Primary antibody-Fab fragment complexes: a flexible alternative to traditional direct and indirect immunolabeling techniques.

Immunolabeling with immune complexes of primary and secondary antibodies offers an attractive method for detecting and quantifying specific antigen. Primary antibodies maintain their affinity for specific antigen after labeling with Fab fragments in vitro. Incubation of these immune complexes with excess normal serum from the same species as the primary antibody prevents free Fab fragments from recognizing immunoglobulin. Effectively a hybrid between traditional direct and indirect immunolabeling techniques, this simple technique allows primary antibodies to be non-covalently labeled with a variety of reporter molecules as and when required. Using complexes containing Fab fragments that recognize both the Fc and F(ab')2 regions of IgG, we show that this approach prevents nonspecific labeling of endogenous immunoglobulin, can be used to simultaneously detect multiple antigens with primary antibodies derived from the same species, and allows the same polyclonal antibody to be used for both antigen capture and detection in ELISA.     

Immunoregulation by antigen/antibody complexes. I. Specific immunosuppression induced in vivo with immune complexes formed in antibody excess

Specific immune complexes, prepared at different ratios of antibody to antigen, were examined for their effects on the antibody response of BALB/c mice to the cell wall polysaccharide antigen (PnC) extracted from Streptococcus pneumonia R36a. Mice immunized with complexes formed in antigen excess developed a PnC-specific antibody response that was equivalent to that in mice injected with free antigen. On the other hand, mice injected with complexes formed in antibody excess developed very little PnC-specific antibody. Furthermore, administration of immune complexes (formed in antibody excess) resulted in suppression of the response to an immunogenic dose of PnC given concurrently or 1 day after injection of immune complexes but not when the antigen was given 1 day before injection of the immune complexes. Injections of free antibody (TEPC-15) also resulted in suppression of the response to antigenic challenge; however, suppression was greatest when the antibody was injected concurrently with the antigen, suggesting that the suppression was mediated through the formation of immune complexes in vivo. The suppression appears to be specific for the antigen (PnC), since in mice injected with TEPC-15/PnC complexes (formed in antibody excess) and challenged with PnC coupled to sheep RBC, only the response to PnC was suppressed.     

Role of immune complexes in the humoral leukocyte adherence inhibition test

Summary The humoral leukocyte adherence inhibition (H-LAI) assay has recently been found to measure an antitumor immunefactor. In this assay, trypsinized leukocytes from control persons are used as indicator cells and 0,25% serum from the patient is added to the assay system together with the relevant tumor antigen.In the present work, evidence is presented that the H-LAI response is mediated through in vitro-formed immune complexes. Different antibody-antigen pairs (anti-albumin — albumin; anti-₂microglobulin — ₂microglobulin; anti-carcinoembryonic antigen — carcinoembryonic antigen; anti-transferrin — transferrin) have been added to the assay mixture. A significant H-LAI response was observed when immune complexes were formed. On the other hand, when unrelated antibody — antigen pairs were added, no response was found. The specificity was demonstrated in experiments where two different antibodies were added simultaneously and the response tested both against the two corresponding antigens and against unrelated antigens.Since the same trypsinized indicator cells can be used for different immune complexes, it is likely that the response is mediated through common receptors on the cell surface with affinity for immune complexes, i.e., Fc-receptors. Presumably, the H-LAI test gives response to immune complexes in general and is as such not specific. The specificity is achieved through the addition of specific antigen and the subsequent in vitro formation of immune complexes.     

The labeled antigen method of immunoenzymatic staining.

A two stage immunohistological technique (the "labeled antigen" procedure) has been assessed for the detection of a variety of human and animal cytoplasmic constituents in tissue sections. In this method specific antiserum is followed by antigen complexed to horseradish peroxidase or to alkaline phosphatase. The primary antibody acts bivalently, linking the labeled antigen to antigen in the tissue section. The major advantage of this technique is that nonantigen specific antibody in the primary antiserum cannot cause nonspecific staining since it has no affinity for the antigen:enzyme complex. Consequently the specificity of the reaction is assured, background staining is minimized and the total staining time (from wax section to mounted slide) can be reduced to as little as 30 min. Further advantages include the possibility of labeling Ig allotypes and the high efficiency of enzyme utilization. Covalent human IgG:horseradish peroxidase complexes can also be used in a triple sandwich in conjunction with human anti-viral or autoimmune antibodies.     

