Modification of the Fc region of a primatized IgG antibody to human CD4 retains its ability to modulate CD4 receptors but does not deplete CD4(+) T cells in chimpanzees.

Keliximab, a Primatized IgG1 CD4 mAb, was reconfigured to an IgG4 antibody. The gamma4 constant region was further modified by substituting glutamic acid for serine at position 235 in the CH2 domain (IgG4-E), to remove residual binding to Fcgamma receptors, and substitution of serine with proline at position 228 in the hinge region (IgG4-PE) for greater stability. Pharmacokinetic analysis in rats gave a t(1/2) of approximately 4 days for IgG4-E and 9 days for IgG4-PE, consistent with a greater stability of the IgG4-PE molecule. The effects on T cell subsets were assessed in chimpanzees given escalating doses of IgG4-PE: 0.05 mg/kg on Day 16, 1.5 mg/kg dose on Day 43, and 15 mg/kg on Day 85. Receptor modulation was observed at the two highest doses, but no depletion of T cells at any dose. The in vitro and in vivo results demonstrate the potential of this IgG4-PE mAb for use in human trials.

Future approaches for treating hematologic disease.

The approval of monoclonal antibodies for therapy of hematologic malignacies (Rituxan, Mylotarg, Campath) renewed the interest in antibodies as potential new treatment options for cancer patients. Antibodies are effective in inhibiting tumor cell growth , inducing apoptosis, and activating host effector mechanisms for tumor cell killing. Monoclonal antibodies can be clinically effective as monotherapy, as targeting agents delivering either potent cytotoxic drugs or radionuclides as well as in combination with conventional chemotherapies. Advances in antibody engineering provided new capabilities to reduce immunogenicity, alter half life, increase effector functions, and increase tumor targeting for optimal therapeutic modalities requiring chronic dosing regimens. During the next decade, as new tumor-specific surface antigens are discovered and the linkage between genes and function is better understood, new targets will be identified for regulating tumor cell growth by engineered antibodies with agonist or antagonist activity. Additionally, antibody engineering will allow for more efficient radionuclide or cytotoxic drug targeting or lead to more selective activation of relevant host effector mechanisms, leading to a safe and effective therapy of cancer.

Enhancement of cell-mediated immunity in melanoma patients immunized with murine anti-idiotypic monoclonal antibodies (MELIMMUNE) that mimic the high molecular weight proteoglycan antigen.

The purpose of this study was to determine whether a combination of two anti-idiotypic antibodies that mimic the high molecular weight proteoglycan antigen found on most melanoma tumors was capable of enhancing cellular immunity in vaccinated high-risk patients with melanoma. Twenty-eight stage I-IV high-risk patients with melanoma were immunized with a mixture of variable concentrations of MELIMMUNE-1 and MELIMMUNE-2, along with the adjuvant SAF-m, using two immunization schedules. Peripheral blood mononuclear cells were collected before the first immunization and 4 weeks after the final immunization and tested for in vitro proliferation to MELIMMUNE-1 and MELIMMUNE-2 and for cytotoxicity against 51Cr-labeled target cell lines. Additionally, supernatants from in vitro proliferation cultures were tested for interleukin 10 and IFN-gamma levels. Significant in vitro proliferation to MELIMMUNE-1 and MELIMMUNE-2 were observed in postimmunization samples but not in prevaccination samples. The mean stimulation index for MELIMMUNE-2 (33.7 +/- 0.6) was significantly higher than that for MELIMMUNE-1 (13.9 +/- 0.3; P < 0.025). Supernatants obtained from 78% of the in vitro stimulated cultures pre- or postvaccination contained significant levels of interleukin 10 (range, 0.43-142 pg/ml), whereas IFN-gamma levels were elevated in 53% of postvaccination samples (range, 3-245 pg/ml) but not prevaccination samples. More importantly, we were able to generate specific CTL responses in 43% of the patients, which correlated with elevated IFN-gamma levels. These results indicate that MELIMMUNE enhances cell-mediated immunity in patients with melanoma.

Tumor regression in mice following vaccination with human papillomavirus E7 recombinant protein in PROVAX.

