Electron microscopic and hydrodynamic studies of protein A-immunoglobulin G soluble complexes

The soluble complexes formed by reacting staphylococcal protein A (SpA) with rabbit immunoglobulin G (IgG) antibodies were characterized by hydrodynamic and electron microscopic methods. In moderate SpA excess, equilibrium mixtures of SpA and rabbit IgG formed four discrete complexes that sedimented at approximately 7, 10, 13, and 15S. The putative complexes were visible by electron microscopy and appeared to contain one, two, three, and approximately five molecules of IgG. Probably because of its elongated shape, SpA was not clearly visible in these mixtures or in control preparations of SpA alone. Both native IgG and IgG modified by cleavage of its single-hinge disulfide bond formed similar complexes on interaction with SpA. It was possible to resolve heterogeneous mixtures of IgG-SpA complexes by using an analytical ultracentrifuge equipped with a photoelectric scanner interfaced to a small computer. The relative concentrations and sedimentation velocities of different complexes in a mixture were determined from computer-generated integral and derivative plots. Both hydrodynamic and electron microscopic methods revealed that the distribution of complexes was sensitive to the IgG to SpA molar ratio. The relative amounts of faster complexes increased as the IgG to SpA molar ratio was increased. Surprisingly, when the IgG to SpA molar ratio was greater than or equal to 2, the complexes were converted into a unique 17S complex. This rather unprecedented transformation was reversible: the addition of excess SpA caused the dissociation of the 17S complex into a mixture of the 7, 10, 13, and 15S structures. The average translational diffusion coefficient of the 17S complex was 2.62 +/- 0.13 Ficks. In the electron microscope, the complex appeared to be exceptionally compact with an average diameter of 287 A. The stoichiometry of the 17S complex, together with sedimentation equilibrium, diffusion, and electron microscopic measurements, indicated that it is composed of four molecules of IgG and two molecules of SpA.     

Separation of complexes containing protein A and IgG or Fcγ fragments by high-performance liquid chromatography

Protein A of Staphylococcus aureus is a bivalent Fc receptor that can form complexes with immunoglobulin G (IgG) or Fcγ fragments that activate humoral (e.g., complement) and cellular (e.g., lymphocyte) components of the immune system both in vitro and in vivo. To obtain complexes formed between protein A of Staphylococcus aureus (SpA) and rabbit IgG or Fcγ fragments for purposes of characterizing their compositions and studying their biological activities, we have used high-performance liquid chromatography to separate complexes in 20 min. Complexes were prepared with trace amounts of ¹²⁵I-SpA and ¹³¹I-IgG or ¹³¹I-Fcγ to simplify the analyses. With excess molar amounts of IgG or Fcγ the complexes have the molecular formulas [(IgG)₂SpA]₂ or [(Fcγ)₂SpA]₂. With excess SpA, complexes corresponding to (IgG)(SpA) or (Fcγ)(SpA) are formed, perhaps with other complexes that have different ratios of components. Since SpA is a rod-shaped molecule it elutes at a molecular weight corresponding to 240,000 rather than the true value of 42,000. This behavior is reflected in the elution of certain complexes at shorter retention times than expected on the basis of actual molecular weights, and facilitates separation of complexes from free IgG or Fcγ. The true molecular weights and molecular formulas of complexes isolated by HPLC were verified by ultracentrifugation. This HPLC method was used to study the interconversion and stability of complexes.     

Mechanism and kinetics of the thermal activation of glucocorticoid hormone receptor complex.