Antigen-antibody dissociation in Alzheimer disease: a novel approach to diagnosis

With the ever-increasing population of aged individuals at risk of developing Alzheimer's disease (AD), there is an urgent need for a sensitive, specific, non-invasive, and diagnostic standard. The majority of efforts have focused on auto-antibodies against amyloid-β (Aβ) protein, both as a potential treatment, and a reliable biomarker of AD pathology. Naturally occurring antibodies against Aβ are found in the CSF and plasma of patients with AD as well as healthy control subjects. To date, differences between diseased and control subjects have been highly variable. However, some of the antibody will be in preformed antigen–antibody complexes and the extent and nature of such complexes may provide a potential explanation for the variable results reported in human studies. Thus, measuring total amounts of antigen or antibody following unmasking is critical. Here, using a technique for dissociating antibody–antigen complexes, we found significant differences in serum antibodies to Aβ between AD and aged-matched control subjects. While the current study demonstrates the relevance of measuring total antibody, bound and unbound, against Aβ in AD, this technique may be applicable to diseases such as acquired immune deficiency syndrome and hepatitis B where determination of antigen and antibody levels are important for disease diagnosis and assessing disease progression.     

Immune complexes that contain HIV antigens activate peripheral blood T cells

Uninfected donor T cells were treated in vitro by model immune complexes that contained either HIV or hepatitis C virus (HCV) antigens. Unlike HCV antigen-containing complexes, the immune complexes that contained HIV antigens have been shown to activate peripheral blood T cells of uninfected donors under in vitro conditions. Both the antiviral antibodies and HIV antigen were involved in the activation process. The unique properties of the immune complexes formed by HIV antigens and antiviral antibodies are believed to result from the virus-specific antibody properties and molecular conformation of the antigen–antibody complex.     

Idiotype-restricted antibody response to specific immune complexes

In this report, we compared the immunogenicity of specific antigen/antibody complexes with that of free antigen. The complexes were prepared in antigen excess using the TEPC-15 myeloma protein and a phosphorylcholine-containing polysaccharide antigen (PnC), and the PnC-specific antibody response was measured using a hemolytic plaque assay 5 days after immunization. The results showed that the complexes were as immunogenic as the free antigen; however, the PnC-specific antibody response induced with the complexes was completely dominated by one particular idiotope (defined by plaque inhibition with the AB1-2 monoclonal antibody). On the other hand, the response of mice immunized with free antigen (PnC) was dominated to a lesser degree by the AB1-2 idiotope, and there was a great degree of variability in idiotope expression among individual mice. The results suggest that immunization with antigen/antibody complexes restricts the response to the expression of idiotopes that are present in the immune complex.     

Evaluation of chemotherapy in experimental toxocarosis by determination of specific immune complexes

Parasitism by the larval phase of Toxocara canis is a chronic process in which the larvae survive in the tissues, resulting in the constant stimulation of the immune system. As a result, the detection of specific antibodies may not reflect the active state of the parasite. We have studied the dynamics of the production of specific immune complexes by ELISA with the monoclonal antibody TC-1 in rabbits inoculated with single and multiple doses of T. canis eggs. We also compared this with the production of specific antibodies and their possible modification after treatment with mebendazole. The specific antibodies against excretory-secretory antigen were detected with peaks at 10 and 12 weeks depending on the dose and remained positive during the entire experiment (62 weeks). Treatment caused an increase in the level of detectable antibodies dropping to similar levels to the controls. Specific immune complexes were detected only in multiple doses, and were then positive during the entire experiment. From the beginning of treatment the values of immune complexes fell quickly, remaining at undetectable levels during the rest of the experiment. For this reason the detection of specific immune complexes is a valid technique for monitoring the efficiency of treatment.     

Influenza virus-induced immune complexes suppress alveolar macrophage phagocytosis

Immune complexes in the lungs are capable of inducing adverse responses. Herein we have detailed the formation of immune complexes in the lungs of influenza virus-infected mice and examined their effect on alveolar macrophage defenses. On days 3, 7, 10, 15, and 30 after aerosol infection with influenza A/PR8/34 virus, the acellular pulmonary lavage fluid was tested for viral antigen, specific viral antibody, and immune complexes by immunoassays. Whereas peak viral antigen (day 3) diminished to undetectable levels by day 10, specific viral antibody remained at a low concentration until day 10, after which it rapidly increased. Immune complex concentrations increased through day 7, peaked at day 10, and gradually returned to the control level by day 30. These data demonstrate that immune complexes of detectable size are induced by influenza virus infection during the interface between antigen excess and antibody excess conditions. Since alveolar macrophages are the pivotal phagocytic defense cells in the lung, the ability of normal alveolar macrophages to ingest opsonized erythrocytes was quantitated in the presence of immune complexes from lavage fluid. Immune complexes from day 10 virus-infected lungs caused a dose-dependent suppression of antibody-mediated phagocytosis to 30% of control values. In contrast, although these immune complexes also markedly decreased the phagocytosis of antibody-coated yeast cells, they did not significantly impair the antibody-independent ingestion of unopsonized yeast cells by macrophages. the suppressive effects of immune complexes on alveolar macrophages may, in part, explain the phagocytic dysfunction that occurs 7 to 10 days after influenza virus pneumonia.     

