Fluorescent probes as a measure of conformational alterations induced by nucleophilic modification and proteolysis of bovine alpha 2-macroglobulin

Conformational alterations occurring in bovine alpha 2-macroglobulin (alpha 2M) resulting from proteolysis and nucleophilic modification have been monitored by UV difference spectra, circular dichroism, and changes in the fluorescence of 6-(p-toluidino)-2-naphthalenesulfonate (TNS) and bis(8-anilino-1-naphthalenesulfonate) (Bis-ANS). The results of this study indicate that these two dyes appear capable of differentiating between conformational changes induced by proteolysis and those induced by methylamine treatment. It appears that TNS is a sensitive probe for monitoring protease-induced but not methylamine-induced conformational changes in bovine alpha 2M. Bis-ANS, on the other hand, appears suitable for monitoring conformational changes induced by methylamine treatment or proteolysis of the molecule and was used as a probe to monitor the kinetics of the conformational change induced by methylamine treatment. It was found that the conformational change did not occur simultaneously with cleavage of the thiol ester bonds by the nucleophile, measured by titration of free sulfhydryl groups with 5,5'-dithiobis(2-nitrobenzoate). The data are consistent with a model in which initial nucleophilic attack results in exposure of sulfhydryl groups, resulting in a conformational change measured by an increase in fluorescence. This event is followed by a unimolecular step representing a conformational change in the protein that results in a further increase in the fluorescence signal. The second-order rate constant for hydrolysis of the thiol ester bonds was determined to be 3.4 +/- 1.0 M-1 s-1, while the rate constant for the conformational change was (4.4 +/- 0.8) X 10(-4) s-1.     

Reaction of proteinases with alpha 2-macroglobulin: evidence for alternate reaction pathways in the inhibition of trypsin

Titration experiments were employed to measure the binding stoichiometry of alpha 2M for trypsin at high and low concentrations of reactants. These titration experiments were performed by measuring the SBTI-resistant trypsin activity and by direct binding measurements using 125I-labeled trypsin. The binding stoichiometry displayed a marked dependence upon protein concentration. At high alpha 2M concentrations (micromolar), 2 mol of trypsin are bound/mol of inhibitor. However, at low alpha 2M concentrations (e.g., 0.5 nM), only 1.3 mol of trypsin were bound/mol of inhibitor. Sequential additions of subsaturating amounts of trypsin to a single aliquot of alpha 2M also resulted in a reduction in the final binding ratio. A model has been formulated to account for these observations. A key element of this model is the observation that purified 1:1 alpha 2M-proteinase complexes are not capable of binding a full mole of additional proteinase [Strickland et al. (1988) Biochemistry 27, 1458-1466]. The model predicts that once the 1:1 alpha 2M-proteinase complex forms, this species undergoes a time-dependent conformational rearrangement to yield a complex with greatly reduced proteinase binding ability. According to this model, the ability of alpha 2M to bind 2 mol of proteinase depends upon the association rate of the second enzyme molecule with the binary (1:1) complex, the enzyme concentration, and the rate of the conformational alteration that occurs once the initial complex forms. Modeling experiments suggest that the magnitude of the rate constant for this conformational change is in the order of 1-2 s-1.     

Reaction of methylamine with human alpha 2-macroglobulin. Mechanism of inactivation

