Carl-Wilhelm Vogel

A nonhuman primate model for the selective elimination of CD8+ lymphocytes using a mouse-human chimeric monoclonal antibody

Nonhuman primates provide valuable animal models for human diseases. However, studies assessing the role of cell-mediated immune responses have been difficult to perform in nonhuman primates. We have shown that CD8+ lymphocyte-mediated immunity in rhesus monkeys can be selectively eliminated using the mouse-human chimeric anti-CD8 monoclonal antibody cM-T807. In vitro, this antibody completely blocked antigen-specific expansion of cytotoxic T cells and decreased major histocompatibility complex class I-restricted, antigen-specific lysis of target cells but did not mediate complement-dependent cell lysis. In vivo administration of cM-T807 in rhesus monkeys resulted in near total depletion of CD8+ T cells from the blood and lymph nodes for up to 6 weeks. This depletion was not solely complement-dependent and persisted longer in adults than in juveniles. Preservation of B cell and CD4+ T cell function in monkeys depleted of CD8+ lymphocytes was demonstrated by their ability to develop humoral immune responses to the administered chimeric monoclonal antibody. Furthermore, during CD8+ lymphocyte depletion, monkeys developed delayed-type hypersensitivity reactions comprised only of CD4+ T cells but not CD8+ T cells. This CD8+ lymphocyte depletion model should prove useful in defining the role of cell-mediated immune responses in controlling infectious diseases in nonhuman primates.

Depletion of the C3 component of complement enhances the ability of rituximab-coated target cells to activate human NK cells and improves the efficacy of monoclonal antibody therapy in an in vivo model

Growing evidence indicates antibody-dependent cellular cytotoxicity (ADCC) contributes to the clinical response to monoclonal antibody (mAb) therapy of lymphoma. Recent in vitro analysis suggests C3b can inhibit mAb-induced natural killer (NK)-cell activation and ADCC. Further studies were conducted to assess the effect of C3 depletion on mAb-induced NK activation and therapy of lymphoma. Normal human serum inhibited the ability of rituximab-coated lymphoma cells to activate NK cells as previously reported. Serum did not inhibit NK-cell activation when it was preincubated with cobra venom factor (CVF) to deplete C3. Similar results were found when transudative pleural fluid or nonmalignant ascites was used as surrogates for extravascular fluid, suggesting the inhibitory effect of complement may be present in the extravascular compartment, in which many malignant lymphocytes reside. In vivo, C3 was depleted before mAb treatment in a syngeneic murine model of lymphoma. Survival of lymphoma-bearing mice after treatment with CVF plus mAb and with a human C3 derivative with CVF-like functions (HC3-1496) plus mAb was both superior to that of mAb alone. These studies show that complement depletion enhances NK-cell activation induced by rituximab-coated target cells and improves the efficacy of mAb therapy in a murine lymphoma model.

Cobra venom factor: Improved method for purification and biochemical characterization☆

A method to purify cobra venom factor (CVF) from cobra venom by sequential column chromatography is described which yields a product virtually free of phospholipase A2, a common contaminant of CVF preparations. The separation of phospholipase A2 from CVF was achieved by chromatography on Cibacron blue-agarose, a resin that tightly binds cobra venom phospholipase A2. A rapid and simple hemolytic assay for the qualitative and quantitative determination of CVF based on its ability to induce bystander lysis of erythrocytes has been devised. CVF was isolated from the venom of the Naja naja kaouthia subspecies and some of its biochemical properties and physicochemical parameters were delineated.

Cobra venom factor: Structure, function, and humanization for therapeutic complement depletion.

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. This manuscript reviews the structure and function of CVF, how it interacts with the complement system, the structural and functional homology to complement component C3, and the use of CVF as an experimental tool to decomplement laboratory animals to study the functions of complement in host defense and immune response as well as in the pathogenesis of diseases. This manuscript also reviews the recent progress in using the homology between CVF and C3 to study C3 structure and function, and to develop human C3 derivatives with the complement-depleting function of CVF. These human C3 derivatives represent humanized CVF, and are a conceptually different concept for pharmacological intervention of the complement system, therapeutic complement depletion. The use of humanized CVF for therapeutic complement depletion in several pre-clinical models of human diseases is also reviewed.