Steroid-receptor complexes formed at low temperature and ionic strength do not bind to nuclei or chromatin. After a temporary exposure to high temperature, or ionic strength, or both, a fraction of them becomes activated (able to bind to nuclei). An assay of the activated form of the complex based upon titration with nuclei in excess was established. This assay was used to perform kinetic and equilibrium studies of the thermal activation of glucocorticoid-receptor complex in order to elucidate its mechanism. It was found that the reaction is of apparent first order and yields a monomolecular product. It thus probably consists of a conformational change in the steroid-receptor complex. The rate of activation is 1.37 +/- 0.06 X 10(-3) S-1 at 25 degrees. The free energy of thermodynamic activation (The word activation is used here in its usual thermodynamic meaning and not in the sense of receptor modification) of this reaction is greater than G = 21.3 Kcal. The corresponding enthalpy and entropy are respectively greater than H = 31.4 kcal and greater than S = 4 cal/degree. These positive and high values of greater than H and greater than S are very similar to those described for denaturation reactions of proteins suggesting that breakage of some noncovalent bonds could take place during activation. The reaction proceeds until approximately 60% of the complexes are activated. It was shown that this corresponds to an equilibrium between activated and nonactivated forms and not to the presence of a population of complexes unable to undergo activation. This equilibrium is not modified by temperature variations between 10 degrees and 30 degrees. It is possible to activate over 80% of the complexes when the activation is performed in the presence of excess acceptor, thus shifting the equilibrium. A similar situation is probably observed in situ in cells since 90% of the complexes are found in the nuclei when liver slices are incubated with hormone.     

Complexes prepared from protein A and human serum,IgG, or Fcγ fragments: characterization by immunochemical analysis of ultracentrifugation fractions and studies on their interconversion

Summary Protein A of Staphylococcus aureus is an Fc receptor for IgG that has been used as a therapeutic reagent to treat cancer in humans and experimental animals. We used ultracentrifugation combined with analysis of isolated fractions by radioimmunoprecipitation and competitive radioimmunoassay with chicken antibodies that bind free protein A or protein A in complexes but do bind free immunoglobulin reagents to localize and characterize the types of complexes formed with different molar ratios of ¹²⁵I-protein A and human ¹³¹I-IgG alone or in serum, and ¹³¹1-Fc fragments. This approach offers a distinct advantage over direct counting of radioactivity in the fractions because resolution of complexes and free reagents is much improved. With excess ¹³¹I-IgG or ¹³¹1-Fc, all the ¹²⁵I-protein A is present only in complexes that contained 4 molecules of immunoglobulin reagent and 2 molecules of protein A (4:2 complexes), whereas with excess ¹²⁵I-protein A the stoichiometry of the complexes was 1:1. We have also shown the preformed 4:2 and 1:1 complexes will interconvert in the presence of added excess protein A or IgG, respectively, and that fresh IgG will exchange with IgG or Fc in preformed complexes. Because protein A has been found to elute from an immobilized reagent used in serotherapy of human cancer and is present in a large excess of IgG, the 4:2 complexes may play an active role in the tumoricidal or toxic reactions observed.Abbreviations SpA protein A of Staphyloccus aureus - VBS EDTA gel, 0.0055 M veronal buffered saline containing 0.01 M EDTA and 0.1% gelatin, pH 7.4 - PBS 0.01 M phosphate buffered saline, pH 7.4     

The adhesion of protein A-bearing Staphylococcus aureus organisms to soluble-staphylococcal-antigens-coated HeLa cells mediated by specific antibodies

The adhesion of staphylococcal protein A (SpA)-bearing Staphylococcus aureus Cowan I organisms to HeLa cells was enhanced by pretreatment of HeLa cells with staphylococcal extracellular antigens and antibodies to them. The adhesion of HLj, an SpA-poor mutant derived from Cowan I, to HeLa cells was not enhanced by the same pretreatment of HeLa cells. Furthermore, the enhanced staphylococcal adhesion was inhibited by soluble SpA. The antigen(s) responsible for the enhanced staphylococcal adhesion was(were) heat stable. Pretreatment of HeLa cells with the mixture of staphylococcal extracellular antigens and antibodies to them also enhanced the adhesion of Cowan I. Similarly the adhesion of Cowan I was enhanced by pretreatment of HeLa cells with extracellular antigens of Pseudomonas aeruginosa and antibodies to them. These results indicated that cell-bound SpA mediated the binding of S. aureus to immune complexes composed of extracellular bacterial products and antibodies to them bound to the surface of HeLa cells, and suggested another role of cell-bound SpA as a co-adhesin with other factors in infections due to S. aureus.     