The human protease inhibitor alpha 2-macroglobulin (alpha 2 M) is inactivated by reaction with methylamine. The site of reaction is a protein functional group having the properties of a thiol ester. To ascertain the relationship between thiol ester cleavage and protein inactivation, the rates of methylamine incorporation and thiol release were measured. As expected for a concerted reaction of a nucleophile with a thiol ester, the rates were identical. Furthermore, both rates were first order with respect to methylamine and second order overall. The methylamine inactivation of alpha 2M was determined by measuring the loss of total protease-binding capacity. This rate was slower than the thiol ester cleavage and had a substantial initial lag. However, the inactivation followed the same time course as a conformational change in alpha 2M that was measured by fluorescent dye binding, ultraviolet difference spectroscopy, and limited proteolysis. Thus, the methylamine inactivation of alpha 2M is a sequential two-step process where thiol ester cleavage is followed by a protein conformational change. It is the latter that results in the loss of total protease-binding capacity. A second assay was used to monitor the effect of methylamine on alpha 2M. The assay measures the fraction of alpha 2M-bound protease (less than 50%) that is resistant to inactivation by 100 microM soybean trypsin inhibitor. In contrast to the total protease-binding capacity, this subclass disappeared with a rate coincident with methylamine cleavage of the thiol ester. alpha 2M-bound protease that is resistant to a high soybean trypsin inhibitor concentration may reflect the fraction of the protease randomly cross-linked to alpha 2M. Both the thiol ester cleavage and the protein conformational change rates were dependent on methylamine concentration. However, the thiol ester cleavage depended on methylamine acting as a nucleophile, while the conformational change was accelerated by the ionic strength of methylamine. Other salts and buffers that do not cleave the thiol ester increased the rate of the conformational change. A detailed kinetic analysis and model of the methylamine reaction with alpha 2M is presented. The methylamine reaction was exploited to study the mechanism of protease binding by alpha 2M. At low ionic strength, the protein conformational change was considerably slower than thiol ester cleavage by methylamine. Thus, at some time points, a substantial fraction of the alpha 2M had all four thiol esters cleaved, yet had not undergone the conformational change. This fraction (approximately 50%) retained full protease-binding capacity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thrombin-induced conformational changes of human alpha 2-macroglobulin: evidence for two functional domains

The interaction of thrombin with alpha 2-macroglobulin (alpha 2M) was characterized by monitoring conformational changes and measuring the increase of free sulfhydryl groups during the reaction. Under experimental conditions where [thrombin] greater than [alpha 2M], the conformational change, measured by increases in the fluorescence of 6-(p-toluidino)-2-naphthalenesulfonate, and thiol group appearance displayed biphasic kinetics. The initial rapid phase results in the formation of a stable complex, the appearance of two sulfhydryl groups, the cleavage of approximately half of the Mr 180 000 subunits, and a conformational change that is not as extensive as that which occurs with trypsin. The slower phase is associated with the appearance of two additional sulfhydryl groups, increased cleavage of the Mr 180 000 subunit, and additional conformational changes. The available evidence suggests that the slow phase results from hydrolysis of the Mr 180 000 subunit(s) due to proteolysis of the alpha 2M-thrombin complex by free thrombin. Experiments with 125I-thrombin document the binding of 1 mol of thrombin/mol of alpha 2M that is not dissociated upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the complex. At higher ratios of thrombin to alpha 2M, a second mole of thrombin will reversibly associate with the 1:1 alpha 2M-thrombin complex. Under conditions where [thrombin] less than [alpha 2M], biphasic kinetics were not observed, and the conformational change, sulfhydryl appearance, and hydrolysis of the Mr 180 000 subunit were found to follow second-order kinetics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetic evidence for a two-step mechanism for the binding of chymotrypsin to alpha 1-proteinase inhibitor.

We have used the proflavin displacement method and a stopped-flow apparatus to measure the rate constant for the binding of 2 microM-chymotrypsin to 20-125 microM-alpha 1-proteinase inhibitor. The observed pseudo-first-order constant showed a hyperbolic dependence on alpha 1-proteinase inhibitor concentration, suggesting a reaction mechanism in which a fast pre-equilibrium (K = 0.19 mM) is followed by a first-order formation of the final complex (k = 252 s-1).     

Kinetics of appearance of sulfhydryl groups in alpha 2-macroglobulin on reaction of the inhibitor with amines

The mechanism of the appearance of sulfhydryl groups in alpha 2-macroglobulin in the reaction with amines was characterized by analyses of the kinetics with ammonia and methylamine. All reactions occurred under pseudo-first-order conditions in the range of pH (7.0-8.6) and amine concentration (10-600 mM) investigated. The logarithm of the pseudo-first-order rate constant increased linearly as a function of pH with a slope of unity, indicating that the unprotonated amine is the active species in the reaction. Plots of the observed pseudo-first-order rate constants vs. concentration of unprotonated amine at constant pH were also linear and gave second-order-rate constants of 0.32 and 13.8 M-1 s-1 for ammonia and methylamine, respectively, at pH 8.0; similar values were obtained at pH 8.6. Activation energies of 85 and 100 kJ mol-1 and activation entropies of 10 and 95 J K-1 mol-1 for ammonia and methylamine, respectively, were estimated from Arrhenius plots, suggesting that the higher reaction rate for methylamine is due primarily to a higher activation entropy. These results are consistent with the release of sulfhydryl groups being caused by a nucleophilic attack of the uncharged amine on a thio ester bond of alpha 2-macroglobulin in a bimolecular reaction occurring under pseudo-first-order conditions. The characteristics of the reaction suggest that the thio ester in each alpha 2-macroglobulin subunit reacts independently and equivalently with the amine and also that the thio ester bond cleavage initiates the reaction sequence leading to inactivation of the inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium release from intact calmodulin and calmodulin fragment 78-148 measured by stopped-flow fluorescence with 2-p-toluidinylnaphthalene sulfonate. Effect of calmodulin fragments on cardiac sarcoplasmic reticulum

