Similar architectures of native and transformed human alpha2-macroglobulin suggest the transformation mechanism.

The refined three-dimensional structure of native human alpha2-macroglobulin (alpha2M) has been determined by cryoelectron microscopy and three-dimensional reconstruction. New features corresponding to "sigmoid arches," "basal bodies," and "apical connections" were observed in the molecule. Since similar elements are found in the architecture of transformed alpha2M, the 2 volumes were aligned in three dimensions. In their common orientations, they show many similarities except near the openings of the central chamber. In the native conformation, these apertures are fully opened, allowing the proteases to access the central chamber of the molecule, while in the transformed structure, they are partially closed. These structures suggest that alpha2M conformational change involves a strong lateral compression and a vertical stretching of the native particle seen in its four-petaled flower view to produce the H view of the transformed form. A model of structural transformation, in which all the parts of the alpha2M molecule seem involved in the entrapment of the proteinases is proposed.

Evidence for the binding of a biologically active interleukin-2 to human alpha 2-macroglobulin.

Human alpha 2-macroglobulin (alpha 2M), which irreversibly entraps proteinases through a drastic conformational change, has also been reported to bind various cytokines. The meaning of cytokine binding to native and/or transformed alpha 2M molecules is, however, not understood. In an attempt to elucidate this question, we have studied the interaction of radioiodinated recombinant human interleukin-2 (125I-rhIL-2) with native and chymotrypsin (alpha 2M-C)- or methylamine-transformed (alpha 2M-MA) alpha 2M. Our results show that native and alpha 2M-MA are able to bind 125I-rhIL-2, with binding occurring only with the latter in a covalent manner, whereas the labeled cytokine is proteolyzed when incubated with alpha 2M-entrapped chymotrypsin. The degradation of uncomplexed 125I-rhIL-2 has also been observed in the presence of trypsin, whereas 125I-rhIL-2 bound to alpha 2M-MA is protected. Moreover, the proliferative activity of this cytokine on responsive cells is still maintained either with native alpha 2M- or alpha 2M-MA-complexed rhIL-2 in comparison with that observed with the cytokine alone. Our results, which lead us to consider alpha 2M molecules as IL-2-binding proteins, emphasize the possible role of these molecules as immune response regulators.

Architecture of native human alpha 2-macroglobulin studied by cryoelectron microscopy and three-dimensional reconstruction.

The architecture of the native human alpha 2-macroglobulin was studied by cryoelectron microscopy and image processing techniques. The lip, padlock, doughnut, and four-petaled flower views of this homotetrameric proteinase inhibitor were observed in the frozen-hydrated specimen, and a new view, termed eye view, was also characterized. The present three-dimensional reconstruction demonstrates that all these electron microscope views derive from a single three-dimensional structure. The molecule is composed of two horizontal bodies and of two oblique arches, which border a large central cavity. The polymorphism and the flexibility of the native alpha 2-macroglobulin are discussed.

An approach to the intramolecular localization of the thiol ester bonds in the internal cavity of human alpha 2-macroglobulin based on correspondence analysis.

The plasma proteinase inhibitor alpha 2-macroglobulin (alpha 2M) can trap small proteins including cytokines. With the four internal thiol ester bonds being involved in the covalent binding of proteinases and other ligands, it was of interest to precisely localize these active groups in the alpha 2M molecule. This was approached by comparing methylamine-transformed human alpha 2M (alpha 2M-MA) and alpha 2M-MA chemically coupled to cytochrome c (Cyt c). This enzyme was chosen because of its size, which is close to that of cytokines, and because of the easy quantification of the reaction stoichiometry. The two molecular species were first mixed in a single sample that was deposited on a carbon-coated grid, negatively stained, and imaged in the electron microscope. The aligned images of the two macromolecular species were then separated by correspondence analysis and hierarchical ascendant classification and compared through the calculation of a subtraction image. The interest of this approach is that prior to the separation of the images, the two molecular species are subjected to rigorously identical treatments. The subtraction images between the average images of alpha 2M-MA and Cyt c-alpha 2M-MA allowed an unambiguous localization of the Cyt c molecules in the internal cavity of the alpha 2M molecule. The internal cavity is gradually filled when the Cyt c/alpha 2M ratio increases. However, it is not yet clear whether the thiol groups are located in the median portion of the wall or in the interwall (paddle) structure.

Three-dimensional architecture of human alpha 2-macroglobulin transformed with methylamine.