Monoclonal alkaline phosphatase-anti-alkaline phosphatase (APAAP) complex: production of antibody, optimization of activity, and use in immunostaining

A mouse monoclonal antibody, FMC55 (an IgG1), to alkaline phosphatase was prepared and evaluated in immunostaining. Clones producing antibody to alkaline phosphatase were selected using a micro-ELISA which identified antibodies forming active soluble complexes (APAAP) with the enzyme. Conditions that influenced the formation of the complex were investigated by using a quantitative assay in which the complex was captured by a bridging anti-mouse antibody. The ratio of FMC55 to enzyme had a major influence on the activity of the complex. Although all complexes had some activity, those that contained excess antibody had reduced ability to bind to anti-mouse antibody because of competition with excess unlabeled antibody. The optimal complex was formed with 3 micrograms of FMC55 per unit of enzyme. This complex contained neither free enzyme nor free antibody. The molecular weight by gel permeation chromatography was 600,000, giving a composition of two enzyme and two antibody molecules or one enzyme and three antibody molecules. The size of the complex was not altered by adding excess antibody or excess enzyme. Immunoblotting showed that FMC55 bound only to the Mr 140,000 homodimeric form of alkaline phosphatase. The APAAP complex was used in combination with biotin-streptavidin-peroxidase reagent to detect two antigens labeled with two different mouse monoclonal antibodies in the same tissue preparation.     

Detection and characterization of individual intermolecular bonds using optical tweezers

The development of scanning probe techniques has made it possible to examine protein-protein interactions at the level of individual molecular pairs. A calibrated optical tweezers, along with immunoglobulin G (IgG)-coated polystyrene microspheres, has been used to detect individual surface-linked Staphylococcus protein A (SpA) molecules and to characterize the strength of the noncovalent IgG-SpA bond. Microspheres containing, on average, less than one IgG per contact area were held in the optical trap while an SpA-coated substrate was scanned beneath them at a distance of approximately 50 nm. This geometry allows the trapped bead to make contact with the surface, from bond formation to rupture, and results in an enhancement of the force applied to a bond due to leverage supplied by the bead itself. Experiments yielded median single-bond rupture forces from 25 to 44 pN for IgG from four mammalian species, in general agreement with predictions based on free energies of association obtained from solution equilibrium constants.     

Immunoglobulin M synthesized by human lymphoblastoid cells: interaction with Staphylococcus aureus and protein A.

Immunoglobulin M synthesized by a human lymphoblastoid cell line, LA173, was found to bind specifically to the protein A-bearing Cowan I strain of Staphylococcus aureus. The (3H)-leucine-labeled, secreted IgM from these LA173 cells also formed precipitin complexes with purified protein A. Soluble complexes formed at high protein A/IgM ratios retained the ability to bind to the bacterial surface. Precipitin complexes also were observed in double diffusion Ouchterlony gels with a line of identity formed between the IgM, protein A, and anti-IgM in adjacent wells. Intracellular IgM species from detergent-lysed LA173 cells were bound to S. aureus. Labeled 19S pentamers, 8S monomers, and HL subunits were eluted from the bacteria and identified by velocity sedimentation and SDS agarose-acrylamide gel electrophoresis. In addition, several intermediates migrating between 8S and 19S were detected and shown to contain authentic H and L chains. Binding of the labeled IgM 19S pentamers to staphylococci was not inhibited by prior treatment of the bacteria with an excess of unlabeled human IgG. However, S. aureus saturated with unlabeled IgG did not bind either labeled IgM monomers or labeled IgG. The interaction of this human IgM with S. aureus exhibited a high degree of specificity with quantitative recovery of secreted 19S IgM. Intracellular IgM species were bound selectively by the bacteria with little if any contamination by other cytoplasmic proteins.     

