Bispecific antibody-mediated destruction of Hodgkin's lymphoma cells.

CD30 is a molecule that is overexpressed on the surface of Hodgkin's lymphoma cells. Therefore, CD30 represents a potential candidate for immunotherapy. In this study, we report the in vitro results of two bispecific molecules (BSMs) that target CD30 to trigger molecules expressed on myeloid effector cells. The first BSM is composed of the Fab' fragment of a CD30-specific antibody, Ki-4, chemically linked to the Fab' fragment of the humanized CD64 (FcgammaRI)-specific antibody, H22 (H22xKi-4). In the second BSM, the H22 Fab' is replaced with the Fab' fragment of the CD89 (FcalphaR)-specific, antibody, A77 (A77xKi-4). Both BSMs were able to bind specifically to lymphoma cell lines expressing CD30. In addition, the H22xKi-4 and A77xKi-4 BSMs were shown to bind cells expressing CD64 and CD89, respectively. Both BSMs mediated potent, dose-dependent antibody dependent cell-mediated cytotoxicity (ADCC) of CD30-expressing tumor cell lines when human monocytes were used as effector cells. In addition, freshly prepared polymorphonuclear leukocytes (PMNs) and effector cells in whole blood were able to mediate the ADCC of targets in conjunction with the A77xKi-4 BSM in some, but not all, experiments. Furthermore, we examined the ability of monocyte-derived macrophages (MDMs) to phagocytose CD30-expressing tumor cell lines in conjunction with the BSM. MDM-mediated phagocytosis was significantly enhanced in the presence of both BSMs. These results demonstrate that targeting lymphoma cells via CD30 to the myeloid high affinity Fc receptor for IgG and to the Fc receptor for IgA results in potent in vitro anti-tumor activity.

Targeting weak antigens to CD64 elicits potent humoral responses in human CD64 transgenic mice.

Previous studies have documented that targeting foreign Ags to IgG FcgammaR leads to enhanced Ag-specific responses in vitro and in vivo. However, the ability to overcome immunologic nonresponsiveness by targeting poorly immunogenic Ags to FcgammaR has not been investigated. To address this question in a simple model, we immunized transgenic mice expressing human CD64 (FcgammaRI) and their nontransgenic littermates with Fab' derived from the murine anti-human CD64 mAb m22. The m22 Fab' served as both the targeting molecule and the Ag. We found that only CD64-expressing mice developed anti-Id titers to m22. Furthermore, chemically linked multimers of m22 Fab', which mediated efficient internalization of the human CD64, were significantly more potent than monomeric m22 F(ab')(2) at inducing anti-Id responses. In all cases, the humoral responses were specific for m22 Id and did not react with other murine IgG1 Fab' fragments. Chemical addition of a second murine Fab' (520C9 anti-human HER2/neu) to m22 Fab' multimers demonstrated that IgG1 and IgG2a anti-Id titers could be generated to 520C9 only in the CD64-expressing mice. These results show that targeting to CD64 can overcome immunological nonresponsiveness to a weak immunogen. Therefore, targeting to CD64 may be an effective method to enhance the activity of nonimmunogenic tumor vaccines.

Triggering Fc alpha-receptor I (CD89) recruits neutrophils as effector cells for CD20-directed antibody therapy.

CD20 Abs induce clinical responses in lymphoma patients, but there are considerable differences between individual patients. In (51)Cr release assays with whole blood as effector source, RAJI cells were effectively killed by a mouse/human chimeric IgG1 construct of CD20 Ab 1F5, whereas ARH-77 proved resistant to killing by this Ab. When whole blood was fractionated into plasma, mononuclear cells, or granulocytic effector cells, RAJI cells were effectively killed in the presence of complement-containing plasma, whereas the mature B cell line ARH-77 proved complement resistant. However, with a bispecific Ab (BsAb) against the myeloid receptor for IgA (CD89; FcalphaRI) and CD20, a broad range of B cell lines were effectively killed. FcalphaRI is expressed on monocytes/macrophages, neutrophils, and eosinophils. As the numbers of these effector cells and their functional activity can be enhanced by application of G-CSF or GM-CSF, lysis via (FcalphaRI x CD20) BsAb was significantly enhanced in blood from patients during therapy with these myeloid growth factors. Interestingly, the major effector cell population for this BsAb were polymorphonuclear neutrophils, which proved ineffective in killing malignant B cells with murine, chimeric IgG1, or FcgammaRI- or FcgammaRIII-directed BsAbs against CD20. Experiments with blood from human FcalphaRI/FcgammaRI double-transgenic mice showed corresponding results, allowing the establishment of relevant syngenic animal models in these mice. In conclusion, the combination of myeloid growth factors and an (FcalphaRI x CD20) BsAb may represent a promising approach to improve effector cell recruitment for CD20-directed lymphoma therapy.

