A comparison of the actions of trypsin and pepsin on porcine immunoglobulin M and their effects on biological activity

The action of trypsin at 55 degree C and pH 8.3 on pig IgM anti-Salmonella has been compared with the action of pepsin at 37 degree C and pH 4.6. Both processes cause the gradual removal of Fab arms and Cmu2 domains to produce eventually an (Fc)5 fragment. However, during tryptic digestion Fab arms are preferentially removed from the same subunit, whereas peptic digestion causes random removal from any subunit. At intermediate stages of digestion both processes produce partially fragmented molecules which consist of an (Fc)5 portion still attached to limited numbers of Fab arms. Both processes cause a gradual decrease in the ability of molecules to agglutinate Salmonella, but complement fixation by the complexes declines much more rapidly. A stage is reached where molecules having four Fab arms can still agglutinate but there is no complement fixation. However, the remaining arms on the tryptic molecules are distributed in pairs on the same subunit, whereas those on the peptic molecules are distributed randomly. Hence the number of remaining Fab arms, rather than their distribution, appears to be the critical factor which influences biological activity. A possible explanation for this is discussed.     

Design and characterization of novel dual Fc antibody with enhanced avidity for Fc receptors

Monoclonal antibodies (mAbs) have become an important class of therapeutics, particularly in the realm of anticancer immunotherapy. While the two antigen-binding fragments (Fabs) of an mAb allow for high-avidity binding to molecular targets, the crystallizable fragment (Fc) engages immune effector elements. mAbs of the IgG class are used for the treatment of autoimmune diseases and can elicit antitumor immune functions not only by several mechanisms including direct antigen engagement via their Fab arms but also by Fab binding to tumors combined with Fc engagement of complement component C1q and Fcγ receptors. Additionally, IgG binding to the neonatal Fc receptor (FcRn) allows for endosomal recycling and prolonged serum half-life. To augment the effector functions or half-life of an IgG1 mAb, we constructed a novel “2Fc” mAb containing two Fc domains in addition to the normal two Fab domains. Structural and functional characterization of this 2Fc mAb demonstrated that it exists in a tetrahedral-like geometry and retains binding capacity via the Fab domains. Furthermore, duplication of the Fc region significantly enhanced avidity for Fc receptors FcγRI, FcγRIIIa, and FcRn, which manifested as a decrease in complex dissociation rate that was more pronounced at higher densities of receptor. At intermediate receptor density, the dissociation rate for Fc receptors was decreased 6- to 130-fold, resulting in apparent affinity increases of 7- to 42-fold. Stoichiometric analysis confirmed that each 2Fc mAb may simultaneously bind two molecules of FcγRI or four molecules of FcRn, which is double the stoichiometry of a wild-type mAb. In summary, duplication of the IgG Fc region allows for increased avidity to Fc receptors that could translate into clinically relevant enhancement of effector functions or pharmacokinetics.     

Complement fixation by model immune complexes free in solution and bound onto cell surfaces.

Immunoglobin (IgG) molecules with anti-2,4-dinitrophenyl activity were covalently cross-linked by using three cross-linking reagents. The resulting oligomers were separated into monomer, dimer, trimer, and heavy fractions. These stable assemblages of IgG molecules were capable of fixing dilute whole guinea pig complement in solution. When oligomers were further aggregated noncovalently into larger complexes, all were able to fix complement. Radioiodinated oligomers were attached to 2,4,6,-trinitrophenylsulfonic acid treated sheep red blood cells (N3ph-SRBC), and the number of bound molecules was determined from the cell-associated radioactivity. Complement-mediated lysis of N3ph-SRBC was then assayed over a range of levels of bound protein and at increasing concentrations of complement. The lytic efficiencies of all oligomers increased with the number of bound molecules, with complement concentration, with hapten density on N3ph-SRBC, and with oligomer size. The results suggest that two adjacent IgG molecules may not serve as a unit signal for triggering the complement cascade, but instead, initiation occurs with increasing efficiency as the size of cell-bound IgG clusters increases.     