Calcium release from high and low-affinity calcium-binding sites of intact bovine brain calmodulin (CaM) and from the tryptic fragment 78-148, purified by high-pressure liquid chromatography, containing only the high-affinity calcium-binding sites, was determined by fluorescence stopped-flow with 2-p-toluidinylnaphthalene sulfonate (TNS). The tryptic fragments 1-77 and 78-148 each contain a calcium-dependent TNS-binding site, as shown by the calcium-dependent increase in TNS fluorescence. The rate of the monophasic fluorescence decrease in endogenous tyrosine on calcium dissociation from intact calcium-saturated calmodulin (kobs 10.8 s-1 and 3.2 s-1 at 25 degrees C and 10 degrees C respectively) as well as the rate of equivalent slow phase of the biphasic decrease in TNS fluorescence (kobsslow 10.6 s-1 and 3.0 s-1 at 25 degrees C and 10 degrees C respectively) and the rate of the solely monophasic decrease in TNS fluorescence, obtained with fragment 78-148 (kobs 10.7 s-1 and 3.5 s-1 at 25 degrees C and 10 degrees C respectively), were identical, indicating that the rate of the conformational change associated with calcium release from the high-affinity calcium-binding sites on the C-terminal half of calmodulin is not influenced by the N-terminal half of the molecule. The fast phase of the biphasic decrease of TNS fluorescence, observed by the N-terminal half of the molecule. The fast phase of the biphasic decrease of TNS fluorescence, observed with intact calmodulin only (kobsfast 280 s-1 at 10 degrees C) but not with fragment 78-148, is most probably due to the conformational change associated with calcium release from low-affinity sites on the N-terminal half. The calmodulin fragments 1-77 and 78-148 neither activated calcium/calmodulin-dependent protein kinase of cardiac sarcoplasmic reticulum nor inhibited calmodulin-dependent activation at a concentration approximately 1000-fold greater (5 microM) than that of the calmodulin required for half-maximum activation (5.9 nM at 0.8 mM Ca2+ and 5 mM Mg2+) of calmodulin-dependent phosphoester formation.     

Kinetics of the reaction of streptokinase-plasmin complex with purified human and mouse alpha 2-macroglobulin. Implications for mechanism.

Streptokinase-human plasmin complex (Sk-hPm) reacted rapidly with purified mouse alpha 2-macroglobulin (m alpha 2M) in vitro at 37 degrees C. Approx. 98% of the plasmin in Sk-hPm bound covalently to at least one m alpha 2M subunit. Most of the streptokinase dissociated (95%). The rate of Sk-hPm inactivation clearly depended on the m alpha 2M concentration. With 1.2 microM-m alpha 2M, 50% of the Sk-hPm (0.02 microM) reacted in less than 50 s. A double-reciprocal plot comparing pseudo-first-order rate constants (kapp.) and m alpha 2M concentration yielded a second-order rate constant of 2.3 x 10(4) M-1.s-1 (r = 0.97). This value is an approximation, since Sk-hPm preparations are heterogeneous. Sk-hPm reacted with human alpha 2M (h alpha 2M), forming alpha 2M-plasmin complex (98% covalent). More than 99% of the streptokinase dissociated. The rate of reaction of Sk-hPm with h alpha 2M did not clearly depend on inhibitor concentration. The kapp. values determined with 0.6-1.2 microM-h alpha 2M were decreased 10-20-fold compared with m alpha 2M. In order to study the effect of Sk-hPm heterogeneity on the reaction with alpha 2M, the proteinase was incubated for various amounts of time at 37 degrees C before addition of inhibitor. The enzyme amidase activity was maximal within 5 min; however, reaction of Sk-hPm with m alpha 2M or h alpha 2M was most extensive after 20 min and 2 h respectively. After incubation for more than 1 h, Sk-hPm acquired fibrinogenolytic activity, suggesting plasmin dissociation. Therefore the enhanced reaction of h alpha 2M with 'older' Sk-hPm preparations may have resulted in part from dissociated plasmin or 'plasmin-like' species. By contrast, the reaction of Sk-hPm with m alpha 2M was most rapid when the proteinase preparation was free of plasmin, indicating direct reaction of Sk-hPm with m alpha 2M as the only major mechanism. Finally, streptokinase-cat plasminogen complex reacted more extensively with m alpha 2M than with h alpha 2M, suggesting that m alpha 2M may be a superior inhibitor with this class of plasminogen activators in general.     