Differential effect of cytokine treatment on Fc alpha receptor I- and Fc gamma receptor I-mediated tumor cytotoxicity by monocyte-derived macrophages.

Macrophages represent an important effector cell for Ab-mediated tumor therapy. Previous studies have documented that cytokines can influence Fc receptor (FcR) expression and function. In this study we examined the tumoricidal activities of the type I receptors for IgG (Fc gamma RI) and the IgA FcR (Fc alpha RI) on monocyte-derived macrophages (MDM) cultured in the presence of IFN-gamma, M-CSF, or GM-CSF. Bispecific Abs were used to target a Her2/neu breast carcinoma cell line, SKBR-3, to Fc alpha RI or Fc gamma RI on MDM. Although Fc alpha RI and Fc gamma RI share a common signaling pathway contingent on association with the gamma-chain (FcR gamma subunit), a marked difference in their efficiency in mediating tumoricidal functions was seen in response to specific cytokines. M-CSF- and GM-CSF-treated MDM mediated efficient phagocytosis of SKBR-3 cells by Fc alpha RI and Fc gamma RI; however, IFN-gamma-treated MDM phagocytosed tumor cells only with the Fc gamma RI-directed bispecific Abs. Similarly, IFN-gamma-cultured MDM lysed tumor cells more efficiently via Fc gamma RI then by Fc alpha RI as measured in Ab-dependent cellular cytotoxicity assays. Conversely, GM-CSF-treated MDM mediated more efficient lysis of tumor cells via Fc alpha RI than Fc gamma RI, while M-CSF-cultured MDM were relatively less efficient in mediating Ab-dependent cellular cytotoxicity through either receptor. With the exception of IFN-gamma-mediated enhancement of Fc gamma RI expression and Fc gamma RI gamma-chain complexes, the regulation of Fc gamma RI- or Fc alpha RI-mediated activity occurred without significant change in either receptor expression or total complexes with gamma subunit. These data suggest that the efficiency of Ab-mediated tumor therapy, which depends on FcR effector cell functions, may be modified by the use of specific cytokines.

Development of a trispecific antibody conjugate that directs two distinct tumor-associated antigens to CD64 on myeloid effector cells.

A trispecific F(ab')3 antibody conjugate (TAC) with specificities for the Fc gamma receptor I (Fc gamma RI/CD64), the epidermal growth factor receptor (EGFR) and the HER2/neu antigen has been developed to redirect effector cell-mediated cytotoxicity against cancer cells expressing both or either of the tumor-associated antigens. The TAC was constructed in two steps using the sulfhydryl-specific cross-linker o-phenylenedimaleimide (o-PDM). In step one, a bispecific antibody was prepared by linking the Fab' fragments of mAb m22 (a murine IgG1 specific for Fc gamma RI) and mAb H425 (a humanized IgG1 antibody recognizing EGFR). The conjugation efficiency was about 60%. In the second step, the Fab' fragment of mAb 520C9, a murine IgG1 specific for HER2/neu, was coupled to the bispecific antibody made in step one. About 40% of the bispecific conjugate was derivatized to form the trispecific antibody. The purity of the TAC was more than 90% after gel filtration purification. The TAC was characterized in vitro for its ability to bind specifically to all the three antigens and to kill target cells expressing the tumor antigens. In contrast to bispecific conjugates that can only target cells expressing either of the tumor antigens, the TAC was able to bind both the antigens more efficiently in cell-binding assays and to kill tumor cells expressing EGFR and HER2/neu antigens.

Bispecific molecules directed to the Fc receptor for IgA (Fc alpha RI, CD89) and tumor antigens efficiently promote cell-mediated cytotoxicity of tumor targets in whole blood.