Antigen Binding to Secretory Immunoglobulin A Results in Decreased Sensitivity to Intestinal Proteases and Increased Binding to Cellular Fc Receptors

In intestinal secretions, secretory IgA (SIgA) plays an important sentinel and protective role in the recognition and clearance of enteric pathogens. In addition to serving as a first line of defense, SIgA and SIgA·antigen immune complexes are selectively transported across Peyer''s patches to underlying dendritic cells in the mucosa-associated lymphoid tissue, contributing to immune surveillance and immunomodulation. To explain the unexpected transport of immune complexes in face of the large excess of free SIgA in secretions, we postulated that SIgA experiences structural modifications upon antigen binding. To address this issue, we associated specific polymeric IgA and SIgA with antigens of various sizes and complexity (protein toxin, virus, bacterium). Compared with free antibody, we found modified sensitivity of the three antigens assayed after exposure to proteases from intestinal washes. Antigen binding further impacted on the immunoreactivity toward polyclonal antisera specific for the heavy and light chains of the antibody, as a function of the antigen size. These conformational changes promoted binding of the SIgA-based immune complex compared with the free antibody to cellular receptors (FcαRI and polymeric immunoglobulin receptor) expressed on the surface of premyelocytic and epithelial cell lines. These data reveal that antigen recognition by SIgA triggers structural changes that confer to the antibody enhanced receptor binding properties. This identifies immune complexes as particular structural entities integrating the presence of bound antigens and adds to the known function of immune exclusion and mucus anchoring by SIgA.     

Ultrastructural visualization of virus-induced surface antigens. Comparative studies of three immunohistochemical techniques.

Three immunohistochemical techniques used for ultrastructural localization of cell surface antigens were compared with respect to ease of reagent preparation and qualitative aspects of cell surface staining. The techniques compared were: (a) ferritin-conjugated antibody, (b) "hybrid" antibody and (c) a modification of the "bridging" technique which employs soluble immune complexes. Used in conjuction with strain MC29 avian oncornavirus-infected chick embryo cells and chicken antiviral immune serum, the results of all three techniques were comparable. In terms of ease of preparation, the "bridging" technique employing soluble complexes was found to be the most satisfactory.     

Removal of glomerular deposits induced by either preformed immune complexes or by a chronic immune complex model in NZB/W mice

The solubilization and removal of defined glomerular immune complex deposits by excess antigen was examined in NZB/W female mice. Glomerular deposits were induced by administering preformed immune complexes to young (2 to 4 mo) mice before they naturally acquired deposits from endogenous disease and to old (7 mo) mice with deposits from naturally acquired disease. The administration of excess antigen specifically removed deposits of preformed immune complexes in both groups. This was associated with a reduction in circulating large latticed complexes containing more than two antigen and two antibody molecules (greater than Ag2Ab2). Established deposits in old mice therefore did not interfere with removal of newly induced deposits of preformed immune complexes. Glomerular deposits were also induced in young mice by a chronic human serum albumin (HSA) immune complex model. The antigen in immune deposits induced by 2 wk of chronic antigen administration was solubilized and was removed within 48 hr of administering excess antigen. Circulating antibodies to the antigen were also reduced by excess antigen. Glomerular deposits of mouse immunoglobulin and complement were not significantly reduced by excess antigen but remained more intense than in mice of comparable age given preformed complexes. Thus deposits of other antigen antibody systems and possibly endogenous disease were induced by the chronic HSA immune complex model in NZB/W mice. However, defined antigen deposits within deposits containing multiple antigen antibody systems can clearly be removed by administering excess antigen.     

Immune complex receptors on cell surface. I. Ultrastructural demonstration of macrophages.