Changes of the proteinase binding properties and conformation of bovine alpha 2-macroglobulin on cleavage of the thio ester bonds by methylamine

Cleavage of the thio ester bonds of human alpha2-macroglobulin (alpha 2M) by methylamine leads to an extensive conformational change and to inactivation of the inhibitor. In contrast, cleavage of these bonds in bovine alpha 2M only minimally perturbs the hydrodynamic volume of the protein [Dangott, L. J., & Cunningham, L. W. (1982) Biochem. Biophys. Res. Commun. 107, 1243-1251], as well as its spectroscopic properties, as analyzed by ultraviolet difference spectroscopy, circular dichroism, and fluorescence in this work. A conformational change analogous to that undergone by human alpha 2M thus does not occur in the bovine inhibitor. However, changes of several functional properties of bovine alpha 2M are induced by the amine. The apparent stoichiometry of inhibition of trypsin thus is reduced from about 1.2 to about 0.7 mol of enzyme/mol of inhibitor. In spite of this decrease, the interaction with the proteinase induces similar conformational changes in methylamine-treated alpha 2M as in intact alpha 2M, as revealed by spectroscopic analyses, indicating that the mode of binding of the proteinase to the inhibitor is essentially unperturbed by thio ester bond cleavage. The reaction with methylamine also greatly increases the sensitivity of bovine alpha 2M to proteolysis by trypsin at sites other than the "bait" region. Moreover, the second-order rate constant for the reaction with thrombin is reduced by about 10-fold. These results indicate that the thio ester bonds of bovine alpha 2M, although not required per se for the binding of proteinases, nevertheless are responsible for maintaining certain structural features of the inhibitor that are of importance for full activity.     

The conformational changes of alpha 2-macroglobulin induced by methylamine or trypsin. Characterization by extrinsic and intrinsic spectroscopic probes.

The conformational changes around the thioester-bond region of human or bovine alpha 2M (alpha 2-macroglobulin) on reaction with methylamine or trypsin were studied with the probe AEDANS [N-(acetylaminoethyl)-8-naphthylamine-1-sulphonic acid], bound to the liberated thiol groups. The binding affected the fluorescence emission and lifetime of the probe in a manner indicating that the thioester-bond region is partially buried in all forms of the inhibitor. In human alpha 2M these effects were greater for the trypsin-treated than for the methylamine-treated inhibitor, which both have undergone similar, major, conformational changes. This difference may thus be due to a close proximity of the thioester region to the bound proteinase. Reaction of trypsin with thiol-labelled methylamine-treated bovine alpha 2M, which retains a near-native conformation and inhibitory activity, indicated that the major conformational change accompanying the binding of proteinases involves transfer of the thioester-bond region to a more polar environment without increasing the exposure of this region at the surface of the protein. Labelling of the transglutaminase cross-linking site of human alpha 2M with dansylcadaverine [N-(5-aminopentyl)-5-dimethylaminonaphthalene-1-sulphonamide] suggested that this site is in moderately hydrophobic surroundings. Reaction of the labelled inhibitor with methylamine or trypsin produced fluorescence changes consistent with further burial of the cross-linking site. These changes were more pronounced for trypsin-treated than for methylamine-treated alpha 2M, presumably an effect of the cleavage of the adjacent 'bait' region. Solvent perturbation of the u.v. absorption and iodide quenching of the tryptophan fluorescence of human alpha 2M showed that one or two tryptophan residues in each alpha 2M monomer are buried on reaction with methylamine or trypsin, with no discernible change in the exposure of tyrosine residues. Together, these results indicate an extensive conformational change of alpha 2M on reaction with amines or proteinases and are consistent with several aspects of a recently proposed model of alpha 2M structure [Feldman, Gonias & Pizzo (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 5700-5704].     