Induction of CD8+ cytotoxic T lymphocytes (CTLs) specific for human papillomavirus (HPV) antigens provides an attractive strategy for immunotherapy of HPV-related cancers in humans. In this study, we investigated the potential of utilizing soluble E7 protein of HPV 16 in an adjuvant formulation, PROVAX as a vaccine against a progressively growing E7 transfected K1735-X21 (H-2k) metastatic melanoma cells (HOPE2) in a mouse model. Vaccination of HOPE2 tumor bearing mice (C3H) with E7 protein in PROVAX resulted in significant inhibition of tumor growth, compared to mice vaccinated with E7 in Alum or saline. In vivo depletion of CD8+ or CD4+ cells indicated that CD8+ cells are the major effector cells in mediating the anti-tumor activity in this model. Furthermore, E7-specific CTL activity in vitro was detected in tumor bearing mice vaccinated with E7-PROVAX. Our studies suggest that recombinant HPV antigens in combination with PROVAX could serve as an effective subunit vaccine to stimulate tumor specific CD8+ T cell mediated immunity against HPV-related cancers.

Effect of linker variation on the stability, potency, and efficacy of carcinoma-reactive BR64-doxorubicin immunoconjugates.

The internalizing anti-Le(y) monoclonal antibody (MAb) BR64 was conjugated to the anticancer drug doxorubicin (DOX) using an acid-labile hydrazone bond to the DOX and either a disulfide or thioether bond to the MAb. The resulting disulfide (BR64-SS-DOX) and thioether (BR64-S-DOX) conjugates were evaluated for stability, potency, and antigen-specific activity in both in vitro and in vivo model systems. The BR64-SS-DOX conjugates demonstrated antigen-specific activity both in vitro and when evaluated against antigen-expressing, DOX-sensitive human carcinoma xenografts. However, the stability and potency of disulfide conjugates were poor, and in vivo activity superior to unconjugated DOX was seen only at doses approaching the maximum tolerated dose. Furthermore, BR64-SS-DOX conjugates were not active against antigen-expressing, DOX-insensitive colon tumor xenografts. In contrast, the BR64-S-DOX conjugates demonstrated good stability both in vitro and in vivo. The increased stability of the BR64-S-DOX conjugates resulted in the delivery of more biologically active DOX to tumors with a concomitant increase in potency and efficacy over that which could be achieved with either unconjugated DOX or BR64-SS-DOX conjugates. Delivery of DOX by BR64-SS-DOX conjugates resulted in complete regressions and cures of both DOX-sensitive lung xenografts and DOX-intensitive colon tumor xenografts. These results demonstrate the importance of linker stability when delivering drugs such as DOX to carcinomas via internalizing antibodies and are likely to have direct relevance to the clinical utility of MAb-directed delivery.

The induction of cytotoxic T cells and tumor regression by soluble antigen formulation.

CTLs specific for tumor antigens play a major role in the immunity against cancer. We have shown that class I-restricted CTLs can be induced by injecting soluble antigens mixed in an antigen formulation (AF) that consists of squalane, Tween 80, and Pluronic L121 (S. Raychaudhuri et al., Proc. Natl. Acad. Sci. USA, 89: 8308-8312, 1992). In this study, using ovalbumin and the ovalbumin-expressing transfectoma (EG7) as a tumor model system, we examined the in vivo antitumor effect of antigen-AF mixture. Vaccination of mice with ovalbumin in AF 2 or 3 days after EG7 tumor challenge showed significant inhibition of tumor growth compared to mice vaccinated with ovalbumin in alum or in saline. Depletion of CD8+ cells at the time of immunization completely abrogated the AF-induced tumor protection, indicating that CD8+ T cells are the major effectors in tumor protection in vivo. Depletion of CD4+ cells led to a marginal loss of tumor protection, which may be the result of inhibition of ovalbumin-specific CTL response due to the lack of T-helper activity. Our results demonstrate that AF can be used in subunit vaccines to stimulate CTLs and tumor regression in vivo.

Granulocyte-macrophage colony-stimulating factor plays a role in the functional activity of mast cells.

A peptide homologous to a region of murine granulocyte-macrophage colony-stimulating factor (mGM-CSF), P27-38, which was shown to be a GM-CSF antagonist, inhibited the function of serotonin release from murine mast cells. Peptide P27-38 inhibited immunoglobulin E (IgE)-mediated serotonin release in a dose-dependent manner when induced by either specific antigen or anti-IgE antibody. In contrast, non-receptor-mediated release of serotonin by agents such as compound 48/80 or the calcium ionophore A23187 were not affected by the GM-CSF antagonist. Similar effects were observed with GM-CSF-neutralizing antibodies. The inhibitory effect of P27-38 and the neutralizing antibodies on serotonin release could be reversed by the addition of exogenous GM-CSF to the stimulated mast cells, indicating that the inhibitory activity was probably due to an effect on endogenously produced GM-CSF. These findings suggest that GM-CSF produced by stimulated mast cells is involved in the regulation of their activity in an autocrine manner.