Immunoelectron microscopic localization of idiotypes and allotypes on immunoglobulin molecules

We have developed a novel approach to the analysis of antigenic (allotypic and idiotypic) determinants on intact immunoglobulin molecules. Immune complexes composed of IgG in combination with anti-idiotype or anti-allotype antibody were "visualized" by transmission electron microscopy. Individual Fab fragments of anti-idiotype or anti-allotype antibody, when bound to the IgG, altered the "Y" configuration in a reproducible and interpretable manner. Anti-idiotype antibody (either as Fab or IgG) bound to the terminus of the presumed V region of the IgG molecule, thus extending the apparent length of the Fab arms. Analysis of a rabbit VH framework allotype (a1) revealed that the determinant(s) is (are) located on the lateral portion of the V region of IgG. Binding of the anti-a1 Fab fragments was always at approximately right angles to the axis of the Fab arms of IgG. Fab antibody to the rabbit kappa light chain (b4) allotype bound to the lateral portion of the terminal half of the IgG Fab arms. This technique should be of value in localizing less well defined immunoglobulin determinants.     

Higher order structures of Adalimumab,Infliximab and their complexes with TNFα revealed by electron microscopy

Adalimumab and Infliximab are recombinant IgG1 monoclonal antibodies (mAbs) that bind and neutralize human tumor necrosis factor alpha (TNFα). TNFα forms a stable homotrimer with unique surface‐exposed sites for Adalimumab, Infliximab, and TNF receptor binding. Here, we report the structures of Adalimumab‐TNFα and Infliximab‐TNFα complexes modeled from negative stain EM and cryo‐EM images. EM images reveal complex structures consisting of 1:1, 1:2, 2:2, and 3:2 complexes of Adalimumab‐TNFα and Infliximab‐TNFα. The 2:2 complex structures of Adalimumab‐TNFα and Infliximab‐TNFα show diamond‐shaped profiles and the 2D class averages reveal distinct orientations of the Fab domains, indicating different binding modes by Adalimumab and Infliximab to TNFα. After separation by size exclusion chromatography and analysis by negative stain EM, the 3:2 complexes of Adalimumab‐TNFα or Infliximab‐TNFα complexes are more complicated but retain features recognized in the 2:2 complexes. Preliminary cryo‐EM analysis of 3:2 Adalimumab‐TNFα complex generated a low‐resolution density consistent with a TNFα trimer bound with three Fab domains from three individual antibody molecules, while each antibody molecule binds to two molecules of TNFα trimer. The Fc domains are not visible in the reconstruction. These results show the two mAbs form structurally distinct complexes with TNFα.     

Electron microscopic evidence for the axial rotation and inter-domain flexibility of the Fab regions of immunoglobulin G

The Fab arms of immunoglobulin G (IgG) have long been known to hinge about their joint with the Fc subunit. Using monoclonal antibodies bound to influenza haemagglutinin (HA) as position markers, we now show that these arms can also rotate about their long axis with respect to Fc. We also show that when two IgGs are bound cyclically with two HA molecules, the arms can bend between the variable and constant domains to accommodate bond angle constraint.     

Immunoglobulin G antibody bound to the C1q subcomponent of human complement exhibits segmental flexibility

The rotational dynamics of rabbit immunoglobulin G (IgG) anti-dansyl antibodies bound to the C1q subcomponent of human complement were studied by nanosecond fluorescence spectroscopy. Deconvoluted anisotropy decays of IgG-C1q mixtures were fitted to a two-exponential expression and were corrected for the effects of unbound IgG, which was determined with an analytical ultracentrifuge. Compared with the anisotropy parameters for free IgG, the pre-exponential weighting factors and the short correlation time of the C1q-bound antibody were nearly unchanged, and the long correlation time increased by only about 45 nanoseconds. These results, together with rotational diffusion calculations, indicate that the Fab arms of the C1q-bound antibody exhibited considerable flexibility. This finding may have biological relevance because it suggests that C1q can bind to the Fc segments of IgG molecules anchored in an immune complex, even though the angles between the two Fab arms of the different antibodies may vary. The results of this study also support our earlier interpretation that both the short and long correlation times of IgG principally represent flexible motions of the Fab segments.     