Characterization of thrombin binding to alpha 2-macroglobulin

The formation and structural characteristics of the human alpha 2-macroglobulin (alpha 2M)-thrombin complex were studied by intrinsic protein fluorescence, sulfhydryl group titration, electrophoresis in denaturing and nondenaturing polyacrylamide gel systems, and in macromolecular inhibitor assays. The interaction between alpha 2M and thrombin was also assessed by comparison of sodium dodecyl sulfate-gel electrophoretic patterns of peptides produced by Staphylococcus aureus V-8 proteinase digests of denatured alpha 2M-125I-thrombin and alpha 2M-125I-trypsin complexes. In experiments measuring fluorescence changes and sulfhydryl group exposure caused by methylamine, we found that thrombin produced its maximum effects at a mole ratio of approximately 1.3:1 (thrombin:alpha 2M). Measurements of the ability of alpha 2M to bind trypsin after prior reaction with thrombin indicated that thrombin binds rapidly at one site on alpha 2M, but occupies the second site with some difficulty. Intrinsic fluorescence studies of trypsin binding to alpha 2M at pH 5.0, 6.5, and 8.0 not only revealed striking differences in trypsin's behavior over this pH range, but also some similarities between the behavior of thrombin and trypsin not heretofore recognized. Structural studies, using sodium dodecyl sulfate-polyacrylamide gel electrophoresis to measure alpha 2M-125I-thrombin covalent complex formation, indicated that covalency reached a maximum at a mole ratio of approximately 1.5:1. At this ratio, only 1 mol of thrombin is bound covalently per mol of alpha 2M. These gel studies and those of proteolytic digests of denatured alpha 2M-125I-trypsin and alpha 2M-125I-thrombin complexes suggest that proteinases form covalent bonds with uncleaved alpha 2M subunits. The sum of our results is consistent with a mechanism of proteinase binding to alpha 2M in which the affinity of the proteinase for alpha 2M during an initial reversible interaction determines its binding ratio to the inhibitor.     

Changes in trypsin-binding properties and conformation of rabbit alpha-2-macroglobulin on reaction with methylamine

Reactions of rabbit alpha-2-macroglobulin with methylamine and trypsin were studied and the results were compared with those obtained for previously described 2-macroglobulins from other species. Rabbit alpha-2-macroglobulin was cleaved by trypsin at a number of sites, whereas the human homologue was split essentially only in the "bait" region into two fragments of similar sizes. Reaction of native or methylamine-treated rabbit alpha-2-macroglobulin with trypsin resulted in a substantial decrease in the intensity of fluorescence induced by binding of 6-(p-toluidino)-2-naphthalenesulfonate or bis(8-anilino-1-naphthalenesulfonate). Under the same conditions, the fluorescence of the human protein increased. The time course of the reaction of rabbit alpha-2-macroglobulin with methylamine was studied by measuring (i) the generation of thiol groups, (ii) the decrease in trypsin-inhibiting activity with remazol brilliant blue hide powder as the substrate, and (iii) the decrease in trypsin-protein amidase activity. The thiol appearance reaction exhibited a multiphasic time course. The initial phase was found to follow second-order kinetics with an apparent rate constant of 1.2 M-1.s-1. Under the same conditions, the human protein showed monophasic kinetics with a rate constant of 12 M-1.s-1. Both the trypsin-inhibiting activity and the trypsin-protein amidase activity concurrently decreased at a slower rate than the thiol appearance. These results indicate that rabbit alpha-2-macroglobulin is more stable to nucleophilic attack by methylamine but less resistant to proteolysis by trypsin than the human homologue, and that the final conformation induced by methylamine differs considerably from that induced by trypsin.     

Fluorescence monitoring of the conformational change in alpha 2-macroglobulin induced by trypsin under second-order conditions: the macroglobulin acts both as a substrate and a competitive inhibitor of the protease

