cell migration, multiple regions of proteolysis appeared sequentially beneath the cell. Similarly, proteolytic action was restricted to adherence sites of resting HT1080 tumor cells but localized to the invadopodia of active cells. Using an extracellular fluorescence quenching method, we demonstrate that these fluorescent peptide products are extracellular. The uPA/uPAR system played an important role in the observed proteolytic activation. Plasminogen activator inhibitor-1 significantly reduced focal proteolysis. Sites of focal proteolysis matched the membrane distribution of uPAR. When uPA was dissociated from uPAR by acid washing, substantially reduced pericellular proteolysis was found. uPAR-negative T47D tumor cells did not express significant levels of substrate proteolysis. However, transfectant clones expressing uPAR (for example, T47D-26) displayed high levels of fluorescence indicating proteolysis at adherence sites. To provide further evidence for the role of the uPA/uPAR system in pericellular proteolysis, peritoneal macrophages from uPA knock-out (uPA–/–) and control (uPA+/+) mice were studied. Pericellular proteolysis was dramatically reduced in uPA-negative peritoneal macrophages. Thus, we have: (1) developed a novel methodology to detect pericellular proteolytic function, (2) demonstrated focused activation of proteolytic enzymatic activity in several cell types, (3) demonstrated its usefulness in real-time studies of cell migration, and (4) showed that the uPA/uPAR system is an important contributor to focal pericellular proteolysis.     

Antibody-free peptide substrate screening of serine/threonine kinase (protein kinase A) with a biotinylated detection probe

Being different from anti-phosphotyrosine antibodies, anti-phosphoserine- or anti-phosphothreonine-specific antibodies with high affinity for the detection of serine/threonine kinase substrates are not readily available. Therefore, chemical modification methods were developed for the detection of phosphoserine or threonine in the screening of protein kinase substrates based on β-elimination and Michael addition. We have developed a biotin-based detection probe for identification of the phosphorylated serine or threonine residue. A biotin derivative induced a color reaction using alkaline phosphate-conjugated streptavidin that amplified the signal. It was effective for the detection and separation of the target peptide on the resin. The detection probe was successfully used in identifying PKA substrates from peptide libraries on resin beads. The peptide library was prepared as a ladder-type, such that the active peptides on the colored resin beads were readily sequenced with the truncated peptide fragments by MALDI-TOF/MS analysis after releasing the peptides from the resin bead through photolysis.     

Isolation and partial chemical characterization of the three major yolk polypeptides from Drosophila melanogaster.

The three major yolk polypeptides of Drosophila melanogaster have been isolated from yolk spheres of early embryos. Their molecular weights, as determined by SDS-polyacrylamide electrophoresis, are 44,000, 45,000, and 46,000. A number of approaches have been used to show that each of these yolk polypeptides are different. They have different isoelectric points, they have different digestion products upon peptide mapping by limited proteolysis, and they show three different antigen-antibody systems when each polypeptide is reacted with an antisera made to a mixture of all three. Both the digestion with chymotrypsin and the immunoelectrophoresis studies indicate similarities between two of the polypeptides while the third appears unique. This is the first example of multiple yolk polypeptides of similar molecular weight.     

A PDZ domain-based assay for measuring HIV protease activity: assay design considerations

We have recently described a biochemical detection method for peptide products of enzymatic reactions based on the formation of PDZ domain*peptide ligand complexes. The product sensor is based on using masked or cryptic PDZ domain peptide ligands as enzyme substrates. Upon enzymatic processing, a PDZ-binding motif is exposed, and the product sequence bound specifically by a Eu(3+)chelate-labeled GST-PDZ ([Eu(3+)]GST-PDZ). The practical applicability of this PDZ-based detection method is determined by the affinity of the PDZ domain*peptide ligand interaction, and the efficiency of the enzyme to process the masked peptide ligand. To expand the use of this PDZ-based detection strategy to a broader range of enzymatic assays, we have taken advantage of the plasticity in ligand recognition by the variety of PDZ domains found in nature. In the original work, the PDZ3 of PSD-95 was used, which preferentially recognizes the consensus sequence Ser-X-Val-COOH. Here, we show that NHERF PDZ1, which binds to the consensus sequence Thr/Ser-X-Leu-COOH, can be used to extend the flexibility in the recognition of the carboxy-terminal amino acid of the ligand, and monitor the enzymatic activity of HIV protease. The choices of detection format, for example, TRET or ALPHA, were also investigated and influenced assay design.     