A frozen-hydrated sample embedded in vitreous ice of human alpha 2-macroglobulin transformed by methylamine was imaged by cryoelectron microscopy and reconstructed in three dimensions. In the reconstruction, the cage-like architecture of this protease inhibitor is fully revealed with a clear visualization of two lozenge-shaped lateral walls connected by thin bridges. The shape and dimensions of the internal cavity normally containing the trapped protease(s) is described. The possible locations of the thiol ester sites and inter-subunit connections are also discussed.

On the mechanism of energy transfer to Tb3+ ions in proteins. A time-resolved luminescence study of the Tb-elastase complex.

Intraprotein energy transfer to terbium ions is widely used for probing distances of calcium sites in proteins. In this work we have performed a time-resolved study of the sensitized luminescence in elastase using a pulsed laser excitation at 265 nm. Terbium-sensitized luminescence was found to build-up within about 150 microseconds, which indicates that the protein transfers energy at a rate several orders of magnitude slower than expected for a singlet state donor. From the rise time of the signal and from its variation with the oxygen concentration, it can be deduced that 80% of the transfer originates from the first triplet excited state of one unique aromatic residue. From the comparison of protein fluorescence and sensitized terbium luminescence excitation spectra the sensitizer was identified as a tryptophan, presumably Trp141, which is situated only 0.7-0.9 nm away from the Tb site. The results are at variance with the usual assumption that energy is transferred from the first excited singlet state of aromatic residues according to a long-range dipole-dipole interaction and are more consistent with a short-distance exchange mechanism.

Three-dimensional reconstruction of a complex of human alpha 2-macroglobulin with monomaleimido Nanogold (Au1.4nm) embedded in ice.

Cysteine 949 and glutamine 952 are known to be part of the thiol ester site of each of the four subunits of human alpha 2-macroglobulin (alpha 2M). The hydrolysis of this thiol ester bound to methylamine results in the incorporation of the amine and liberation of a free sulfhydryl group that can be specifically labeled. Therefore, a high-resolution marker specific for the sulfhydryl groups, the monomaleimido Nanogold (Au1.4nm) cluster was used to bind this amino acid. After cryoelectron microscopy, a three-dimensional reconstruction of the alpha 2M-Nanogold conjugates (alpha 2M-Au1.4nm) was achieved, revealing the internal location of the thiol ester sites in the transformed alpha 2M molecules. From this study we propose three possible locations for the cysteine 949.

Electron microscopy of alpha 2-macroglobulin with a thiol ester bound ligand.

In order to covalently bind the hydrolyzed thiol ester groups of the human alpha 2-macroglobulin (alpha 2M) transformed by methylamine, the phospholipase A2 (PLA2), a small enzyme (M(r) = 13,000) from Naja nigricollis snake venom was activated by succinimidyl 4-(maleimidomethyl)cyclohexane-1-carboxylate (SMCC). Average images determined from electron micrographs of the methylamine-transformed alpha 2M, with and without activated PLA2, were determined by image processing and compared. A localization of the PLA2 was achieved by subtracting the average image of alpha 2M transformed by methylamine from that containing PLA2. The results are consistent with previous work showing the central localization of chymotrypsin trapped in alpha 2M. They also suggest that the four thiol esters are located near the center of the alpha 2M molecule.

Ultrastructure of alpha 2-macroglobulins.

New results concerning the ultrastructure of human alpha 2-macroglobulin (alpha 2M) molecules are presented in connection and comparison with the historical, the current and our own most recent, even unpublished results on the structure and function of alpha 2M and related proteins. The electron microscopic approach uses classical negative staining, combined with the new imaging mode "Electron Energy Loss Spectroscopy", which provides unusual contrast, resolution and readability of the electron micrographs. Immuno- and cryoelectron microscopy, as well as image processing has provided new data necessary to the building of tentative 3D models of the molecule. A model for the native tetrameric alpha 2M is described for the first time, and tries to explain and gather the various observations, sometimes contradictory, taken from different laboratories. A revised version for a model of the methylamine- and proteinase-transformed forms of alpha 2M is also shown. The probable positions of the bait regions and the thiol esters are given on both models. We confirm that alpha 2M is a twin trap capable of inactivating one or two proteinases by partial immobilization. Preliminary results on the production of crystals of alpha 2M-chymotrypsin complexes are also presented. A critical analysis of our models is presented in comparison with others. The technical limitations reached with some techniques and some possible extensions of future research in the field are also presented.

