Fluorescence studies on the active sites of proteinases

Statistical coupling analysis of aspartic proteinases based on crystal structures of the Trichoderma reesei enzyme and its complex with pepstatin A

The crystal structures of an aspartic proteinase from Trichoderma reesei (TrAsP) and of its complex with a competitive inhibitor, pepstatin A, were solved and refined to crystallographic R-factors of 17.9% (R(free)=21.2%) at 1.70 A resolution and 15.8% (R(free)=19.2%) at 1.85 A resolution, respectively. The three-dimensional structure of TrAsP is similar to structures of other members of the pepsin-like family of aspartic proteinases. Each molecule is folded in a predominantly beta-sheet bilobal structure with the N-terminal and C-terminal domains of about the same size. Structural comparison of the native structure and the TrAsP-pepstatin complex reveals that the enzyme undergoes an induced-fit, rigid-body movement upon inhibitor binding, with the N-terminal and C-terminal lobes tightly enclosing the inhibitor. Upon recognition and binding of pepstatin A, amino acid residues of the enzyme active site form a number of short hydrogen bonds to the inhibitor that may play an important role in the mechanism of catalysis and inhibition. The structures of TrAsP were used as a template for performing statistical coupling analysis of the aspartic protease family. This approach permitted, for the first time, the identification of a network of structurally linked residues putatively mediating conformational changes relevant to the function of this family of enzymes. Statistical coupling analysis reveals coevolved continuous clusters of amino acid residues that extend from the active site into the hydrophobic cores of each of the two domains and include amino acid residues from the flap regions, highlighting the importance of these parts of the protein for its enzymatic activity.

Surface-enhanced Raman and steady fluorescence study of interaction between antitumoral drug 9-aminoacridine and trypsin-like protease related to metastasis processes, guanidinobenzoatase

Fluorescence spectroscopy and surface-enhanced Raman spectroscopy (SERS) were applied to study the interaction of the antitumoral drug 9-aminoacridine (9AA) with a trypsin-like protease guanidinobenzoatase (GB) extracted from a mouse Erlich tumor. As a consequence of this interaction, a strong 9AA exciplex emission was detected in the emission fluorescence spectra at certain drug and enzyme concentrations. A SERS study was accomplished on silver colloids at several excitation wavelengths in order to obtain more information about the interaction mechanism. The results derived from Raman spectroscopy indicated that 9AA in the amino monomeric form may interact with the enzyme by means of two different bonds: an ionic bond with a negatively charged amino acid and a ring stacking interaction with an aromatic residue placed in the catalytic site of GB. This interaction mechanism was responsible for a strong exciplex emission detected at a longer wavelength than the expected value of the normal fluorescence emission. Moreover, the GB concentration dependence of the interaction suggested that the drug was sensitive to the quaternary structure of the enzyme.

Transpeptidation by porcine pepsin catalyzed by a noncovalent intermediate unique to its iso-mechanism