Proteolysis of vimentin and desmin by the Ca2+-activated proteinase specific for these intermediate filament proteins.

The degradation of vimentin and desmin by the Ca2+-activated proteinase specific for these intermediate filament proteins proceeds in two stages in the form of a limited proteolysis. At first, the reaction is very rapid, with the stepwise and complete removal of a peptide (ca. 9,000 daltons) from the N-terminal of vimentin and desmin. This results in the production of a characteristic "staircase" of degradation products, as seen in two-dimensional polyacrylamide gel electrophoresis. The second stage of proteolysis is characterized by the accumulation of peptides which are resistant to further proteolysis; this is due not to product inhibition but to the fact that these peptides are not substrates for the proteinase and therefore do not protect the latter from inactivation (autodigestion). In vitro phosphorylation of the substrates does not affect proteinase activity, probably because the phosphorylation site is located towards the C-terminal of the molecules. The specific and limited proteolysis of vimentin and desmin results in the deletion of the nucleic acid binding and filament assembly site of these proteins, indicating that the Ca2+-activated proteinase plays a role in regulating the function(s) of these intermediate filament proteins, rather than their simple turnover during the cell cycle.     

A possible approach to the analysis of protease mixtures

A problem of quantitative assay of proteases in complex mixtures is solved by using a set of peptide substrates with detectable (chromogenic or fluorogenic) groups (DGs). Quantitation of separate DGs released in reaction of enzyme mixture with a set of substrates is carried out in chromatographic analysis of reaction products. Reaction of peptide derivatives of aminonaphthalene sulfamides with a mixture of thrombin and proteases from viper venom shows the amounts of produced DGs to be proportional to the amounts of both thrombin and venom proteases, confirming the validity of proposed approach. There are cases of mutual influence of some components in proteases mixtures as illustrated by inhibition of trypsin activity in presence of viper venom; one determines enzyme activities in this specific mixture rather than their amounts.     

Assay of myosin light chain kinase activity by high-performance liquid chromatography using a synthetic peptide as substrate.

The most popular method to determine the activity of myosin light chain kinase is to measure the radioactivity incorporated from [gamma-32P]ATP into phosphoryl-accepting substrates. In this paper, we report a new method for determination of myosin light chain kinase activity without using radioisotopes. Synthetic peptides and nonradiolabeled ATP were used as substrate, and the peptide substrate was phosphorylated by myosin light chain kinase purified from chicken gizzard. After terminating the reaction, the reaction mixture was directly injected into a reversed-phase HPLC column without pretreatment, separated with the isocratic solvent system of acetonitrile-H2O-trifluoroacetic acid, and monitored at 220 nm uv absorbance. The reaction rate was determined from the peak areas of phosphorylated and unphosphorylated peptides. One chromatographic separation was achieved within 9 min, and the analysis could be repeated successively more than 100 times without washing the column. Using this method, we measured the differential inhibition of myosin light chain kinase by various inhibitors. With the aid of an automatic injector, the HPLC method with synthetic peptide enables us to handle many samples quickly and is useful for screening new myosin light chain kinase inhibitors.     

The Use of an Escherichia coli Lys- Auxotroph to Assay Nutritionally Available Lysine in Biological Materials

A new bacterial method for determining amino acids in protein foods is described. Instead of the 'natural'microbial auxotrophs e.g. Tetrahymena, Streptococcus , and Leuconostoc , currently used for such assays, an 'artificial'mutant is used, viz. an auxotroph of Escherichia coli . Test proteins (Bovine serum albumin, legume and maize meals) were predigested with a mixture of pronase and intestinal peptidases, the efficiency and extent of proteolysis being monitored by pH stat titration. Final digests were examined by Sephadex gel filtration to ensure that all protein cleavage products were small enough to pass through the E. coli cell wall and to reach its cyto-plasmic amino acid and peptide permeases. The lysine content of the meals, as determined from the growth of an E. coli lysine auxotroph upon the digests, was found to be greater than 90° of the lysine determined chemically in acid hydrolysates. Practical and theoretical advantages of using this latter type of bacterium rather than the fastidious species are discussed. In addition, the particular value of using an intestinal bacterium like E. coli to assay nutritional availability of amino acids is considered in relation to its normal utilization of digested protein foods in vivo , and the similarities between its amino acid and peptide permeases and those of the intestine.