Clostridium histolyticum collagenase: development of new thio ester, fluorogenic, and depsipeptide substrates and new inhibitors

A new series of thio ester, depsipeptide, and peptide substrates have been synthesized for the bacterial enzyme Clostridium histolyticum collagenase. The hydrolysis of the depsipeptide substrate was followed on a pH stat, and thio ester hydrolysis was measured by inclusion of the chromogenic thiol reagent 4,4'-dithiopyridine in the assay mixture. The best thio ester substrate, Boc-Abz-Gly-Pro-Leu-SCH2CO-Pro-Nba, had a kcat/KM of 63 000 M-1 s-1, while several shorter thio ester sequences were inactive as substrates. In general, the peptide analogues of all the reactive thio ester substrates were shown to be hydrolyzed 5-10 times faster by collagenase. In one case (Z-Gly-Pro-Leu-Gly-Pro-NH2) where a comparison was made, the peptide substrate was respectively 8- and 106-fold more readily hydrolyzed than the corresponding thio ester and ester substrates. Cleavages of the two fluorescence-quench substrates Abz-Gly-Pro-Leu-Gly-Pro-Nba and Abz-Gly-Pro-Leu-SCH2CO-Pro-Nba could be easily followed fluorogenically since a 5-10-fold increase in fluorescence occurred upon hydrolysis. The fluorescent peptide substrate is the best synthetic substrate known for C. histolyticum collagenase with a kcat/KM value of 490 000 M-1 s-1. A series of new reversible inhibitors were developed by the attachment of zinc ligating groups (hydroxamic acid, carboxymethyl, and thiol) to various peptide sequences specific for C. histolyticum collagenase. The shorter peptides designed to bind to either the P3-P1 or P1'-P3' subsites were poor to moderate inhibitors. The thiol HSCH2CH2CO-Pro-Nba had the lowest K1 (0.02 mM).(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of vertebrate collagenase and gelatinase using a new fluorogenic substrate peptide

A fluorogenic substrate for vertebrate collagenase and gelatinase, Dnp-Pro-Leu-Gly-Leu-Trp-Ala-D-Arg-NH2, was designed using structure-activity data obtained from studies with synthetic inhibitors and other peptide substrates of collagenase. Tryptophan fluorescence was efficiently quenched by the NH2-terminal dinitrophenyl group, presumably through resonance energy transfer. Increased fluorescence accompanied hydrolysis of the peptide by collagenase or gelatinase purified from culture medium of porcine synovial membranes or alkali-treated rabbit corneas. Amino acid analysis of the two product peptides showed that collagenase and gelatinase cleaved at the Gly-Leu bond. The peptide was an efficient substrate for both enzymes, with kcat/Km values of 5.4 microM-1 h-1 and 440 microM-1 h-1 (37 degrees C, pH 7.7) for collagenase and gelatinase, respectively. Under the same conditions, collagenase gave kcat/Km of about 46 microM-1 h-1 for type I collagen from calf skin. Since both enzymes exhibited similar Km values for the synthetic substrate (3 and 7 microM, respectively), the higher catalytic efficiency of gelatinase reflects predominantly an increase in kcat. Both enzymes were inhibited by HSCH2(R,S)CH[CH2CH(CH3)2]CO-L-Phe-L-Ala-NH2 in this assay (50% inhibition at 20 nM and less than 1 nM for collagenase and gelatinase, respectively). Soluble type I collagen was a competitive inhibitor of peptide hydrolysis by collagenase (KI = 0.8 microM) and exhibited mixed inhibition of gelatinase (KI = 0.3 microM).     