The reaction of bovine pancreatic trypsin with human plasma alpha(2)-macroglobulin (alpha(2)M) was studied at 25 degrees C, using equimolar mixtures of E and I in 50 mM potassium phosphate buffer, pH 7. The conformational change in alpha(2)M was monitored through the increase in protein fluorescence at 320 nm (exc lambda, 280 nm). At [alpha(2)M](0) =[E](0) =11.5-200 nM, the fluorescence change data fit the integrated second-order rate equation, (F(infinity) -F(0) )/(F(infinity) -F(t) )=1+k(i,obsd) [alpha(2)M](0) t, indicating that cleavage of the bait region in alpha(2)M was the rate-determining step. The apparent rate constant (k(i,obsd)) was found to be inversely related to reactant concentration. The kinetic behavior of the system was compatible with a model involving reversible, nonbait region binding of E to alpha(2)M, competitively limiting the concentration of E available for bait region cleavage. The intrinsic value of k(i) was (1.7+/-0.24) x 10(7) M(-1) s(-1).K(p), the inhibitory constant associated with peripheral binding, was estimated to be in the submicromolar range. The results of the present study point to a potential problem in interpreting kinetic data relating to protease-induced structural changes in macromolecular substrates. If there is nonproductive binding, as in the case of trypsin and alpha(2)M, and the reactions are monitored under pseudo first-order conditions ([S](0) >[E](0) ), an intrinsically second-order process (such as the rate-limiting bait region cleavage in alpha(2)M) may become kinetically indistinguishable from an intrinsically first-order process (e.g. rate-limiting conformational change). Hence an excess of one component over the other should be avoided in kinetic studies addressing such systems.     

Inhibition of alpha 2-macroglobulin-bound trypsin by soybean trypsin inhibitor

Soybean trypsin inhibitor, a protein of Mr = 20,000, has been used to assess the degree of inaccessibility of porcine trypsin within the alpha 2-macroglobulin-trypsin complex. The interaction between alpha 2-macroglobulin-bound trypsin and the inhibitor was demonstrated by affinity chromatography and trypsin inhibition. Whereas the free trypsin-inhibitor association is very fast (k = 1.2 X 10(7) M-1 s-1), the reaction between complexed trypsin and inhibitor takes 10 h to reach equilibrium. In addition, alpha 2-macroglobulin reduces, by several orders of magnitude, the affinity of trypsin for the inhibitor. Only one of the two trypsin molecules of the ternary (trypsin)2-alpha 2-macroglobulin complex is readily accessible to soybean inhibitor. It is postulated that the recently discovered proximity of the alpha 2-macroglobulin binding sites (Pochon, F., Favaudon, V., Tourbez-Perrin, M., and Bieth, J. (1981) J. Biol. Chem. 256, 547-550) accounts for this behavior. In the light of these results it is concluded that the proteinase binding sites are localized on the alpha 2-macroglobulin surface and that the two subunits of this protein are either not identical or not symmetrically arranged.     

Interaction of chymotrypsinogens with alpha 1-protease inhibitor

In a previous report [Largman, C., Brodrick, J.W., Geokas, M.C., Sischo, W.M., & Johnson, J.H. (1979) J. Biol. Chem. 254, 8516-8523] it was demonstrated that human proelastase 2 and alpha 1-protease inhibitor react slowly to form a complex that is stable to denaturation with sodium dodecyl sulfate and beta-mercaptoethanol and that the zymogen can be recovered from the isolated complex following dissociation by hydroxylamine. The present report demonstrates that bovine chymotrypsinogen A reacts with human alpha 1-protease inhibitor in a very similar manner. The rate of complex formation was measured by two methods. In the first, the reaction was followed by determining the loss of the inhibitory activity of alpha 1-protease inhibitor as a function of time. A second-order rate constant for complex formation formation (pH 7.6, 36 degrees C) of 12.9 +/- 2.4 M-1s-1 was obtained. In the second procedure, the reaction of fluorescein isothiocyanate labeled chymotrypsinogen A with alpha 1-protease inhibitor was measured by fluorescence polarization. A second-order rate constant (pH 7.6, 37 degrees C) of 13.9 +/- 2.1 M-1s-1 was obtained. The rate of complex formation is approximately 10(-5) of that measured for the reaction of bovine chymotrypsin with alpha 1-protease inhibitor. Dissociation of the complex was not observed after dilution or the addition of excess bovine alpha-chymotrypsin. As judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis experiments, human chymotrypsinogens I and II react with alpha 1-protease inhibitor at rates that are approximatley equivalent to that determined for bovine chymotrypsinogen A. In contrast, bovine trypsinogen reacts very slowly with alpha 1-protease inhibitor, at a rate that is at most 10(-2) of that of bovine chymotrypsinogen A. These results suggest that zymogens react with alpha 1-protease inhibitor by virtue of partially formed active sites and that the potential active-site specificity of the zymogen in part determines the rate of complex formation.     