Analysis of correlated domain motions in IgG light chain reveals possible mechanisms of immunological signal transduction

It was shown experimentally that binding of a micelle composed of Congo red molecules to immunological complexes leads to the enhanced stability of the latter, and simultaneously prevents binding of a complement molecule (C1q). The dye binds in a cavity created by the removal of N-terminal polypeptide chain, as observed experimentally in a model system-immunoglobulin G (IgG) light chain dimer. Molecular Dynamics (MD) simulations of three forms of IgG light chain dimer, with and without the dye, were performed to investigate the role of N-terminal fragment and self-assembled ligand in coupling between V and C domains. Root-mean-square distance (RMSD) time profiles show that removal of N-terminal fragment leads to destabilization of V domain. A micelle composed of four self-assembled dye molecules stabilizes and fixes the domain. Analysis of root-mean-square fluctuation (RMSF) values and dynamic cross-correlation matrices (DCCM) reveals that removal of N-terminal fragment results in complete decoupling between V and C domains. Binding of self-assembled Congo red molecules improves the coupling, albeit slightly. The disruption of a small beta-sheet composed of N- and C-terminal fragments of the domain (NC sheet) is the most likely reason for the decoupling. Self-assembled ligand, bound in the place originally occupied by N-terminal fragment, is not able to take over the function of the beta-sheet. Lack of correlation of motions between residues in V and C domains denotes that light chain-Congo red complexes have hampered ability to transmit conformational changes between domains. This is a likely explanation of the lack of complement binding by immunological complexes, which bind Congo red, and supports the idea that the NC sheet is the key structural fragment taking part in immunological signal transduction.     

C5b-9 assembly: average binding of one C9 molecule to C5b-8 without poly-C9 formation generates a stable transmembrane pore

Membrane attack by serum complement normally results in the formation of C5b-9 complexes that are heterogeneous with respect to their C9 content. We here report that an apparently homogeneous population of C5b-9 complexes can be generated through treatment of C5b-7-laden sheep erythrocytes with C8 and C9 for 60 min at 0 degree C. Experiments performed by using radioiodinated C8 and C9 components have indicated that binding of C8 to these target cells is essentially temperature independent. In contrast, when a surplus of C9 molecules is offered to C5b-8 cells, an approximately fourfold to 4.5-fold higher number of C9 molecules become cell bound at 37 degrees C as opposed to 0 degree C. C5b-9 complexes isolated from target membranes treated with C9 at 0 degree C contain no polymerized C9 and do not exhibit the ring structure characteristic of the classical complement lesion. Nevertheless, these complexes generate stable transmembrane channels and cause hemolysis at 37 degrees C. The pores have been sized to 1 to 3 nm effective diameter by osmotic protection experiments. SDS-PAGE of the isolated complexes indicates an average stoichiometry of only one molecule C9 bound per C5b-8 complex. The results show that oligomerization of C9 with formation of ring lesions is not a basic requirement for the generation of stable transmembrane complement pores in sheep erythrocytes. They indirectly support the contention that terminal complement components other than C9 contribute to the intramembrane domains of C5b-9 pores.     

Structural details of proteinase entrapment by human alpha2-macroglobulin emerge from three-dimensional reconstructions of Fab labeled native, half-transformed, and transformed molecules

Three-dimensional electron microscopy reconstructions of native, half-transformed, and transformed alpha2-macroglobulins (alpha2Ms) labeled with a monoclonal Fab Fab offer new insight into the mechanism of its proteinase entrapment. Each alpha2M binds four Fabs, two at either end of its dimeric protomers approximately 145 A apart. In the native structure, the epitopes are near the base of its two chisel-like features, laterally separated by 120 A, whereas in the methylamine-transformed alpha2M, the epitopes are at the base of its four arms, laterally separated by 160 A. Upon thiol ester cleavage, the chisels on the native alpha2M appear to split with a separation and rotation to give the four arm-like extensions on transformed alpha2M. Thus, the receptor binding domains previously enclosed within the chisels are exposed. The labeled structures further indicate that the two protomeric strands that constitute the native and transformed molecules are related and reside one on each side of the major axes of these structures. The half-transformed structure shows that the two Fabs at one end of the molecule have an arrangement similar to those on the native alpha2M, whereas on its transformed end, they have rotated. The rotation is associated with a partial untwisting of the strands and an enlargement of the openings to the cavity. We propose that the enlarged openings permit the entrance of the proteinase. Then cleavage of the remaining bait domains by a second proteinase occurs with its entrance into the cavity. This is followed by a retwisting of the strands to encapsulate the proteinases and expose the receptor binding domains associated with the transformed alpha2M.     