Substrate specificity of human collagenase 3 assessed using a phage-displayed peptide library

The substrate specificity of human collagenase 3 (MMP-13), a member of the matrix metalloproteinase family, is investigated using a phage-displayed random hexapeptide library containing 2 x 10(8) independent recombinants. A total of 35 phage clones that express a peptide sequence that can be hydrolyzed by the recombinant catalytic domain of human collagenase 3 are identified. The translated DNA sequence of these clones reveals highly conserved putative P1, P2, P3 and P1', P2', and P3' subsites of the peptide substrates. Kinetic analysis of synthetic peptide substrates made from human collagenase 3 selected phage clones reveals that some of the substrates are highly active and selective. The most active substrate, 2, 4-dinitrophenyl-GPLGMRGL-NH(2) (CP), has a k(cat)/K(m) value of 4.22 x 10(6) m(-)(1) s(-)(1) for hydrolysis by collagenase 3. CP was synthesized as a consensus sequence deduced from the preferred subsites of the aligned 35 phage clones. Peptide substrate CP is 1300-, 11-, and 820-fold selective for human collagenase 3 over the MMPs stromelysin-1, gelatinase B, and collagenase 1, respectively. In addition, cleavage of CP is 37-fold faster than peptide NF derived from the major MMP-processing site in aggrecan. Phage display screening also selected five substrate sequences that share sequence homology with a major MMP cleavage sequence in aggrecan and seven substrate sequences that share sequence homology with the primary collagenase cleavage site of human type II collagen. In addition, putative cleavage sites similar to the consensus sequence are found in human type IV collagen. These findings support previous observations that human collagenase 3 can degrade aggrecan, type II and type IV collagens.     

A new and highly sensitive fluorescence assay for collagenase-like peptidase activity.

A highly sensitive fluorescence assay for collagenase-like peptidase (CL-peptidase) has been developed using a newly synthesized substrate, (succinyl-Gly-Pro-Leu-Gly-Pro)-4-methylcoumaryl-7-amide (Suc-GPLGP-MCA). Suc-GPLGP-MCA was hydrolyzed at the Leu-Gly bond by CL-peptidase, (Gly-Pro)-4-methylcoumaryl-7-amide liberated by the enzyme was immediately hydrolyzed to Gly-Pro and 7-amino-4-methylcoumarin (AMC) by an excess of an auxiliary enzyme, X-prolyl dipeptidyl-aminopeptidase, and the fluorescence intensity of the AMC was measured at 460 nm with excitation at 380 nm. When assayed by this method, CL-peptidase partially purified from chick embryo showed a pH optimum at 8.0 and a K_m value of 4.0 × 10^?4m toward Suc-GPLGP-MCA. Under the optimum condition, the reaction proceeded linearly up to 4 h. The CL-peptidase activity was found in normal human sera by this method and the mean and standard deviation of the activity was 0.59 ± 0.10 nmol/min/ml of serum (n = 10). This assay was also applicable for the CL-peptidase in human liver and kidney. The results suggest that the CL-peptidase assayed by this new substrate may be different from the “PZ-peptidase” which cleaves a synthetic substrate for collagenase-like peptidase, 4-phenylazobenzyloxycarbonyl (PZ)-Pro-Leu-Gly-Pro-d-Arg (PZ-peptide). The new peptide, Suc-GPLGP-MCA, was found not to be a substrate for specific collagenase from tadpole.     

Use of fluorescence energy transfer to characterize the compactness of the constant fragment of an immunoglobulin light chain in the early stage of folding

The CL fragment of a type-kappa immunoglobulin light chain in which the C-terminal cysteine residue was modified with N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine (CL-AEDANS fragment) was prepared. This fragment has only one tryptophan residue at position 148. The compactness of the fragment whose intrachain disulfide bond was reduced in order for the tryptophan residue to fluoresce (reduced CL-AEDANS fragment) was studied in the early stages of refolding from 4 M guanidine hydrochloride by fluorescence energy transfer from Trp 148 to the AEDANS group. The AEDANS group attached to the SH group of a cysteine scarcely fluoresced when excited at 295 nm. For the reduced CL-AEDANS fragment, the fluorescence emission band of the Trp residue overlapped with the absorption band of the AEDANS group, and the fluorescence energy transfer was observed between Trp 148 and the AEDANS group in the absence of guanidine hydrochloride. In 4 M guanidine hydrochloride, the distance between the donor and the acceptor was larger, and the efficiency of the energy transfer became lower. The distance between Trp 148 and the AEDANS group for the intact protein estimated by using the energy-transfer data was in good agreement with that obtained by X-ray crystallographic analysis. By the use of fluorescence energy transfer, tryptophyl fluorescence, and circular dichroism at 218 nm, the kinetics of unfolding and refolding of the reduced fragment were studied. These three methods gave the same unfolding kinetic pattern. However, the refolding kinetics measured by fluorescence energy transfer were different from those measured by tryptophyl fluorescence and circular dichroism, the latter two giving the same kinetic pattern.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of pH, temperature, and D2O on the activity of porcine synovial collagenase and gelatinase