Localization of the proteinases in the human alpha 2-macroglobulin-chymotrypsin complex by image processing of electron micrographs.

Human alpha 2-macroglobulin (alpha 2M), a large tetrameric plasma glycoprotein, inhibits a wide spectrum of proteinases by a particular "trapping" mechanism resulting from the proteolysis of peptide bonds at specific "bait" regions. This induces the hydrolysis of four thiol esters triggering both the possible covalent bonding of the proteinases and a considerable structural change in the alpha 2M molecule, also observed following direct cleavage of the thiol esters by methylamine. By subtracting average images of electron micrographs from two populations of alpha 2M molecules in the same biochemical state (with both the four cleaved bait regions and thiol esters), but containing either two or zero chymotrypsins, we are able to demonstrate the position of the two proteinases inside the tetrameric alpha 2M molecule. The comparison of the alpha 2M molecules transformed either by immobilized chymotrypsin or methylamine shows that the proteolysis of the bait regions seems of minimal importance for the general shape of the molecule and provides a direct visualization of the actual role of the thiol esters in the conformational change.

Image processing of proteinase- and methylamine-transformed human alpha 2-macroglobulin. Localization of the proteinases.

Comparative x-ray scattering experiments and electron microscopic observations have been performed on native S-form, and on different F-forms of human plasma alpha 2-macroglobulin (alpha 2M), obtained by proteinase (chymotrypsin, plasmin, and thrombin) or methylamine treatment. Image processing of electron micrographs of the alpha 2M molecules transformed by chymotrypsin, plasmin, and methylamine displayed average images which could be compared. The proteinase-complex alpha 2M molecules exhibited the usual H-like structure, but the methylamine-inactivated ones showed a different organization, with almost no stain-excluding material in the central region of the molecule, which therefore presented a central cavity filled with stain. By subtracting average images of alpha 2M-methylamine from alpha 2M-chymotrypsin or alpha 2M-plasmin, a putative localization of the proteinases inside the alpha 2M molecule, very close to its center was revealed. The values of the radii of gyration for the S- and F-forms obtained by x-ray scattering were very different (78 and 67.7 A, respectively). All four scattering curves of the F-forms were comparable in shape and showed maxima and minima different from that of the S-form alpha 2M. Image processing of electron micrographs and x-ray scattering have provided independent results which indicate that a large cavity exists in the alpha 2M-methylamine molecule and that the proteinases might be located in a very central position inside the alpha 2M-proteinase molecules.

Dissociation of alpha 2 M-macroglobulin into functional half-molecules by mild acid treatment.

A slight decrease in pH below neutrality causes the dissociation of alpha 2-macroglobulin (alpha 2M) into dimers formed of two disulfide-bonded subunits. Half-dissociation occurs at pH 6.30 (50 mM NaCl), as determined by gel filtration analysis. The dissociation can be reversed either by increasing the pH or the ionic strength. The ability of alpha 2 M half-molecules at pH 5.75 to bind chymotrypsin is not too different from that of the whole molecule at pH 7.5. Furthermore, the steady-state kinetic parameters toward chromogenic substrate of chymotrypsin bound to alpha 2 M half and whole molecules are quite identical. Likewise, the accessibility of trypsin toward soybean trypsin inhibitor is also fairly similar when involved in half or whole alpha 2 M complexes. These results are consistent with the idea that alpha 2 M-half molecules on chymotrypsin binding undergo a conformational change. This change can be observed by electron microscopy.

Conformational change at the active center of serine-proteases upon their binding to alpha 2-macroglobulin.

The inhibition rates and spectral characteristics of 2 probes specific for the active-site serine residue of proteases were examined for evidence of conformational change of the proteases upon their binding to alpha 2-macroglobulin (alpha 2M). Elastase, chymotrypsin, trypsin, and plasmin were reacted with (7-nitrobenz-2-oxa-1,3-diazole) aminoethyl- and aminopentyl methylphosphonofluoridate. The inhibition rate constants depend on the chain length of the aminoalkyl moiety of the probe and range from 10(5) to 10(4) M-1 min-1 for elastase and chymotrypsin. They are significantly modified when the proteases are stoichiometrically bound to alpha 2M. The absorption maximum of the chromophore appears in the range of 460-470 nm and 475-480 nm for the aminoethyl- and aminopentyl- conjugates, respectively. The fluorescence emission is maximal around 530 nm with a low quantum yield of about 3%. These spectral characteristics are altered in different ways by the covalent or non-covalent binding mode of the protease to alpha 2M. Finally, the CD spectrum of the NBD aminoethyl and aminopentyl elastase and chymotrypsin conjugates exhibits intense optical activity in the absorbing band of the NBD-moiety. These chiral properties are greatly altered upon binding of the protease to alpha 2M. All these results strongly suggest a conformational change in the protease at its active center upon its binding to alpha 2M; this conformational change could be taken into account to explain the alteration of the catalytic properties of the alpha 2M-bound proteases.