A continuous flow immunoassay for rapid and sensitive detection of small molecules

An immunosensor operating in continuous flow and capable of detecting low molecular weight antigens is described. The approach differs from previously described continuous flow assays by not requiring incubation steps or the introduction of additional reagents following the loading of the sample into the system. Detection of the antigen is rapid, occurring within 3 min in the system described. The assay is based on the binding of labeled antigen to an immobilized antibody, with subsequent displacement of the labeled antigen when antigen is present in the buffer flow. Signal detection occurs downstream of the antigen recognition event. In this study, the hapten 2,4-dinitrophenol (DNP) as DNP-lysine was used as model antigen. To generate a labeled antigen, DNP was coupled to the terminal amino group of insulin A chain (tetra S-sulfonate form) which provides two tyrosine residues for the introduction of an 125I-label (DNP-Ins-125I) or three carboxyl groups for the attachment of three fluorescein residues (DNP-Ins-Fl). The radiolabeled antigen was used to establish assay conditions. Subsequently, fluorescein was substituted for the radioisotope label in order to develop an assay independent of the restrictions associated with isotopes. Using this flow immunoassay, we were able to detect DNP-lysine down to a detection limit of 143 nM (29 pmol/200 microliters) using DNP-Ins-125I or DNP-Ins-Fl as labeled antigen. The density of immobilized antibody and the flow rate were identified to be critical parameters for the sensitivity of the assay.

A carbohydrate-directed heterobifunctional cross-linking reagent for the synthesis of immunoconjugates☆

A novel, highly water-soluble, heterobifunctional cross-linking reagent, S-(2-thiopyridyl)-L-cysteine hydrazide (TPCH), was synthesized which contains a hydrazide moiety for coupling to aldehyde groups generated in the carbohydrate residues of antibodies by mild periodate oxidation, and a pyridyl disulfide moiety for coupling to molecules with a free sulfhydryl group. Since the carbohydrate moieties are distal to the antigen binding region of antibodies, derivatization with this cross-linker minimizes impairment of the antigen binding function. Derivatization of the human monoclonal IgM antibody 16-88 against human colon carcinoma cells with as many as 16 TPCH cross-linker molecules did not impair its antigen binding capability. Using mild oxidation conditions for antibody derivatization, sialic acid residues were identified as attachment sites for the cross-linker molecules, since after desialylation of antibody 16-88 by neuraminidase virtually no cross-linker molecules could be incorporated. Comparison of TPCH with S-(2-thiopyridyl)mercaptopropionic acid hydrazide and S-(2-thiopyridyl)-L-cysteine, two related cross-linking reagents, revealed that TPCH is most efficiently incorporated into periodate-treated antibody. Based on the structural differences of the cross-linkers, the more efficient incorporation of TPCH appears to be a function of the presence of a hydrazide moiety with an adjacent amino group. When three to four molecules of pyridyl disulfide-derivatized barley toxin were coupled to TPCH-derivatized antibody 16-88, the antigen binding capability remained uncompromised. In addition, no significant impairment of toxin activity upon coupling to the antibody was observed. Based on these data, TPCH may be very useful for the synthesis of immuno-conjugates with no or only minimal impairment of the antigen binding function.

Insights into complement convertase formation based on the structure of the factor B-cobra venom factor complex.

Immune protection by the complement system critically depends on assembly of C3 convertases on the surface of pathogens and altered host cells. These short‐lived protease complexes are formed through pro‐convertases, which for the alternative pathway consist of the complement component C3b and the pro‐enzyme factor B (FB). Here, we present the crystal structure at 2.2‐Å resolution, small‐angle X‐ray scattering and electron microscopy (EM) data of the pro‐convertase formed by human FB and cobra venom factor (CVF), a potent homologue of C3b that generates more stable convertases. FB is loaded onto CVF through its pro‐peptide Ba segment by specific contacts, which explain the specificity for the homologous C3b over the native C3 and inactive products iC3b and C3c. The protease segment Bb binds the carboxy terminus of CVF through the metal‐ion dependent adhesion site of the Von Willebrand factor A‐type domain. A possible dynamic equilibrium between a ‘loading’ and ‘activation’ state of the pro‐convertase may explain the observed difference between the crystal structure of CVFB and the EM structure of C3bB. These insights into formation of convertases provide a basis for further development of complement therapeutics.