The pH dependence of Vmax and Vmax/Km for hydrolysis of Dnp-Pro-Leu-Gly-Leu-Trp-Ala-D-Arg-NH2 at the Gly-Leu bond by porcine synovial collagenase and gelatinase was determined in the pH range 5-10. Both enzymes exhibited bell-shaped dependencies on pH for these two kinetic parameters, indicating that activity is dependent on at least two ionizable groups, one of which must be unprotonated and the other protonated. For collagenase, Vmax/Km data indicate that in the substrate-free enzyme, these groups have apparent pK values of 7.0 and 9.5, while the Vmax profile indicates similar pK values of 6.8 and 10.1 for the enzyme-substrate complex. The corresponding pH profiles of gelatinase were similar to those of collagenase, indicating the importance of groups with apparent pK values of 5.9 and 10.0 for the free enzyme and 5.9 and 11.1 for the enzyme-substrate complex. When these kinetic constants were determined in D2O using the peptide substrate, there was no significant effect on Vmax or Km for collagenase or Km for gelatinase. However, there was a deuterium isotope effect of approximately 1.5 on Vmax for gelatinase. These results indicate that a proton transfer step is not involved in the rate-limiting step for collagenase, but may be limiting with gelatinase. The Arrhenius activation energies for peptide bond hydrolysis of the synthetic peptide as well as the natural substrates were also determined for both enzymes. The activation energy (81 kcal) for hydrolysis of collagen by collagenase was nine times greater than that determined for the synthetic substrate (9.2 kcal). In contrast, the activation energy for hydrolysis of gelatin by gelatinase (26.3 kcal) was only 2.4 times greater than that for the synthetic substrate (11 kcal).     

A convenient fluorescent assay for vertebrate collagenases

A versatile, convenient assay for vertebrate collagenases has been developed using the fluorescent peptide substrate dansyl-Pro-Gln-Gly-Ile-Ala-Gly-D-Arg. This sequence resembles that of collagen at the site of cleavage but includes modifications designed to eliminate nonspecific hydrolysis by contaminating peptidases. Both human skin fibroblast and bovine corneal cell collagenases cleave the substrate specifically at the Gly-Ile bond. Plasmin, thrombin, trypsin, alpha-chymotrypsin, carboxypeptidase B, and bacterial collagenase do not cleave the substrate. Elastase and angiotensin converting enzyme display 20- and 400-fold less activity than the vertebrate collagenases, respectively, and cleave the peptide at different positions. The assay is performed by incubating a 5- to 25-microliters aliquot of trypsin-activated sample with an equal volume of 2 mM substrate overnight at 33 degrees C and pH 7.5. Thin-layer chromatography then separates the fluorescent product from the substrate in less than 20 min and allows the detection of subnanogram levels of collagenase. The assay is applicable to the screening of large numbers of samples under different conditions of pH and ionic strength and is readily adaptable for use in a variety of collagenase-dependent systems, such as assays for collagenase activating and/or inducing factors.     

Spatial relationship between a fast-reacting thiol and a reactive lysine residue of myosin subfragment 1