Increased Levels of IgG Antibodies against Human HSP60 in Patients with Spondyloarthritis

Spondyloarthritis (SpA) comprises a heterogeneous group of inflammatory diseases, with strong association to human leukocyte antigen (HLA)-B27. A triggering bacterial infection has been considered as the cause of SpA, and bacterial heat shock protein (HSP) seems to be a strong T cell antigen. Since bacterial and human HSP60, also named HSPD1, are highly homologous, cross-reactivity has been suggested in disease initiation. In this study, levels of antibodies against bacterial and human HSP60 were analysed in SpA patients and healthy controls, and the association between such antibodies and disease severity in relation to HLA-B27 was evaluated.Serum samples from 82 patients and 50 controls were analysed by enzyme-linked immunosorbent assay (ELISA) for immunoglobulin (Ig)G1, IgG2, IgG3 and IgG4 antibodies against human HSP60 and HSP60 from Chlamydia trachomatis, Salmonella enteritidis and Campylobacter jejuni. Disease severity was assessed by the clinical scorings Bath Ankylosing Spondylitis Disease Activity Index (BASDAI), Bath Ankylosing Spondylitis Functional Index (BASFI) and Bath Ankylosing Spondylitis Metrology Index (BASMI).Levels of IgG1 and IgG3 antibodies against human HSP60, but not antibodies against bacterial HSP60, were elevated in the SpA group compared with the control group. Association between IgG3 antibodies against human HSP60 and BASMI was shown in HLA-B27⁺ patients. Only weak correlation between antibodies against bacterial and human HSP60 was seen, and there was no indication of cross-reaction.These results suggest that antibodies against human HSP60 is associated with SpA, however, the theory that antibodies against human HSP60 is a specific part of the aetiology, through cross-reaction to bacterial HSP60, cannot be supported by results from this study. We suggest that the association between elevated levels of antibodies against human HSP60 and disease may reflect a general activation of the immune system and an increased expression of human HSP60 in the synovium of patients with SpA.     

Immune complexes with cationic antibodies deposit in glomeruli more effectively than cationic antibodies alone

In previously published studies, highly cationized antibodies alone and in immune complexes bound to glomeruli by charge-charge interaction, but only immune complexes persisted in glomeruli. Because normal IgG does not deposit in glomeruli, studies were conducted to determine whether cationized antibodies can be prepared which deposit in glomeruli when bound to antigen but not when free in circulation. A series of cationized rabbit antiHSA was prepared with the number of added amino groups ranging from 13.3 to 60.2 per antibody molecule. Antibodies alone or in preformed soluble immune complexes, prepared at fivefold or 50-fold antigen excess, were administered to mice. With the injection of a fixed dose of 100 micrograms per mouse, antibodies alone did not deposit in glomeruli with less than 29.6 added amino groups by immunofluorescence microscopy. In contrast, 100 micrograms of antibodies with 23.5 added amino groups in immune complexes, made at fivefold antigen excess, formed immune deposits in glomeruli. With selected preparations of cationized, radiolabeled antibodies, deposition in glomeruli was quantified by isolation of mouse glomeruli. These quantitative data were in good agreement with the results of immunofluorescence microscopy. Immune complexes made at 50-fold antigen excess, containing only small-latticed immune complexes with no more than two antibody molecules per complex, deposited in glomeruli similar to antibodies alone. Selected cationized antibodies alone or in immune complexes were administered to mice in varying doses. In these experiments, glomerular deposition of immune complexes, made at fivefold antigen excess, was detected with five- to 10-fold smaller doses than the deposition of the same antibodies alone. These studies demonstrate that antibody molecules in immune complexes are more likely to deposit in glomeruli by charge-charge interactions than antibodies alone.     

Isothermal titration calorimetry reveals differential binding thermodynamics of variable region-identical antibodies differing in constant region for a univalent ligand

The classical view of immunoglobulin molecules posits two functional domains defined by the variable (V) and constant (C) regions, which are responsible for antigen binding and antibody effector functions, respectively. These two domains are thought to function independently. However, several lines of evidence strongly suggest that C region domains can affect the specificity and affinity of an antibody for its antigen (Ag), independent of avidity-type effects. In this study, we used isothermal titration calorimetry to investigate the thermodynamic properties of the interactions of four V region-identical monoclonal antibodies with a univalent peptide antigen. Comparison of the binding of IgG1, IgG2a, IgG2b, and IgG3 with a 12-mer peptide mimetic of Cryptococcus neoformans polysaccharide revealed a stoichiometry of 1.9-2.0 with significant differences in thermodynamic binding parameters. Binding of this peptide to the antibodies was dominated by favorable entropy. The interaction of these antibodies with biotinylated peptides manifested greater enthalpy than for native peptides indicating that biotin labeling affected the types of Ag-Ab complexes formed. Our results provide unambiguous thermodynamic evidence for the notion that the C region can affect the interaction of the V region with an Ag.     