Porcine pepsin proteolysis of the hexapeptide Leu-Ser-p-nitro-Phe-Nle-Ala-Leu-OMe (where OMe = methoxy and Nle = norleucine) in the presence of dipeptide Leu-Leu synthesizes a new hexapeptide Leu-Ser-p-nitro-Phe-Leu-Leu. Contrary to transpeptidation kinetics of other proteases, which depend upon an acyl-enzyme intermediate, the time course for pepsin-catalyzed transpeptidation displays a distinct lag before reaching a steady-state reaction velocity. Moreover, this lag is coupled to burst kinetics for the formation of proteolytic products, Leu-Ser-p-nitro-Phe and Nle-Ala-Leu-OMe. The lag requires that free Leu-Ser-p-nitro-Phe accumulate in the reaction medium during the lag phase and subsequently rebind for transpeptidation. Consistent with this dissociative kinetic mechanism are normal solvent isotope effects on formation of the proteolytic products Leu-Ser-p-nitro-Phe (vH/vD = 2.2 +/- 0.2) and Nle-Ala-Leu-OMe (vH/vD = 1.8 +/- 0.1) as opposed to an inverse effect on the formation of the transpeptidation product Leu-Ser-p-nitro-Phe-Leu-Leu (vH/vD = 0.40 +/- 0.09). Because proteolysis is slower in D2O but transpeptidation is faster, the isotopically sensitive step must occur after release of both products of proteolysis, which precludes putative acyl-enzyme covalent intermediates. Isotopically enhanced transpeptidation is a new type of isotope effect but one that is consistent with the Uni Bi iso-mechanism previously postulated on the basis of solvent isotope effects on Vmax but not on Vmax/Km (Rebholz, K. L., and Northrop, D. B. (1991) Biochem. Biophys Res. Commun. 179, 65-69) and confirmed by solvent isotope effects on the onset of inhibition by pepstatin (Cho, Y.-K., Rebholz, K. L., and Northrop, D. B. (1994) Biochemistry 33, 9637-9642). As a new biochemical mechanism for peptide bond synthesis that has a potential for applications in biotechnology, it is here proposed that the energy necessary to drive peptide synthesis from free peptides comes from the sizable free energy drop associated with rehydration of the active site of pepsin in 55 M water.

The pH dependence of the hydrolysis of chromogenic substrates of the type, Lys-Pro-Xaa-Yaa-Phe-(NO2)Phe-Arg-Leu, by selected aspartic proteinases: evidence for specific interactions in subsites S3 and S2

Variation in the kinetic parameters, kcat and Km, with pH has been used to obtain evidence for significant acid-dissociation processes in the hydrolysis of octapeptide substrates by three aspartic proteinases. These substrates are all cleaved at the peptide bond between a Phe (P1) and a p-nitroPhe (P1') residue resulting in a shift in absorbance at 300 nm that facilitates kinetic measurements. The substrates differ in the amino-acid residues present in the P3 and the P2 positions. Porcine pepsin, calf chymosin, and the aspartic proteinase from Endothia parasitica all show pH dependencies that imply that favorable or unfavorable interactions can occur with the S3 or S2 areas of the enzyme-active site. Examination of the crystallographically determined structure of the E. parasitica proteinase and consideration of the amino-acid sequence differences between the three enzymes suggests that the origin of the pH effects arises from favorable interactions between Glu-13 (COO-) of pig pepsin and Thr (OH) or His (ImH+) in P3 of a substrate. Similarly, Lys-220 (NH3+) of chymosin and a Glu (COO-) in P2 of a substrate may produce a favorable interaction and Asp-77 (COO-) of E. parasitica proteinase and a Glu (COO-) in P2 of a substrate may produce an unfavorable interaction. These results lead to possible explanations for subtle specificity differences within a family of homologous enzymes, and suggest loci for study by site-directed mutagenesis.

Patterns of extracellular proline-specific endopeptidases in Legionella and Flavobacterium spp. demonstrated by use of chromogenic peptides

Some Legionella strains possess a strong extracellular proline-specific endopeptidase (PSE) activity. Using an enlarged selection of chromogenic peptides representing a variety of N-terminal amino-acids binding to a -prolyl-proline, paranitroanilide chain, PSE activity of Legionella and Flavobacterium strains was examined. Differences in PSE activity emphasized the importance of the chemical structure at the nonchromogenic end of the peptide substrates. There seem to be distinct patterns of N-terminal specificity of PSE in the two bacterial groups.