Fluorescence energy transfer was used to examine the spatial proximity between two key side chains in myosin subfragment 1 (S-1), viz., the reactive thiol (SH1) located on the C-terminal 20K tryptic fragment and the reactive lysyl (RLR) on the N-terminal 27K tryptic fragment of S-1 heavy chain. S-1 was specifically labeled at SH1 with an energy donor, N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine (AEDANS), and at RLR with an energy acceptor, 2,4,6,-trinitrobenzenesulfonate (TNBS). Prior blocking of SH1 with AEDANS increased the pK of RLR from 9.04 to 9.42. Trinitrophenylation of SH1-blocked S-1 was about 50% slower and sharply reduced the Ca2+ ATPase activity. Reciprocally, blocking of RLR with TNBS slowed the rate of reaction of SH1 and AEDANS by 40-60%. Addition of the second label does not grossly alter the conformation resulting from the first label. S-1 labeled at RLR with TNBS and at SH1 with optically inert iodoacetamide shows the same TNP difference spectrum +/- MgADP (lambda min 365 nm) as S-1 with S 1 free. Also, S-1 labeled at SH1 with AEDANS and at RLR with an optically inert methyl group shows the same AEDANS emission spectrum (lambda em max 475 nm), excited-state lifetime (tau = 20.3 ns) and rotational correlation time (phi = 106 ns) as S-1 with RLR free. When the decrease of either the quantum yield or the excited-state lifetime of the donor in the absence and presence of the acceptor was measured, the energy transfer efficiency was found to be 70%. The apparent interchromophore distance was calculated to be 2.6 nm through the use of the F?rster equation with an uncertainty of less than 12%.     

Selective inhibition of fibroblast activation protein protease based on dipeptide substrate specificity

Fibroblast activation protein (FAP) is a transmembrane serine peptidase that belongs to the prolyl peptidase family. FAP has been implicated in cancer; however, its specific role remains elusive because inhibitors that distinguish FAP from other prolyl peptidases like dipeptidyl peptidase-4 (DPP-4) have not been developed. To identify peptide motifs for FAP-selective inhibitor design, we used P(2)-Pro(1) and acetyl (Ac)-P(2)-Pro(1) dipeptide substrate libraries, where P(2) was varied and substrate hydrolysis occurs between Pro(1) and a fluorescent leaving group. With the P(2)-Pro(1) library, FAP preferred Ile, Pro, or Arg at the P(2) residue; however, DPP-4 showed broad reactivity against this library, precluding selectivity. By contrast, with the Ac-P(2)-Pro(1) library, FAP cleaved only Ac-Gly-Pro, whereas DPP-4 showed little reactivity with all substrates. FAP also cleaved formyl-, benzyloxycarbonyl-, biotinyl-, and peptidyl-Gly-Pro substrates, which DPP-4 cleaved poorly, suggesting an N-acyl-Gly-Pro motif for inhibitor design. Therefore, we synthesized and tested the compound Ac-Gly-prolineboronic acid, which inhibited FAP with a K(i) of 23 +/- 3 nm. This was approximately 9- to approximately 5400-fold lower than the K(i) values for other prolyl peptidases, including DPP-4, DPP-7, DPP-8, DPP-9, prolyl oligopeptidase, and acylpeptide hydrolase. These results identify Ac-Gly-BoroPro as a FAP-selective inhibitor and suggest that N-acyl-Gly-Pro-based inhibitors will allow testing of FAP as a therapeutic target.     

Hydrolysis of dansyl-peptide substrates by leucine aminopeptidase: origin of dansyl fluorescence changes during hydrolysis

The origin of the fluorescence changes observed in stopped-flow experiments of the hydrolysis of three 5-(dimethylamino)naphthalene-1-sulfonyl-(dansyl) peptide substrates by porcine kidney cytosol leucine aminopeptidase has been investigated. The substrates used all have the potential to accept energy from aromatic residues of the enzyme via resonance energy transfer when they are bound as enzyme-substrate complexes, indicating that fluorescence changes due to the buildup and decay of such intermediates are possible. However, the fluorescence of these substrates differs from that of the products, and direct excitation of their dansyl groups during hydrolysis can also be responsible for the observed fluorescence changes due to changes in the concentrations of free substrate and product. The dansyl fluorescence changes observed with excitation wavelengths near 280 nm are not accompanied by quenching of the enzyme fluorescence, as would be expected if there were enzyme-to-substrate energy transfer. The magnitude of the maximal fluorescence change at a fixed concentration of substrate is also independent of the enzyme concentration. Furthermore, the excitation profile for the fluorescence changes shows that they arise from direct excitation of the dansyl group. Thus, there is no energy transfer in these reactions, and the fluorescence changes observed arise from direct excitation of the dansyl group and reflect the instantaneous concentration of substrate. This behavior contrasts sharply with that for the reaction of carboxypeptidase A with dansyl-Gly-Tyr, which has been studied as a positive control for an energy-transfer system.(ABSTRACT TRUNCATED AT 250 WORDS)     