Immune and nonimmune effector functions of IgG3 mouse monoclonal antibody R24 detecting the disialoganglioside GD3 on the surface of melanoma cells

R24, an IgG3 mouse monoclonal antibody reactive with the disialoganglioside GD3, was found to be a potent mediator of human complement cytotoxicity and human effector cell cytotoxicity. Cytotoxicity correlated with the degree of antibody binding (GD3 cell surface expression) for each of the melanoma cell lines and melanocyte cell cultures tested. Melanoma cell lines binding low amounts of R24 (low GD3 cell surface expressors) were not lysed in R24-directed immune reactions, suggesting that a threshold number of R24 molecules bound per cell is necessary to initiate these cytotoxic mechanisms. Since both complement- and cell-mediated reactions lysed the same subpopulations of cells in each cell line, both mechanisms appeared to depend on similar threshold quantities of bound R24 molecules. However, due to the heterogeneity of R24 binding in each cell line, the numerical value for this threshold could not be determined. Only in cell lines binding greater than 10(7) R24 molecules per cell were greater than 90% of the cells lysed. Normal melanocytes in culture were not lysed by R24-directed immune mechanisms, due to their low GD3 expression, indicating that monoclonal antibodies such as R24 may show tumor specificity with regard to effector functions even though normal cells express the relevant antigen. In contrast to the potent in vitro activity of R24, treatment of nu/nu mice bearing human melanoma grafts resulted in tumor inhibition only when started within 3 days of tumor cell inoculation. No effect was seen on established tumors. Thus, this in vivo mouse model failed to predict the clinical and pathological findings observed in treatment trials of R24 in human melanoma patients--urticaria involving skin metastases, cellular infiltration of tumor tissue, and tumor regression. In addition to activating immunologic effector functions, R24 had direct effects on melanoma cells, blocking their ability to attach to surfaces and causing tumor cell aggregation. These effects were again related to the number of R24 molecules bound to the cell surface; no aggregation was seen with cell lines binding less than 4 X 10(5) molecules per cell. Both immune and nonimmune effector functions may be involved in the tumor inhibitory activity of R24 in humans.

Structure and Function of Cobra Venom Factor, the Complement-Activating Protein in Cobra Venom

Cobra Venom Factor (CVF) is an unusual venom component known to be present in the venom of the cobra species Naja, Ophiophagus, and Hemachatus of the Elapidae family (1). CVF is not a toxin in the classical sense. As a matter of fact, the purified molecule is not toxic. It specifically interacts with components of the serum complement system, leading to complement activation which in turn leads to the consumption of complement activity.

A homogeneous immunoassay for the mycotoxin T-2 utilizing liposomes, monoclonal antibodies, and complement

The trichothecene mycotoxin T-2 is a fungal metabolite known to contaminate agricultural products and cause intoxication of humans and animals. We have developed a homogeneous competition inhibition assay for T-2 mycotoxin based on complement-mediated lysis of liposomes. The T-2 mycotoxin was converted to an acid chloride derivative, subsequently coupled to the amino group of phosphatidylethanolamine, and incorporated with the phospholipid into unilamellar liposomes. Carboxyfluorescein, which is self-quenched at high concentrations, was entrapped in the liposomes as a release marker. We used a monoclonal IgG1 antibody specific for T-2 mycotoxin and a polyclonal anti-mouse Ig as a secondary antibody since the anti-T-2 IgG1 does not activate complement. In the absence of free T-2, the liposomes were lysed within 30 min after the addition of complement, releasing carboxyfluorescein into the surrounding buffer. In the presence of free T-2 toxin, the binding of antibodies to the liposomes was reduced, causing a corresponding decrease in lysis. This assay proved to be sensitive to T-2 toxin levels as low as 2 ng, which is 10-fold more sensitive than the present enzyme immunoassay using the same antibodies.