Identification and partial characterization of two type XII-like collagen molecules

We have identified two distinct collagenous macromolecules in extracts of fetal bovine skin. Each of the molecules appears to contain three identical alpha-chains with short triple-helical domains of approximately 25 kD, and nontriple-helical domains of approximately 190 kD. Consistent with these observations, extracted molecules contain a relatively short triple-helical domain (75 nm) and a large globular domain comprised of three similar arms. Despite these similarities, the purified collagenase-resistant domains are distinguished by a number of criteria. The globular domains can be chromatographically separated on the basis of charge distribution. Peptide profiles generated by V8 protease digestion are dissimilar. These molecules are immunologically unique and have distinct distributions in tissue. Finally, rotary shadow analysis of purified domains identifies size and conformation differences. Structurally, the molecules are very similar to type XII collagen, but differ in tissue distribution, since both these molecules are present in cartilage, while type XII is reported to be absent from that tissue.     

Solution structure of human and mouse immunoglobulin M by synchrotron X-ray scattering and molecular graphics modelling. A possible mechanism for complement activation

The pentameric 71-domain structure of human and mouse immunoglobulin M (IgM) was investigated by synchrotron X-ray solution scattering and molecular graphics modelling. The radii of gyration RG of human IgM Quaife and its Fc5, IgM-S, Fab'2 and Fab fragments were determined as 12.2 nm, 6.1 nm, 6.1 nm, 4.9 nm and 2.9 nm in that order. The RG values were similar for mouse IgM P8 and its Fab'2 and Fab fragments, despite the presence of an additional carbohydrate site. The IgM scattering curves, to a nominal resolution of 5 nm, were compared with molecular graphics models based on published crystallographic alpha-carbon co-ordinates for the Fab and Fc structures of IgG. Good curve fits for Fab were obtained based on the crystal structure of Fab from IgG. A good curve fit was obtained for Fab'2, if the two Fab arms were positioned close together at their contact with the C mu 2 domains. The addition of the Fc fragment close to the C mu 2 domains of this Fab'2 model, to give a planar structure, accounted for the scattering curve of IgM-S. The Fc5 fragment was best modelled by a ring of five Fc monomers, constrained by packing considerations and disulphide bridge formation. A position for the J chain between two C mu 4 domains rather than at the centre of Fc5 was preferred. The intact IgM structure was best modelled using a planar arrangement of these Fab'2 and Fc5 models, with the side-to-side displacement of the Fab'2 arms in the plane of the IgM structure. All these models were consistent with hydrodynamic simulations of sedimentation data. The solution structure of IgM can therefore be reproduced quantitatively in terms of crystallographic structures for the fragments of IgG. Putative Clq binding sites have been identified on the C mu 3 domain. These would become accessible for interaction with Clq when the Fab'2 arms move out of the plane of the Fc5 disc in IgM, that is, a steric mechanism exposing pre-existing Clq sites. Comparison with a solution structure for Clq by neutron scattering shows that two or more of the six globular Clq heads in the hexameric head-and-stalk structure are readily able to make contacts with the putative Clq sites in the C mu 3 domains of free IgM if if the Clq arm-axis angle in solution is reduced from 40 degrees-45 degrees to 28 degrees. This could be the trigger for Cl activation.     

Troybodies and pepbodies

All antibodies (Abs) with effector function are produced in mammalian cells, whereas bacterial production is restricted to smaller targeting fragments (scFv and Fab) without effector functions. In this project, we isolated different peptides that bind one of several Ab effector molecules. We have developed bacterial expression vectors for direct cloning of these peptides as fusions to scFv and Fab, and have obtained targeting fragments that also have the ability to bind Ab effector molecules. Some of these fusions (pepbodies) may also initiate Ab effector functions. We have also genetically inserted T-cell epitopes into Abs with specificity for antigen-presenting cell (APC) surface molecules to target the Ab-T-cell epitope fusions (Troybodies) to APCs. The approach is to exchange loops in Ig constant domains with single copies of well-defined T-cell epitopes. We have shown that a number of such T-cell epitopes are loaded on to MHC class II on APCs and are presented to specific T-cells. An increase in T-cell activation of up to four orders of magnitude is achieved compared with synthetic peptide. Our current goal is to identify all the loops in all Ig constant domains that may be loaded with T-cell epitopes to produce a multi-vaccine.     