A quenched fluorescent dipeptide for assaying dispase- and thermolysin-like proteases

Metalloproteases such as dispase and thermolysin play a crucial role in the life cycle of bacteria. Commonly, they prefer hydrophobic amino acids at P1' of substrate proteins, thereby cleaving the peptide bond at the alpha amino group. Activity of such proteases has been measured by the use of tailor-made oligopeptides provided with fluorescence resonance energy transfer dyes. We can now show that the short dipeptide Dabcyl-Ser-Phe-EDANS is an appropriate substrate of dispase and thermolysin. It was cleaved by both enzymes at the single peptide bond accompanied by a steep increase in fluorescence. Substantial quenching effects of the formed products were observed only when more than 80microM substrate was hydrolyzed. High affinity of the proteases for the dipeptide resulted in low K(m) values of 91+/-9 and 104+/-18microM, which are comparable to those measured for longer peptides. Dabcyl-Ser-Phe-EDANS was also used to determine the pH and optimal temperature of dispase, which were found at pH 7.0 and 50 degrees C. Buffer substances such as acetate, citrate, and tris(hydroxymethyl)aminomethane had no significant effect on enzyme activity. Measurements up to 100 degrees C revealed that hydrolysis of the quenched fluorescent dipeptide took place only in the presence of active dispase.     

Sequence specificity of human skin fibroblast collagenase. Evidence for the role of collagen structure in determining the collagenase cleavage site

The sequence specificity of human skin fibroblast collagenase has been investigated by measuring the rate of hydrolysis of 16 synthetic octapeptides covering the P4 through P4' subsites of the substrate. The choice of peptides was patterned after potential collagenase cleavage sites (those containing either the Gly-Leu-Ala or Gly-Ile-Ala sequences) found in types I, II, and III collagens. The initial rate of hydrolysis of the P1-P1' bond of each peptide has been measured by quantitating the concentration of amino groups produced upon cleavage after reaction with fluorescamine. The reactions have been carried out under first-order conditions ([S] much less than KM) and kcat/KM values have been calculated from the initial rates. The amino acids in subsites P3 (Pro, Ala, Leu, or Asn), P2 (Gln, Leu, Hyp, Arg, Asp, or Val), P1' (Ile or Leu), and P4' (Gln, Thr, His, Ala, or Pro) all influence the hydrolysis rates. However, the differences in the relative rates observed for these octapeptides cannot in themselves explain why fibroblast collagenase hydrolyzes only the Gly-Leu and Gly-Ile bonds found at the cleavage site of native collagens. This supports the notion that the local structure of collagen is important in determining the location of the mammalian collagenase cleavage site.     

HIV-1 protease: characterization of a catalytically competent enzyme-substrate intermediate.

The steady-state and pre-steady-state kinetic parameters for the interaction of E with the fluorogenic substrate 2-aminobenzoyl-Thr-Ile-Nle-Phe(p-NO(2))-Gln-Arg-NH(2) were determined in 1.25 M NaCl, 0.1 M MES-TRIS at pH 6.0 at 25 degrees C. At low concentrations of enzyme, the values of the K(m) and k(cat) calculated from steady-state data were 2.1 microM and 7.4 s(-1), respectively. At high concentrations of enzyme, the time-courses of fluorescence enhancement associated with catalysis were very dependent on the excitation wavelength used to monitor the reaction. Because the absorbance spectrum of the substrate overlapped the fluorescence emission spectrum of the enzyme, these abnormalities were attributed to fluorescence energy transfer between the enzyme and the substrate in an enzyme-substrate intermediate. The kinetic data collected with lambda(ex) = 280 nm and lambda(em) > 435 nm were analyzed according to the following mechanism in which EX was the species with enhanced fluorescence relative to substrate or products: [formula see text]. The values of the kinetic parameters with (1)H(2)O as the solvent were K = 13 microM, k(2) = 150 s(-1), k(-2) = 25 s(-1), and k(3) = 11 s(-1). The values of the kinetic parameters with (2)H(2)O as the solvent were K = 13 microM, k(2) = 210 s(-1), k(-2) = 12 s(-1), and k(3) = 4.4 s(-1). These values yielded solvent isotope effects of 2 on k(cat) and 0.9 on k(cat)/K(m). From analysis of the complete time-course of the fluorescence change (lambda(ex) = 280 nm and lambda(em) > 435 nm) during the course of substrate hydrolysis, the intermediate EX was determined to be 6.3-fold more fluorescent than the product, which, in turn, was 4.5-fold more fluorescent than ES or S. Rapid quench experiments with 2 N HCl as the quenching reagent confirmed that EX was a complex between enzyme and substrate. Consequently, the small burst in fluorescence observed when monitoring with lambda(ex) = 340 nm (0.3 product equiv per enzyme equivalent) was attributed to the fluorescence change upon transfer of substrate from an aqueous environment to a nonaqueous environment in the enzyme. These results were consistent with carbon-nitrogen bond cleavage being the major contributor to k(cat).     