Functional modifications of α2-macroglobulin by primary amines. Kinetics of inactivation of α2-macroglobulin by methylamine, and formation of anomalous complexes with trypsin

The unique steric inhibition of endopeptidases by human alpha(2)M (alpha(2)-macroglobulin) and the inactivation of the latter by methylamine were examined in relation to each other. Progressive binding of trypsin by alpha(2)M was closely correlated with the loss of the methylamine-reactive sites in alpha(2)M: for each trypsin molecule bound, two such sites were inactivated. The results further showed that, even at low proteinase/alpha(2)M ratios, no unaccounted loss of trypsin-binding capacity occurred. As alpha(2)M is bivalent for trypsin binding and no trypsin bound to electrophoretic slow-form alpha(2)M was observed, this indicates that the two sites must react (bind trypsin) in rapid succession. Reaction of [(14)C]methylamine with alpha(2)M was biphasic in time; in the initial rapid phase complex-formation with trypsin caused a largely increased incorporation of methylamine. In the subsequent slow phase trypsin had no such effect. These results prompted further studies on the kinetics of methylamine inactivation of alpha(2)M with time of methylamine treatment. It was found that conformational change of alpha(2)M and decrease in trypsin binding (activity resistant to soya-bean trypsin inhibitor) showed different kinetics. The latter decreased rapidly, following pseudo-first-order kinetics. Conformational change was much slower and followed complex kinetics. On the other hand, binding of (125)I-labelled trypsin to alpha(2)M did follow the same kinetics as the conformational change. This discrepancy between total binding ((125)I radioactivity) and trypsin-inhibitor-resistant binding of trypsin indicated formation of anomalous complexes, in which trypsin could still be inhibited by soya-bean trypsin inhibitor. Further examination confirmed that these complexes were proteolytically active towards haemoglobin and bound (125)I-labelled soya-bean trypsin inhibitor to the active site of trypsin. The inhibition by soya-bean trypsin inhibitor was slowed down as compared with reaction with free trypsin. The results are discussed in relation to the subunit structure of alpha(2)M and to the mechanism of formation of the complex.     

The reaction of human alpha 2-macroglobulin with alpha-chymotrypsin. A stopped-flow kinetic investigation

The kinetics of the conformational changes of human alpha 2-macroglobulin (alpha 2M) induced by reaction with pure alpha-chymotrypsin, have been analyzed using three fluorescent probes, namely protein tryptophan groups and the dye 6-(4-toluidino)-2-naphthalenesulfonate, to monitor alterations of the alpha 2M structure, and a covalent conjugate of chymotrypsin and fluorescein isothiocyanate (Chy-FITC). The main reaction sequence exhibits a triphasic time course with any of the labels used. Each phase is first-order. The fixation of a single molecule of chymotrypsin to one protease-binding site of alpha 2M (site A) initiates the whole process and determines the access to the second site (site B). Of the three exponential phases of the reaction (20 degrees C), phase I (k1 approximately 19.6 min-1) and phase II (k2 approximately 5.3 min-1) belong to site A. Phase III is related to site B transformation. It contains two steps with different responses from tryptophan (k3 approximately 0.77 min-1) and Chy-FITC (k3 approximately 0.19 min-1) fluorescence measurements. The point to be stressed is that site A and site B, while presumably identical in the native form, are not equivalent with regard to their fluorescence and kinetic properties. However, the activation energy (E = 30.1 +/- 2.7 kJ mol-1) is the same for the three phases of the reaction. When present in sufficient excess, free chymotrypsin or native alpha 2M is able to form reversible complexes with the above-related chymotrypsin-alpha 2M adducts. Only the alpha 2M site A core seems to be involved in this parallel process. In addition the conformational state of the chymotrypsin-alpha 2M complexes is shown to depend on the pH, with a pKa of 6.4.     

Kinetics of the reactions between streptokinase, plasmin and alpha 2-antiplasmin.