A method is described for ultrastructural localization of immune complex receptors on the surface of viable peritoneal exudate cells. The technique entails incubation with a soluble complex of horseradish peroxidase (HRP) and specific antibody to HRP at 4 degrees C followed by exposure to diaminobenzidine and processing for electron microscopy. The bound immune complexes were evident as focal deposits of HRP reaction product, adhering closely to the external surface of macrophages with an uninterrupted periodicity varying between 30 and 120 nm. Following incubation with an insoluble immune complex containing a higher proportion of antibody, receptor sites stained frequently, but large aggregates adhered to the cells. Rinsing cells after staining with soluble complexes partially displaced the bound immune complexes. Fixation prior to exposure to immune complexes largely eliminated the binding capacity of the immune complex receptors.     

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.     

Immune deposits formed in situ by a monoclonal antibody recognizing a new intrinsic rat mesangial matrix antigen

We describe a unique mesangial matrix component of the rat glomerulus identified by a murine monoclonal antibody. The antigen is present exclusively in the glomerular mesangium and cannot be detected in other rat tissues by indirect immunofluorescence techniques or following pretreatment of tissue sections with acid urea or other nonionic detergents. Specific immunoprecipitation of the solubilized antigen yields a single peptide with an apparent m.w. of 81,000 when analyzed by discontinuous SDS-PAGE. This mesangial matrix component is collagenase resistant and trypsin sensitive. Perfusion of an isolated kidney preparation with this antibody results in direct binding of the mouse immunoglobulin to its mesangial antigen. Passive administration of the monoclonal antibody to Lewis rats results in characteristic electron dense deposits within the mesangial matrix that can be visualized ultrastructurally as early as 3 days. The immune deposits form without the activation of rat complement and persist for longer periods than those that develop after the planting of aggregated proteins or preformed immune complexes. Experimental animals that received either a monoclonal antibody specific for laminin or a non-kidney binding preparation did not develop such immune deposits at any time during the course of the autologous phase of the immune process. The results obtained in this study indicate that electron dense immune deposits can develop in the mesangium with the participation of a unique intrinsic matrix component and specific circulating monoclonal antibodies by an in situ mechanism of immune complex formation.     

Antibody-mediated cell cytotoxicity in a defined system: regulation by antigen, antibody, and complement.

The use of a serum-free environment and target cells carrying defined amounts of radiolabeled antigen allowed a quantitative study of the role of antigen, antibody, and complement on antibody-mediated cell cytotoxicity (AbMC). For lysis to occure, a minimum number of antigen molecules must be present on the target cell. 51Cr release from target cells with lower antigen density requires larger concentration of effector cells and antibodies. Target cell-bound complement, itself unable to mediate cytotoxicity, reduces the number of IgG molecules required for lysis. The antibody and complement, however, have to be bound to the same target cell. Bystander complement-coated erythrocytes, present in the same reaction mixture with IgG-coated targets, are not lysed. Blocking of AbMC is effected only by antigen, either soluble or in immune complexes prepared in antigen excess. Antigen competes at the level of the target cell. Blocking at the level of the effector cell, by use of immune complexes prepared at equivalence or in antibody excess, is difficult to achieve. The large number of cells with Fc receptors contained in mouse spleens may explain this finding. Arming of effector cells by passive binding of immune complexes is poorly effective as a means of obtaining lysis of the target cells. In all situations, the outcome of the reaction is determined by the presence of free antibody-combining sites, alone, or in immune complexes, that are able to combine with the target cell membrane antigen. The requirements for lysis are rather stringent.     

Immune reactions in polysaccharide media. The composition of the antigen–antibody complexes in the precipitin reaction

The precipitin reaction is enhanced in the presence of polysaccharides (Hellsing, 1966). This reaction has now been studied in detail with labelled antigen ((125)I-labelled human serum albumin) and antibody ((131)I-labelled rabbit anti-albumin immunoglobulin G). The relative proportions of antigen and antibody in the precipitates are unchanged by the addition of dextran in spite of the increased precipitation. The ratio of antibody to antigen in the soluble immune complexes decreases with increasing polysaccharide concentration. This can be interpreted as a decrease in the aggregate size of the complexes. At the same time the amount of free antigen in the solution increases. The results are consistent with a decrease in solubility, primarily of the large immune aggregates, together with a shift in the equilibrium between small and large complexes. The effect is in accord with a steric-exclusion phenomenon.     