The FcR for IgA (Fc alpha RI, CD89) is primarily expressed on cytotoxic immune effector cells. By chemically cross-linking F(ab') fragments of the FcR for IgA (Fc alpha RI)-specific mAb (A77) with tumor Ag-specific mAb (anti-HER2/neu and anti-epidermal growth factor receptor), we have developed bispecific molecules (BSM) that simultaneously bind to respective tumor Ags and Fc alpha RI-expressing effector cells in whole blood. These BSM mediated up to 55% of specific lysis of appropriate tumor Ag-expressing target cells (from a variety of tumors) with purified polymorphonuclear leukocytes, monocytes, or whole blood effector cells without preactivation with exogenous cytokines. To our knowledge, this is the first demonstration of Ab-dependent cell-mediated cytotoxic activity via Fc alpha RI in whole blood. Also, monocyte-derived macrophages mediated phagocytosis of HER2/neu-expressing tumor cells (>95% tumor cell loss). These BSM-mediated cytotoxic activities were completely inhibited by F(ab')2 of A77, demonstrating the specific role of Fc alpha RI as a trigger molecule. Furthermore, the binding of these BSM to monocytes or polymorphonuclear leukocytes in whole blood did not induce modulation of Fc alpha RI in the absence of the target Ag. Therefore, immune effector cells may be "armed" with Fc alpha RI-directed BSM in whole blood. These Fc alpha RI-directed BSM may offer new treatment options for various malignancies and other disease conditions.

Cytolytic and cytostatic properties of an anti-human Fc gammaRI (CD64) x epidermal growth factor bispecific fusion protein.

A bispecific fusion protein (H22-EGF) that binds simultaneously to the epidermal growth factor receptor (EGF-R) and to the high affinity receptor for the Fc portion of human IgG, Fc gammaRI (CD64), has been successfully constructed and expressed. For this construction, genomic DNA encoding the Fd fragment of humanized anti-Fc gammaRI mAb, H22, which binds Fc gammaRI at an epitope that is distinct from the Fc binding site, was fused to cDNA encoding human epidermal growth factor (EGF), a natural ligand for EGF-R. The resulting H22Fd-EGF-expressing vector was transfected into a myeloma cell line that was transfected previously with a vector containing DNA encoding the H22 kappa-light chain. SDS-PAGE analysis of purified H22-EGF demonstrated that the fusion protein was secreted predominantly as H22Fab'-EGF monomer (approximately 55 kDa), even though a free Cys residue exists in the hinge region of the H22 Fab' component. Using a novel bispecific flow cytometry-binding assay, we demonstrated that the purified bispecific fusion protein, H22-EGF, was able to bind simultaneously to soluble Fc gammaRI and EGF-R-expressing cells. H22-EGF inhibited the growth of EGF-R-overexpressing tumor cells and mediated dose-dependent cytotoxicity of these cells in the presence of Fc gammaRI-bearing cytotoxic effector cells. These results suggest that this fusion protein may have therapeutic utility for EGF-R-overexpressing malignancies.

Influence of the chemical nature of side chain at beta 108 of hemoglobin A on the modulation of the oxygen affinity by chloride ions. Low oxygen affinity variants of human hemoglobin expressed in transgenic pigs: hemoglobins Presbyterian and Yoshizuka.

Hemoglobin A (HbA) and two low oxygen affinity variants of HbA, HbPresbyterian and HbYoshizuka, were produced in transgenic pigs and purified to homogeneity by ion-exchange chromatography. These two variants contain either lysine (HbPresbyterian) or aspartic acid (HbYoshizuka) instead of the normal asparagine residue at position beta 108 in HbA. Transgenic pigs expressed these variants at a level up to 11% and were healthy. Both HbPresbyterian and HbYoshizuka exhibited low O2 affinity (P50 of 21.2 and 18.9, respectively, compared with control HbA value of 11.8 in 0.1 M NaCl, pH 7.5) and retained normal cooperativity with Hill coefficients of 2.9 and 2.5, respectively. HbPresbyterian exhibited Bohr effect comparable with HbA. In contrast, HbYoshizuka had a diminished response to changes in pH. Thus the structural basis of reduced O2 affinity of these variants appears to be distinct: the consequence of mutation at beta 108 is a function of the chemical nature of the side chain. This is further confirmed by the sensitivity of the O2 affinity of the variants to the presence of Cl-. The O2 affinity of HbYoshizuka is insensitive to changes in Cl- concentration, whereas the O2 affinity of HbPresbyterian exhibited a pronounced and dramatic chloride effect. In fact, P50 of HbPresbyterian was identical to that of HbA at very low Cl- concentrations, and the P50 increased to >40 at 0.5 M Cl-. The chloride effect was completely abolished when HbPresbyterian was stabilized at the 2,3-diphosphoglycerate pocket by interdimeric cross-linking. Molecular modeling studies demonstrate that in HbPresbyterian, Cl- can bridge the epsilon-amino group of Lys beta 108 with either the guanidino group of Arg beta 104 or the epsilon-amino group of Lys alpha 99, resulting in the stabilization of the "T" structure. The utility of these low O2 affinity hemoglobins as cell-free oxygen carriers is discussed.