Single-molecule imaging of human insulin receptor ectodomain and its Fab complexes

The insulin receptor (IR) is a four-chain, transmembrane dimer held together by disulfide bonds. To gain information about the molecular envelope and the organization of its domains, single-molecule images of the IR ectodomain and its complexes with three Fabs have been analyzed by electron microscopy. The data indicate that the IR ectodomain resembles a U-shaped prism of approximate dimensions 90 x 80 x 120 A. The width of the cleft (assumed membrane-distal) between the two side arms is sufficient to accommodate ligand. Fab 83-7, which recognizes the cys-rich region of IR, bound halfway up one end of each side arm in a diametrically opposite manner, indicating a twofold axis of symmetry normal to the membrane surface. Fabs 83-14 and 18-44, which have been mapped respectively to the first fibronectin type III domain (residues 469-592) and residues 765-770 in the insert domain, bound near the base of the prism at opposite corners. These images, together with the data from the recently determined 3D structure of the first three domains of the insulin-like growth factor type I receptor, suggest that the IR dimer is organized into two layers with the L1/cys-rich/L2 domains occupying the upper (membrane distal) region of the U-shaped prism and the fibronectin type III domains and the insert domains located predominantly in the membrane-proximal region.     

Analysis of Bacterial Immunoglobulin-Binding Proteins by X-Ray Crystallography

Protein crystallography offers a powerful means of analyzing the molecular mechanisms that underlie the action of bacterial immunoglobulin-binding proteins. Successful approaches used to date involve the isolation of individual IgG-binding domains from the immunoglobulin-binding protein under study and the crystallization of these on their own or in complex with Fc or Fab fragments. Two structures of complexes that have been determined to high resolution by protein crystallography are compared. A single IgG-binding domain from protein A (from Staphylococcus) binds to a human Fc fragment through formation of two α-helices, which bind in the cleft between the CH2 and the CH3 domains. Recognition is mediated by side chains on protein A which interact with conserved side chains on the surface of the antibody, ensuring binding to IgG molecules from different subclasses and species. A similar analysis of the complex of a single IgG-binding domain from protein G (from Streptococcus) with an Fab fragment from mouse IgG1 reveals that the same problem in molecular recognition is tackled in a different way. Protein G binds via an antiparallel alignment of β-strands from the IgG-binding domain and the CH1 domain in Fab: this main chain-main chain interaction is supported by a number of specific hydrogen bonds between the side chains in both proteins. By recognition of a high proportion of main-chain atoms, protein G minimizes the effects of IgG sequence variability in a way that is distinct from that adopted by protein A.     

Activation of the human classical complement pathway by a mouse monoclonal hybrid IgG1-2a monovalent anti-TNP antibody bound to TNP-conjugated cells

A mouse hybridoma selected and cloned for anti-TNP specificity produced three distinct monoclonal antibody species that were separated on protein A-Sepharose by stepwise acid elution. The IgG1 kappa product of the parental myeloma was eluted at pH 6.0. An IgG2a kappa bivalent anti-TNP antibody was eluted at pH 4.5, whereas elution at pH 5.0 yielded a hybrid IgG1-2a kappa monovalent anti-TNP antibody. The IgG2a molecules agglutinated TNP-conjugated sheep erythrocytes (TNP-ES) and lysed TNP-ES in the presence of normal human serum (NHS). Hybrid IgG1-2a antibody was also capable of lysing the cells in NHS, although it did not agglutinate TNP-ES. A threshold in monovalent antibody input was necessary for the lysis of TNP-ES, indicating a requirement for a minimal density of bound monovalent IgG to trigger complement activation. Lysis occurred in NHS-VBS++ but not in NHS-MgEGTA, and it was associated with a dose-dependent consumption of C1, C4, and C2 hemolytic activities. Quantitation of the antibody bound to TNP-ES when using radiolabeled rabbit anti-mouse Fab antibody demonstrated that for similar inputs, 5.4 times as much bivalent as monovalent antibody bound to TNP-ES. When similar amounts of antibody were effectively bound to TNP-ES, monovalent hybrid IgG1-2a was five times less efficient than bivalent IgG2a to yield 50% cell lysis in the presence of NHS. These results indicate that neither bivalent binding nor the presence of two identical heavy chains are necessary requirements for antibody-dependent activation of the classical complement pathway.     