DNA-lipid complexes: stability of honeycomb-like and spaghetti-like structures.

A molecular level theory is presented for the thermodynamic stability of two (similar) types of structural complexes formed by (either single strand or supercoiled) DNA and cationic liposomes, both involving a monolayer-coated DNA as the central structural unit. In the "spaghetti" complex the central unit is surrounded by another, oppositely curved, monolayer, thus forming a bilayer mantle. The "honeycomb" complex is a bundle of hexagonally packed DNA-monolayer units. The formation free energy of these complexes, starting from a planar cationic/neutral lipid bilayer and bare DNA, is expressed as a sum of electrostatic, bending, mixing, and (for the honeycomb) chain frustration contributions. The electrostatic free energy is calculated using the Poisson-Boltzmann equation. The bending energy of the mixed lipid layers is treated in the quadratic curvature approximation with composition-dependent bending rigidity and spontaneous curvature. Ideal lipid mixing is assumed within each lipid monolayer. We found that the most stable monolayer-coated DNA units are formed when the charged/neutral lipid composition corresponds (nearly) to charge neutralization; the optimal monolayer radius corresponds to close DNA-monolayer contact. These conclusions are also valid for the honeycomb complex, as the chain frustration energy is found to be negligible. Typically, the stabilization energies for these structures are on the order of 1 k(B)T/A of DNA length, reflecting mainly the balance between the electrostatic and bending energies. The spaghetti complexes are less stable due to the additional bending energy of the external monolayer. A thermodynamic analysis is presented for calculating the equilibrium lipid compositions when the complexes coexist with excess bilayer.     

Size and structure of antigen-antibody complexes: thermodynamic parameters

The role of antigen-antibody (Ag-Ab) complexes in the immune response depends, in part, on the size of the complexes. Previously, we combined electron microscopy with classical and quasi-elastic light scattering to characterize the molecular weight distribution and the conformation of Ag-Ab complexes made from bovine serum albumin (BSA) and pairs of anti-BSA monoclonal antibodies at a single concentration and Ag:Ab molar ratio. In this report, the molecular weight distribution of Ag-Ab complexes was determined by classical light scattering at a single Ag:Ab ratio and over a range of concentrations, and binding of BSA to pairs of MAb was determined by radioimmunoassay at several Ag:Ab molar ratios. A thermodynamic model was developed for the equilibrium size distribution of Ag-Ab complexes formed between a pair of MAb, each with unique affinity and specificity, and an Ag containing a single epitope for each of the pair of MAb. The combined experimental data were used in conjunction with the model to determine the values of cyclization and polymerization constants. Successful determination of the parameters required data from both classical light scattering and electron microscopy. Cyclization constants were lower than those reported in other studies of Ag-Ab complexes; this may be attributable to our use of a protein Ag, as compared to a divalent hapten. In two out of three cases, cyclization constants increased with increasing number of Ab in the complex, in contrast to previous assumptions. The validity of the thermodynamic model was further shown by its ability, in combination with conformational and hydrodynamic model, to predict the hydrodynamic radius of the complexes over a wide range of experimental conditions.     