Streptokinase reacts very rapidly with human plasmin (rate constant 5.4 S 10(7) M-1 s-1) forming a 1:1 stoichiometric complex which has a dissociation constant of 5 X 10(-11) M. This plasmin-streptokinase complex is 10(5) times less reactive towards alpha 2-antiplasmin than plasmin, the inhibition rate constant being 1.4 X 10(2) M-1 s-1. The loss of reactivity of the streptokinase-plasmin complex towards alpha 2-antiplasmin is independent of the lysine binding sites in plasmin since low-Mr plasmin, which lacks these sites, and plasmin in which the sites have been blocked by 6-aminohexanoic acid, are both equally unreactive towards alpha 2-antiplasmin on reaction with streptokinase. The plasmin-streptokinase complex binds to Sepharose-lysine and Sepharose-fibrin monomer in the same fashion as free plasmin, showing that the lysine binding sites are fully exposed in the complex. Bovine plasmin is rapidly inhibited by human alpha 2-antiplasmin (k1 = 1.6 X 10(6) M-1 s-1) and similarly loses reactivity towards the inhibitor on complex formation with streptokinase (50% binding at 0.4 microM streptokinase).     

Electron microscopy studies of alpha 2-macroglobulin conformational intermediates obtained by derivatization with cis-dichlorodiammineplatinum (II)

The structure of human alpha 2-macroglobulin (alpha 2M) after reaction with cis-dichlorodiammineplatinum (II) (cis-DDP) was studied by electron microscopy. The cis-DDP stabilized a novel conformation of the native inhibitor resembling a doughnut surrounded by two, three, of four well defined spherules. When only two spherules were present, these structures were usually oriented on opposite sides of the doughnut. The protein region joining a spherule to the central structure did not include sufficient mass to exclude stain and was, therefore, invisible. Other images showed spherules that were partially superimposed on the doughnut. A comparison of many molecules suggested great flexibility of the peripheral spherules relative to the central structure. The cis-DDP prevented complete conformational change when the alpha 2M was reacted with trypsin. The products of this reaction included apparent conformational intermediates. These intermediates most closely resembled either native alpha 2M or the well established "H" structure of alpha 2M-proteinase, depending on the initial conditions used to modify the alpha 2 M with cis-DDP. When cis-DDP-treated alpha 2M was reacted with trypsin, purified by chromatography and subsequently treated with diethyldithiocarbamate, complete conformational change was observed. Based on an analysis of the alpha 2M structural intermediates obtained using the chemical modification procedures described here, a new model of alpha 2M conformational change was developed. We postulate that conformational change initially involves contraction of the peripheral spherules towards the central doughnut. These spherules then unfold and elongate in the perpendicular direction to form the lateral walls of the proteinase transformed alpha 2M H structure.     

Mechanism of agonist and antagonist binding to alpha 2 adrenergic receptors: evidence for a precoupled receptor-guanine nucleotide protein complex

The alpha 2 adrenergic receptor (AR) inhibits adenylate cyclase via an interaction with Ni, a guanine nucleotide binding protein. The early steps involved in the activation of the alpha 2 AR by agonists and the subsequent interaction with Ni are poorly understood. In order to better characterize these processes, we have studied the kinetics of ligand binding to the alpha 2 AR in human platelet membranes on the second time scale. Binding of the alpha 2 antagonist [3H]yohimbine was formally consistent with a simple bimolecular reaction mechanism with an association rate constant of 2.5 X 10(5) M-1 s-1 and a dissociation rate constant of 1.11 X 10(-3) s-1. The low association rate constant suggests that this is not a diffusion-limited reaction. Equilibrium binding of the alpha 2 adrenergic full agonist [3H]UK 14,304 was characterized by two binding affinities: Kd1 = 0.3-0.6 nM and Kd2 = 10 nM. The high-affinity binding corresponds to approximately 65% and the low-affinity binding to 35% of the total binding. The kinetics of binding of [3H]UK 14,304 were complex and not consistent with a mass action interaction at one or more independent binding sites. The dependence of the kinetics on [3H]UK 14,304 concentration revealed a fast phase with an apparent bimolecular reaction constant kappa + of 5 X 10(6) M-1 s-1. The rate constants and amplitudes of the slow phase of agonist binding were relatively independent of ligand concentration. These results were analyzed quantitatively according to several variants of the "ternary complex" binding mechanism. In the model which best accounted for the data, (1) approximately one-third of the alpha 2 adrenergic receptor binds agonist with low affinity and is unable to couple with a guanine nucleotide binding protein (N protein), (2) approximately one-third is coupled to the N protein prior to agonist binding, and (3) the remainder interacts by a diffusional coupling of the alpha 2 AR with the N protein or a slow, ligand-independent conformational change of the alpha 2 AR-N protein complex. The rates of interaction of liganded and unliganded receptor with N protein are estimated.