A new substrate for porcine pepsin possessing cryptic fluorescence properties

A fluorescent substrate for porcine pepsin, 50-dimethylaminonaphthalene-1-sulfonyl (Dns)-Ala-Ala-Phe-Phe-3-[4-(N-CH3)-pyridyl]propyl-1-oxy ester has been synthesized. It is stable, soluble from pH 1 to 7, and is readily hydrolyzed by pepsin with values of 288 (+/- 40) s-1 for kcat, 0.039 mM (+/- 0.005) for Km, and 7510 s-1 mM-1 (+/- 500) for kcat/Km in sodium formate, pH 3.1. Kinetic studies were carried out by following the increased fluorescence (300-nm excitation, 525-nm emission) as hydrolysis occurred. The products of hydrolysis were identified and established that the peptide bond between the phenylalanine residues is cleaved by pepsin. The inhibition of pepsin catalysis by pepsinogen (1-12) activation peptide was studied in order to compare the inhibition of the reaction of pepsin with Dns-Ala-Ala-Phe-Phe-OP4P-CH3+ with that obtained by the standard milk-clotting assay. The inhibition results were comparable. Dns-Ala-Ala-Phe-Phe-OP4P-CH3+ should be a valuable tool for studies of pepsin because of its solubility over an extended pH range, its excellent turnover rate, and the ease with which the hydrolysis can be followed.

Conformational flexibility in the active sites of aspartyl proteinases revealed by a pepstatin fragment binding to penicillopepsin

Crystals of the molecular complex between the esterified tripeptide fragment of pepstatin and the aspartyl proteinase penicillopepsin are isomorphous with crystals of native penicillopepsin. The difference electron-density map at 1.8-A resolution, computed by using the amplitude differences and refined phases of reflections from the crystal of native penicillopepsin, unambiguously showed the binding mode of isovaleryl-Val-Val-StaOEt, where StaOEt is the ethyl ester of statine [(4S,3S)-4-amino-3-hydroxyl-6-methylheptanoic acid]. In addition, a major conformational change in penicillopepsin involving the large beta loop of residues from Trp-71 to Gly-83 (the so-called "flap" region) occurs as a result of this inhibitor binding. This structural movement provides the first confirmation of the importance of enzyme flexibility in the aspartyl proteinase mechanism. The 3-hydroxyl group of the Statine residue and the carbonyl oxygen atom of the ethyl ester are situated on either side of the approximate plane containing the hydrogen-bonded carboxyl groups of Asp-33 and Asp-213. The observed binding mode of the pepstatin tripeptide fragment is similar to that predicted for the binding of good substrates with penicillopepsin [James, M. N. G. (1980) Can. J. Biochem. 58, 251-271].

Demonstration of extracellular proteolytic enzymes from Legionella species strains by using synthetic chromogenic peptide substrates

Crude concentrates of extracellular proteases from strains belonging to species within the genus Legionella were examined for their effect upon synthetic chromogenic tri- and tetrapeptides. For the species L. pneumophila, similar and reproducible substrate degradation patterns were found. Strains from the other Legionella species produced proteases with dissimilar proteolytic patterns, which were all distinct from those of the L. pneumophila proteases.

Bimane-labelled pepstatin, a fluorescent probe for the subcellular location of cathepsin D

1. Pepstatinyl-cystamine was synthesized. The disulphide bond was cleaved and the pepstatin-bound thiol was made to react with monobromobimane. The fluorescent N-pepstatinyl-S-bimanyl-2-aminoethanethiol was purified. 2. Human cathepsin D showed tight binding of the bimane-labelled pepstatin at pH 3.5. The titration curves were used to determine the apparent dissociation constant, KD; values of approx. 1 x 10(-10) M were obtained. 3. Gel-chromatographic experiments showed that, like that of pepstatin, the binding of N-pepstatinyl-S-bimanyl-1-aminoethanethiol to cathepsin D was strongly pH-dependent. Binding was seen at pH 5.0, but could not be demonstrated at pH 7.4. 4. Cultured human synovial cells were fixed and incubated with the fluorescent inhibitor at pH 5.0 or pH 7.4. When examined by fluorescence microscopy the cells stained at pH 5.0 showed a punctate perinuclear distribution of bimane fluorescence. By contrast, the cells stained at pH 7.4 showed no fluorescence. 5. The distribution of cathepsin D, determined by indirect immunofluorescence at pH 7.4, closely resembled that of the fluorescent inhibitor seen at pH 5.0. 6. We conclude that N-pepstatinyl-S-bimanyl-2-aminoethanethiol is a fluorescent probe selective for the active conformation of cathepsin D.