The molecular organization of human alpha 2-macroglobulin. An immunoelectron microscopic study with monoclonal antibodies.

To study the three-dimensional organization of alpha 2-macroglobulin (alpha 2M) from human plasma, immunoelectron microscopy of negatively stained specimens was used. A panel of monoclonal antibodies (mAb) with specificities typical for the two major conformers of alpha 2M (native and protease-transformed) was explored. The mAb have been selected and were classified biochemically as specific for either native or transformed alpha 2M or as reactive with both conformers. Furthermore, among the mAb that were specific for the proteinase-transformed form of alpha 2M, those reacting with the 20-kDa receptor-binding domain were considered a fourth category. Immunoelectron microscopy with these 20-kDa receptor-binding domain-specific mAb yielded the most typical result: predominantly, individual H-like alpha 2M-chymotrypsin molecules were complexed with two IgG molecules, each one bound to the extremities of two arms of the H-like figure. The resulting planar complex has the appearance of a dumbbell. Since this was observed with eight different mAb of this specificity, the result is interpreted to mean that the 20-kDa receptor-binding domain is compact and constitutes the outermost domain at the extremes of the arms of the H-like transformed alpha 2M. The mAb which are specific for the transformed state of alpha 2M but which do not react with the 20-kDa receptor-binding domain, also bound at the arms of the H-like figure, but at nonterminal positions. Moreover, these mAb produced mostly linear, chain-like immune complexes of numerous H-like alpha 2M molecules cross-linked by the IgG. The large category of mAb that reacted with both conformers of alpha 2M (native and proteinase complex) were observed to make various types of immune complexes with intra- and intermolecular cross-linking by the IgG. The observations of reaction of these mAb with Cd2+-induced dimers (half-molecules of alpha 2M), either native or transformed, proved helpful and, for certain mAb, essential to understand the organization of the alpha 2M-IgG complexes. Combined, the observations allow us to propose new models for the three-dimensional organization of native and chymotrypsin-transformed dimeric and tetrameric human alpha 2M.

Functional alpha 2-macroglobulin half-molecules induced by cadmium.

Human alpha 2-macroglobulin can be reversibly dissociated by Cd2+ at low ionic strength in half-molecules which retain their ability to bind tightly plasmin and chymotrypsin. The steady state kinetic parameters of these proteinases towards chromogenic substrates when bound to half-molecules are not greatly different from those determined for these enzymes linked to whole alpha 2M molecules. Cd2+ can also induce the dissociation of plasmin- and chymotrypsin - alpha 2M complexes into proteinase-alpha 2M half-molecule conjugates. These results, taken with the fact that monomeric units of alpha 2M cannot bind these proteinases, strongly suggest that each active site of alpha 2M consists in a specific arrangement of two monomeric units linked by disulfide bridges.

Some consequences of the covalent and non-covalent binding modes of plasmin with alpha 2-macroglobulin.

Analysis of plasmin-alpha 2-macroglobulin interactions by polyacrylamide gel electrophoresis showed that both the light and heavy chains of the proteinase have covalent links with the inhibitor. This covalent binding occurs with a 95 +/- 5% yield and can be abolished in the presence of hydroxylamine without modification of the plasmin-alpha 2-macroglobulin stoichiometry, the extent of the 180-kDa peptide chain cleavage and the generation of the -SH groups. However, these two different binding modes greatly influence the enzymatic properties of the proteinase as well as the occupancy by an other proteinase molecule of the free binding site of the (1:1) plasmin-alpha 2-macroglobulin complex. Non-covalently bound plasmin is more active on synthetic substrates and interacts more tightly with the basic pancreatic trypsin inhibitor than the covalently bound enzyme. Furthermore, the former complex incorporates significantly more chymotrypsin than the latter. The incorporation of chymotrypsin influences the catalytic properties of plasmin within the ternary complex.