Real-time detection of basal and stimulated G protein GTPase activity using fluorescent GTP analogues

Hydrolysis of fluorescent GTP analogues BODIPY FL guanosine 5 '-O-(thiotriphosphate) (BGTPgammaS) and BODIPY FL GTP (BGTP) by Galpha(i1) and Galpha was characterized using on-line capillary electrophoresis (o) laser-induced fluorescence assays in order that changes in sub-strate, substrate-enzyme complex, and product could be monitored separately. Apparent k values (V /[E]) (max cat) steady-state and K(m) values were determined from assays for each substrate-protein pair. When BGTP was the substrate, maximum turnover numbers for Galpha and Galpha(i1) were 8.3 +/- 1 x 10(-3) and 3.0 +/- 0.2 x 10(-2) s(-1), respectively, and K(m) values were 120 +/- 60 and 940 +/- 160 nm. Assays with BGTPgammaS yielded maximum turnover numbers of 1.6 +/- 0.1 x 10(-4) and 5.5 +/- 0.3 x 10(-4) s(-1) for Galpha and Galpha(i1); K(m) values were 14 (o)(+/-)8 and 87 +/- 22 nm. Acceleration of Galpha GTPase activity by regulators of G protein signaling (RGS) was demonstrated in both steady-state and pseudo-single-turnover assay formats with BGTP. Nanomolar RGS increased the rate of enzyme product formation (BODIPY(R) FL GDP (BGDP)) by 117-213% under steady-state conditions and accelerated the rate of G protein-BGTP complex decay by 199 -778% in pseudo-single-turnover assays. Stimulation of GTPase activity by RGS proteins was inhibited 38-81% by 40 mum YJ34, a previously reported peptide RGS inhibitor. Taken together, these results illustrate that Galpha subunits utilize BGTP as a substrate similarly to GTP, making BGTP a useful fluorescent indicator of G protein activity. The unexpected levels of BGTPgammaS hydrolysis detected suggest that caution should be used when interpreting data from fluorescence assays with this probe.     

A direct fluorometric assay for tissue transglutaminase

Herein we report the design of a direct and continuous fluorometric assay for determining tissue transglutaminase (TGase) activity. The progress of the TGase-catalyzed reaction of 4-(N-carbobenzoxy-l-phenylalanylamino)-butyric acid coumarin-7-yl ester was monitored as an increase of fluorescence (lambda(exc) 330 nm, lambda(em) 460 nm) due to the release of 7-hydroxycoumarin. Using this assay, we determined the K(m) of two acceptor substrates, N-acetyl-L-lysine methyl ester and aminoacetonitrile. We also determined the K(m) of 4-(N-carbobenzoxy-L-phenylalanylamino)-butyric acid coumarin-7-yl ester for its TGase-mediated hydrolysis and for its enzymatic reaction with the acyl acceptor substrates N-acetyl-L-lysine methyl ester and aminoacetonitrile. We ascertained that the fluorescent substrate was selective toward tissue TGase by testing it with different enzymes, namely microbial transglutaminase (mTGase), Factor XIIIa, papain, and gamma-glutamyl transpeptidase. 4-(N-carbobenzoxyglycinylamino)-butyric acid coumarin-7-yl ester, lacking the benzyl side chain, was also found to be an efficient fluorogenic substrate of tissue TGase. Finally, we have shown that this method is applicable to 96-well microtiter plate format.     