Structure and flexibility of individual immunoglobulin G molecules in solution

In contrast to averaging methods of determining structure, such as X-ray diffraction, NMR, and single-particle tomography, cryo-electron tomography allows three-dimensional imaging of an individual object in solution. The method has previously been used to study cells and very large macromolecules. We have used cryo-electron tomography to analyze a monoclonal IgG, with a molecular weight of only 150 kDa. Tomograms reveal y-shaped IgG molecules with three protruding subunits. Docking X-ray structures enabled us to recognize the three subunits as two ellipsoidal Fab arms and a heart-shaped Fc stem. Each subunit has a similar structure in the tomograms and in the X-ray map. Notably, the positions of the Fab arms relative to the Fc stem differed greatly from one molecule to another. The large flexibility of IgG in solution is most likely of functional significance in antigen recognition. This distribution of individual structures provides a qualitative insight into the system dynamics.     

The binding of complement by complexes formed between a rabbit antibody and oligosaccharides of increasing size.

Immune complexes formed between a homogeneous rabbit antibody to type III pneumococcal polysaccharide and a series of oligosaccharides of varying size derived from it were prepared and tested for their ability to fix guinea pig hemolytic complement. Antibody and either tetra-, hexa-, or octasaccharide formed only monomeric antibody-hapten complexes and did not show any complement binding. A dodecasaccharide and a 16-sugar residues oligomer formed dimer and trimer immune complexes. These complexes were also unable to fix complement. However, as the size of the sugar oligomers was increased to about 21 sugar residues per oligosaccharide molecule or more, the resulting complexes exhibited substantial complement binding, concomitant with the formation of antigen-antibody aggregates higher than trimers. On the other hand, an independent study carried out with the same material suggested changes in the conformation of the Fc moiety in the antibody molecule upon addition of oligosaccharide ligands as small as a 16-residue unit. Since the resulting complexes hardly ehibited any complement binding, ligand-induced conformational changes in the Fc part of the antibody molecule appears to be an insufficient condition per se for triggering complement fixation.     

Immunochemical studies of organ and tumor lipids XVIII. Cytolipin R determinants in the rat erythrocyte membrane

Summary Rabbit antisera to rat lymphosarcoma contain antibodies that agglutinate trypsinized rat erythrocytes. These reactions can be specifically inhibited by cytolipin R, a ceramide tetrasaccharide isolated from rat lymphosarcoma. The agglutinin in the rabbit antisera can be absorbed with untreated erythrocytes, showing that cytolipin R determinants are present in the intact rat erythrocyte membrane. Untreated erythrocytes are able to react with antibody, but presumably the number of cytolipin R determinants necessary for agglutination becomes available only after treatment with trypsin. The anti-cytolipin R antibodies in anti-rat lymphosarcoma sera that cause hemagglutination and those that fix complement with this hapten are different, since the agglutinin can be absorbed completely without appreciable decrease in complement-fixing antibody.A preliminary report was presented at the 53rd Annual Meeting of the Federation of American Societies for Experimental Biology, Atlantic City, N.J., April, 1969 (1969,Fed. Proc. 28:700).     

Intramolecular localization of epitopes within an oligomeric protein by immunoelectron microscopy and image processing

Three epitopes have been localized by immunoelectron microscopy on subunit Aa6 of the 4 x 6-meric hemocyanin of the scorpion Androctonus australis. Soluble immunocomplexes composed of monoclonal antibodies and of native hemocyanin were purified, negatively stained with uranyle acetate by the single-layer technique, and examined under the electron microscope (EM). The molecule images were digitized, aligned, and submitted to correspondence analysis according to the method of Van Heel and Frank (Ultramicroscopy 6:187-194, 1981). A high-precision localization of the attachment point of the Fab arm to the antigen was achieved through a careful analysis of the average images. This method easily allowed the discrimination of epitopes located in different domains (Mr 20 kDa) of the same subunit. Nonoverlapping epitopes located in the same structural domain of subunit Aa6 could be distinguished by the stain exclusion patterns of their Fab arms. The method is general and may be used for epitope mapping in any antigen producing definite EM views.