Dissociation between murine spleen cell mitogenic activity of enterotoxin contaminants and anti-tumor activity of staphylococcal protein A

Soluble staphylococcal protein A (SpA) in the form of high m.w. complexes with IgG has been shown to significantly inhibit the growth of Meth A fibrosarcomas in BALB/c mice. Although SpA reportedly is a potent T cell mitogen that can induce immune cell proliferation and production of humoral factors with anti-tumor activity, it has been suggested that mitogenic enterotoxin contaminants might be responsible for these effects. The purpose of the present study was to investigate the nature of SpA-induced cell proliferation and the relationship between mitogenicity and the anti-tumor effect that we observed in our mouse model. SpA stimulated the proliferation of a mixed population of splenic B and T cells from BALB/c mice, but activity did not require the presence of IgG in the culture medium. Furthermore, mitogenic activity could be inhibited completely by anti-SEA plus anti-SEB, but was unaffected by anti-SpA. HPLC-purified SpA was inactive while the mitogenic factor(s) had the same retention time as authentic enterotoxin and its activity was inhibited by anti-SEA and anti-SEB, but not by anti-SpA. Enterotoxin-free rSpA produced in Escherichia coli had the same IgG binding capacity as the staphylococcal product but was not mitogenic. These data indicate that SEA and SEB completely account for mitogenicity in SpA preparations. In contrast, we found that optimal concentrations of rSpA as well as crude and HPLC purified staphylococcal SpA were equally effective in inhibiting the growth of established Meth A fibrosarcomas demonstrating that SpA is responsible for antitumor activity without any apparent role for enterotoxins.     

Effect of antibody excess on the size, stoichiometry, and DNAse resistance of DNA anti-DNA immune complexes

The binding of antibodies to DNA was examined under conditions of increasing antibody excess. DNA anti-DNA immune complexes (IC) formed at increasing antibody to DNA ratios were digested with excess DNAse I, and the DNAse-resistant (protected) IC were analyzed. With increasing antibody excess, the size of the IC that were resistant to DNAse digestion increased, and the size of the protected DNA within the IC also increased. This suggested that IgG molecules could bind in close proximity along the DNA molecule, preventing access of DNAse to the DNA between adjacent IgG. To further define the binding of adjacent IgG, DNAse digested IC containing one or two IgG were isolated, and the DNA contained within these IC was analyzed on DNA sequencing gels. Binding of a single IgG to DNA resulted in the protection of a DNA fragment 35 to 45 base pairs (bp) long, corresponding to the distance between binding sites of a single IgG molecule. Binding of two IgG to DNA protected a DNA fragment 50 to 60 bp long, 1 1/2 times the size of the fragment protected by one IgG. These data suggest that in conditions of Ab excess, IgG molecules can interdigitate along the DNA molecule, resulting in small, stable, DNAse-resistant IC of high antibody density.     

Variations in the size of growth hormone-antibody complexes

Guinea pigs were immunized with extracted human growth hormone. Human sera were obtained after treatment with biosynthetic methionyl hGH. The size of hGH-anti hGH antibody complexes was determined from the sedimentation velocity at 100,000 g. At an excess of hGH over antibodies 8 S complexes were uniformly observed in human and guinea pig sera. S values between 11.8 and 15.6 were observed at antibody excess in individual guinea pig sera. Antibodies from humans treated with methionyl hGH formed smaller complexes (7.5 S). One patient with GH-deficiency developed resistance to treatment. Complexes of 12.3 S were formed by his antibodies. HGH sustains the formation of antibody complexes containing more than three IgG molecules (15.6 S). It is discussed that human antibodies of higher diversity may form complexes larger than trimers which initiate the complement cascade.     

Acceleration of intradermal catabolism of guinea pig IgG1 and IgG2 antibodies by challenge with antigen.

The intradermal catabolism of antibodies injected in guinea pigs to provoke skin reactions was studied using 125I-labeled guinea pig IgG1 and IgG2 anti-ovalbumin antibodies. Disappearance of both the IgG1 and IgG2 antibodies from injected sites was accelerated by intravenous injection of the antigen. The antigen-antibody complexes produced in vitro were also catabolized more rapidly than free antibodies, when estimated using 125I-labeled antibodies. On the other hand, the catabolism of normal IgG2 was not influenced by local anaphylactic reaction elicited by IgG1 antiovalbumin antibody coexisting at the sites. Therefore, the enhanced catabolism of antibodies on challenge was not caused by increased vascular permeability due to anaphylactic reactions, but by more rapid elimination of immune complexes formed at the sites. The Fc parts of IgG1 and IgG2 antibodies played an essential role in the enhancement of catabolism since the catabolism of the F(ab')2 fragments was not accelerated by complex formation with ovalbumin, but rather reduced.     