The interdomain motions in myosin subfragment 1.

The interdomain motions in myosin subfragment 1 (S1) were studied by steady-state and time-resolved fluorescence of tryptophan residues and N-(iodoacetyl)-N'-(5-sulfo-1-naphtyl)ethylenediamine (AEDANS) attached to Cys178 of alkali light chain 1 (A1) exchanged into S1. The efficiency of fluorescence resonance energy transfer (FRET) from tryptophan residues of motor domain to AEDANS at A1 decreased dramatically after addition of ATP to S1A1-AEDANS. The efficiency of FRET calculated from the crystal structure of chicken S1 corresponded to the experimental one measured in the presence of ATP. The results showed that AEDANS at Cys178 of A1 became more mobile and distant from the motor domain of S1 upon ATP binding. These findings led to the suggestion that a release of the products of ATP hydrolysis and power stroke might be associated with movement of light chain-binding domain towards the N-terminal domain of S1.     

Effects of ATP and protons on the Na : K selectivity of the (Na+ + K+)-ATPase studied by ligand effects on intrinsic and extrinsic fluorescence

The effect of pH and of ATP on the Na : K selectivity of the (Na+ + K+)-ATPase has been tested under equilibrium conditions. The Na+ : K+-induced change in intrinsic tryptophan fluorescence and in fluorescence of eosin maleimide bound to the system has been used as a tool. 1 mol of eosin maleimide per mol of enzyme gives no loss in either ATPase or phosphatase activity and the fluorescence in the presence of Na+ is about 30% higher than in the presence of K+. Choline, protonated Tris, protonated histidine and Mg2+ have an 'Na+' effect on the extrinsic fluorescence, while Rb+, Cs+ and NH4+ have a 'K+' effect. Choline and protonated Tris have an Na+ effect on intrinsic fluorescence. A close correlation between the effect of Na+ compared to K+ on the fluorescence change and on Na+ activation of hydrolysis indicates that the observed changes in fluorescence are due to an effect of Na+ and of K+ on the internal sites of the system. The equilibrium between the two conformations, which are reflected by the difference in fluorescence with Na+ and K+, respectively, is highly influenced by the concentration of protons. At a given Na+ : K+ ratio, an increase in the proton concentration shifts the equilibrium towards the 'K+' fluorescence form while a decrease shifts the equilibrium towards the 'Na+' fluorescence form, i.e., protons increase the apparent affinity for K+ and vice versa, K+ increases pK values of importance for the Na+ : K+ selectivity. Conversely, a decrease in protons increases the apparent affinity for Na+ and vice versa, Na+ decreases the pK. ATP decreases the apparent pK for the protonation-deprotonation, i.e., ATP facilitates the deprotonation which accompanies Na+ binding. The results suggest two effects of ATP for the hydrolysis in the presence of Na+ and K+ : (i) at low ATP concentrations (K0.5 < 10 microM) on the K+-Na+ exchange on the internal sites and (ii) at higher, substrate, concentrations on the activation by K+ on the external sites.     

Interactions of troponin I and its inhibitory fragment (residues 104-115) with troponin C and calmodulin

Fluorescent probes have been used to study the interaction of troponin I and its inhibitory peptide TnIp with troponin C, calmodulin, and the proteolytic fragments of calmodulin. The probes used included the noncovalently bound ligand TNS and the covalently attached labels dansyl and AEDANS. The fluorescence intensity of TNS bound to troponin C, calmodulin, or the calmodulin fragments was greatly enhanced by the presence of TnIp. This effect was used to estimate the corresponding binding constants. It was found that TnIp is bound by the C-terminal half-molecule of calmodulin, TR2C, with an affinity comparable to that of intact calmodulin or troponin C, while the binding affinity of the N-terminal half-molecule, TR1C, was an order of magnitude less, suggesting that the TnIp-containing portion of troponin I combines with the C-terminal half of calmodulin or troponin C. The fluorescence properties of an AEDANS group linked to Cys-98 of troponin C were modified by interaction with troponin I or TnIp. The fluorescence properties of the same group linked to Cys-27 of wheat germ calmodulin were affected by TnI, but not TnIp. TnI had a small effect upon the fluorescence of a dansyl group linked to Met-25 of troponin C. TnIp also inhibited the tryptic hydrolysis of the midpoint of the central connecting strand of calmodulin and troponin C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hepatitis A virus 3C proteinase substrate specificity.