Detection of circulating immune complexes by the enzyme-linked immunosorbent assay in sera from cattle infected with Fasciola hepatica

Polyethylene glycol-precipitated immune complexes (PIC) from the sera of 5 calves with Fasciola hepatica worm burdens ranging between 27 and 70 flukes were examined for parasite antigen content at 2, 4, 6, 8, 10, and 16 wk postinfection (PI) by the enzyme-linked immunosorbent assay (ELISA). Three assays were devised using an affinity-processed rabbit antibody to worm excretory/secretory (FhES) antigens. The PIC plate assay detected parasite antigen by adherence of anti-FhES antibody to PIC incubated overnight on ELISA plates, and tests were visualized using anti-rabbit peroxidase-linked antibody. The serum complex and PIC capture assay utilized the anti-FhES immunoglobulin as an antigen capture antibody linked to the solid phase. The attached complexes were then detected by the adhering bovine antibody, either soluble complexes in serum or as PIC. All assays showed circulating immune complex (CIC) values elevated at 6-8 wk PI, which generally coincided with increased host circulating antibody to FhES antigens. The greatest detection rate for all of the immune complex (IC) detection assays occurred with the PIC capture assay. It detected antigen in almost 90% of sera tested at 6 and 8 wk PI. Both the serum complex and PIC capture assay detected greatest amounts of CIC in those animals with the largest worm burdens, whereas the PIC plate assay showed no such trend. This study shows that F. hepatica antigen detection in CIC can be used to aid immunologic diagnosis of fascioliasis.     

Production of auto-anti-idiotypic antibody during the normal immune response. XII. Enhanced auto-anti-idiotypic antibody production as a mechanism for apparent B-cell tolerance in rabbits after feeding antigen

Rabbits fed trinitrophenylated bovine serum albumin (TNP-BSA) generated fewer anti-TNP plaque-forming cells but greater numbers of hapten (TNP)-augmentable IgM and IgG PFC following immunization with TNP-Ficoll or TNP-Brucella abortus than did animals not previously fed antigen. Spleen and mesenteric and bronchial lymph nodes were similarly affected. In addition more auto-anti-idiotype (Id) antibody (anti-anti-TNP) was eluted by hapten from spleen cells of antigen-fed rabbits than from spleen cells of control rabbits not prefed antigen. Gel filtration studies ruled out the possibility that the Id binding activity in the eluates was due to immune complexes. The isotype of the anti-Id was IgG except in one rabbit where it was IgM. The results are consistent with the interpretation that the production of auto-anti-Id antibody is one of the factors responsible for the specific depression of the IgM and IgG immune responses which follows antigen feeding. In contrast the antigen feeding resulted in priming for an IgA anti-TNP response without detectable hapten-augmentable IgA PFC.     

Inhibition of immune precipitation by complement

Normal human complement serum (NHS) inhibited precipitin reactions between tetanus toxoid and human or rabbit anti-tetanus toxoid IgG antibody, between bovine serum albumin (BSA) and rabbit anti-BSA IgG antibody, and between hen egg albumin and rabbit anti-egg albumin IgG antibody. Ethylene-diaminetetraacetic acid (EDTA) prevented this inhibition. Mg-ethyleneglycol-bis(aminoethyl)-tetra-acetic acid-(EGTA) also prevented the inhibition except with lower concentrations of antibody and antigen. Therefore, the inhibition of immune precipitation seemed to occur mainly through the classical pathway of complement activation. The alternative pathway was usually dispensable, but it augmented the inhibition. Guinea pig complement serum (NGS) was less effective than NHS in inhibiting immune precipitation. Guinea pig serum deficient in C4 (C4DGS) did not inhibit the immune precipitation. Mouse complement serum was effective for inhibiting precipitation, and C5-deficient serum was as effective as normal serum. Therefore, the inhibition of immune precipitation is considered to occur by activation of complement up to the step of C3. The size of the soluble immune complexes formed in the presence of NHS varied depending on the concentrations of antibody and antigen, even when the ratio of antigen to antibody was constant. On incubation at 37 degrees C immune precipitation was inhibited by 1/2 dilution of NHS for 2 to 3 hr and then gradually increased to the level in the absence of complement. When the immune complexes were formed in the presence of serum containing complement, fragments of C4 and C3 were incorporated into the soluble immune complexes. The C3 fragments incorporated into the soluble complexes were C3b, iC3b, C3c, and C3d, some of which were bound covalently with heavy chains of IgG antibody molecules. Some of the covalent linkages between C3 fragments and IgG seemed to be destroyed by alkali treatment, but not by hydroxylamine treatment. The formation of covalent bonds between IgG and C3 and probably C4 was essential for inhibition of immune precipitation, because inhibitors of their formation, such as putrescine, cadaverine, and salicylhydroxamic acid, effectively prevented the inhibition of precipitation. When antigen and antibody reacted in the presence of mixtures of various combinations of isolated complement components, C1, C4, C2, and C3 showed maximal inhibition of immune precipitation, whereas factors I and H had little effect.