Effect of base stacking on the relative thermodynamic stability of oligonucleotide complexes: a spectroscopic study

Three-strand oligonucleotide complexes are employed to assess the effect of base stacking and base pair mismatch on the relative thermodynamic stabilities of oligonucleotide duplexes. The melting behavior of three-strand oligonucleotide complexes incorporating nicks and gaps as well as internal single base mismatches is monitored using temperature-dependent optical absorption spectroscopy. A sequential three-state equilibrium model is used to analyze the measured melting profiles and evaluate thermodynamic parameters associated with dissociation of the complexes. The free-energy of stabilization of a nick complex compared to a gap complex due to base stacking is determined to be -1.9 kcal/mol. The influence of a mispaired base in these systems is shown to destabilize a nick complex by 3.1 kcal/mol and a gap complex by 2.8 kcal/mol, respectively.     

Superoxide anion production from guinea pig macrophages stimulated with immune complexes of different IgG subclasses

Guinea pig peritoneal macrophages produced superoxide anions (O2-) when reacted with ovalbumin complexes of homologous IgG1 and IgG2 antibodies. In this reaction, IgG2 complexes were about three times as active as IgG1 complexes. But the susceptibility of IgG1 complexes to phagocytosis by the cells appeared to be indistinguishable from that of IgG2 complexes. The avidity of IgG1 complexes in the antigen excess zone for Fc receptors on the cells was lower than that of the IgG2 counterparts. The amount of IgG1 complex bound to the cells, however, did not significantly differ from that of IgG2 complexes when compared using each complex at the equivalence zone which showed maximal effector functions on the cells. The binding of Clq to IgG2 complexes increased markedly the amounts of complexes bound to the cells, but it reduced O2- generation. These results suggest that the difference in abilities of IgG1 and IgG2 complexes to promote O2- generation may be caused by different structures of the Fc parts or their antigen complexes involved in priming macrophages for O2- generation.     

The interaction of Phe472 with a fluorescent inhibitor bound to the complex of myosin subfragment-1 with nucleotide

The fluorescent probe 3-[4-(3-phenyl-2-pyrazolin-1-yl)benzene-1-sulfonyl amido]phenylboronic acid (PPBA) acts as a fluorescent inhibitor for the ATPases of skeletal [Hiratsuka (1994) J. Biol. Chem. 269, 27251-27257] and Dictyostelium discoideum [Bobkov et al. (1997) J. Muscle Res. Cell Motil. 18, 563-571] myosins. The former paper suggested that, upon addition of excess nucleotides to the binary complex of subfragment-1 from skeletal myosin (S1) with PPBA, a stable ternary complex of S1 with PPBA and nucleotide is formed. Useful fluorescence properties of PPBA enable us to distinguish the conformation of the myosin ATPase at the ATP state from that at the ADP state. In the present paper, to determine the PPBA-binding site in the complexes, enzymatic and fluorescence properties of the S1.PPBA.nucleotide complexes were investigated. Upon formation of the ternary complex with ATP, a new peak appeared at 398 nm in the PPBA fluorescence spectrum. Experiments using model compounds of aromatic amino acid suggested that this fluorescence peak at 398 nm is originated from PPBA interacting with Phe residue(s). Taking into account differences in fluorescence spectra between complexes of S1 and those of subfragment-1 from D. discoideum myosin (S1dC), in the ternary complex of S1 formed with ATP, PPBA was suggested to interact with Phe residue(s) that is absent in S1dC. Docking simulation of PPBA on the S1.nucleotide complex revealed that Phe472 interacts with PPBA. Binding sites of PPBA and blebbistatin, an inhibitor showing high affinity and selectivity toward myosin II [Kovács et al. (2004) J. Biol. Chem. 279, 35557-35563], seem to overlap at least partly.