Hepatitis A virus (HAV) 3C proteinase is responsible for processing the viral precursor polyprotein into mature proteins. The substrate specificity of recombinant hepatitis A 3C proteinase was investigated using a series of synthetic peptides representing putative polyprotein junction sequences. Two peptides, corresponding to the viral polyprotein 2B/2C and 2C/3A junctions, were determined to be cleaved most efficiently by the viral 3C proteinase. The kcat/Km values determined for the hydrolysis of a further series of 2B/2C peptides, in which C-terminal and N-terminal amino acids were systematically removed, revealed that P4 through P2' amino acids were necessary for efficient substrate cleavage. The substitution of Ala for amino acids in P1 and P4 positions decreased the rate of peptide hydrolysis by 100- and 10-fold, respectively, indicating that the side chains of Gln in P1 and Leu in P4 are important determinants of substrate specificity. Rates of hydrolysis measured for other P1- and P4-substituted peptides indicate that S1 is very specific for the Gln side chain whereas S4 requires only that the amino acid in P4 be hydrophobic. A continuous fluorescence quench assay was developed, allowing the determination of kcat/Km dependence on pH. The pH rate profile suggests that catalyzed peptide hydrolysis is dependent on deprotonation of a reactive group having a pKa of 6.2 (+/- 0.2). The results of tests with several proteinase inhibitors indicate that this cysteine proteinase, like other picornaviral 3C proteinases, is not a member of the papain family.     

Kinetic analysis of matrix metalloproteinase activity using fluorogenic triple-helical substrates

Matrix metalloproteinase (MMP) family members are involved in the physiological remodeling of tissues and embryonic development as well as pathological destruction of extracellular matrix components. To study the mechanisms of MMP action on collagenous substrates, we have constructed homotrimeric, fluorogenic triple-helical peptide (THP) models of the MMP-1 cleavage site in type II collagen. The substrates were designed to incorporate the fluorophore/quencher pair of (7-methoxycoumarin-4-yl)acetyl (Mca) and N-2,4-dinitrophenyl (Dnp) in the P(5) and P(5)' positions, respectively. In addition, Arg was incorporated in the P(2)' and P(8)' positions to enhance enzyme activity and improve substrate solubility. The desired sequences were Gly-Pro-Lys(Mca)-Gly-Pro-Gln-Gly approximately Leu-Arg-Gly-Gln-Lys(Dnp)-Gly-Ile/Val-Arg. Two fluorogenic substrates were prepared, one using a covalent branching protocol (fTHP-1) and one using a peptide self-assembly approach (fTHP-3). An analogous single-stranded substrate (fSSP-3) was also synthesized. Both THPs were hydrolyzed by MMP-1 at the Gly approximately Leu bond, analogous to the bond cleaved in the native collagen. The individual kinetic parameters for MMP-1 hydrolysis of fTHP-3 were k(cat) = 0.080 s(-1) and K(M) = 61.2 microM. Subsequent investigations showed fTHP-3 hydrolysis by MMP-2, MMP-3, MMP-13, a C-terminal domain-deleted MMP-1 [MMP-1(Delta(243-450))], and a C-terminal domain-deleted MMP-3 [MMP-3(Delta(248-460))]. The order of k(cat)/K(M) values was MMP-13 > MMP-1 approximately MMP-1(Delta(243-450)) approximately MMP-2 > MMP-3 approximately MMP-3(Delta(248-460)). Studies on the effect of temperature on fTHP-3 and fSSP-3 hydrolysis by MMP-1 showed that the activation energies between these two substrates differed by 3.4-fold, similar to the difference in activation energies for MMP-1 hydrolysis of type I collagen and gelatin. This indicates that fluorogenic triple-helical substrates mimic the behavior of the native collagen substrate and may be useful for the investigation of collagenase triple-helical activity.