(6-Maleimidocaproyl)hydrazone of doxorubicin--a new derivative for the preparation of immunoconjugates of doxorubicin.

The (6-maleimidocaproyl)hydrazone of doxorubicin was synthesized and conjugated to several mAbs, including chimeric BR96, via a Michael addition reaction to thiol-containing mAbs. DTT reduction of disulfides present in the mAb was a reliable and general method for generating a consistent number of reactive SH groups. The conjugates, after purification by Bio-Beads, were free of unreacted linker and/or doxorubicin. All conjugates released doxorubicin under acidic conditions that mimic the lysosomal environment, while they were relatively stable at neutral pH. BR96 conjugates showed antigen-specific cytotoxicity.

Identification of functional domains in murine granulocyte-macrophage colony-stimulating factor using monoclonal antibodies to synthetic peptides.

Granulocyte-macrophage (GM)-CSF is an important hematopoietic cytokine that regulates proliferation and differentiation of macrophages, neutrophils, and eosinophils. In this study, we generated mAb to five synthetic peptides that correspond to regions along the murine GM-CSF molecule. The ability of anti-peptide mAb to bind to and inhibit biologic activity of murine (m) GM-CSF was determined. mAb with the highest neutralization titers were derived from mice immunized with peptide II, which correspond to amino acids 27 to 38 of mGM-CSF. Immunochemical studies showed that peptide II specifically blocked binding of anti-peptide II mAb to GM-CSF. mAb to two other peptides in the N-terminal half corresponding to residues 7 to 17 and 47 to 58, respectively, of mGM-CSF also inhibited GM-CSF-dependent proliferation and differentiation of murine bone marrow precursors for macrophages and granulocytes. Anti-peptide mAb also inhibited growth of a murine hematopoietic cell line FDCP1 and a murine T cell line HT-2, which was shown to be dependent on GM-CSF for growth in vitro. Biologic activity of both natural and recombinant mGM-CSF was neutralized by anti-peptide mAb. These findings indicate that epitopes in the N-terminal region of mGM-CSF are important for biologic activity, and the epitope defined by peptide II (residues 27 to 38) lies within a particularly important functional domain of the mGM-CSF molecule.

Determination of immunoreactivity of doxorubicin antibody immunoconjugates by a Le(y) competitive RIA.

Many monoclonal antibody-drug immunoconjugates have been evaluated for their ability to deliver cytotoxic drugs to tumors. It is essential to establish that the ability of the conjugates to bind antigen, i.e. their immunoreactivity, is not adversely affected by the drug conjugation procedure. We have described herein a measurement of the immunoreactivity of BR96-DOX, a conjugate comprised of BR96, a chimeric monoclonal antibody specific for the Le(y) tetrasaccharide commonly expressed on human carcinomas, and doxorubicin, an anticancer agent in widespread clinical use. We have employed a competitive RIA, in which microtiter wells were coated with synthetic Le(y) conjugated to human serum albumin and then incubated with 125I-labeled antibody BR96 in the presence of test conjugate or intact BR96 mAb. The test conjugates were found to compete as effectively as unconjugated BR96. This assay is highly applicable to QC processes with the intra-assay CV = 2.0% and the interassay CV = 4.3%.

Antigen-specific activity of carcinoma-reactive BR64-doxorubicin conjugates evaluated in vitro and in human tumor xenograft models.

The anticarcinoma antibody BR64 was conjugated to a doxorubicin derivative, doxorubicin 13-[3-(2-pyridyldithio)propionyl]hydrazone, and the resulting conjugates (BR64-DOX) were evaluated for activity and immunological specificity in vitro and in human tumor xenograft models. The BR64-DOX immunoconjugates retained immunoreactivity and cytotoxicity and demonstrated antigen-specific cytotoxicity in vitro. The potency of BR64-DOX immunoconjugates in vitro was related to the drug:monoclonal antibody mole ratio of the conjugates. The antitumor activity of BR64-DOX conjugates was consistently superior to the maximal activity obtained with the parent drug, doxorubicin (DOX), in established human lung and human breast carcinoma xenograft models. The superior antitumor activity of BR64-DOX conjugates was reflected both in tumor growth inhibition and in regressions and cures of established tumors following the administration of tolerated doses of BR64-DOX. The antitumor activity of BR64-DOX conjugates was not the result of synergism between monoclonal antibody BR64 and DOX, because mixtures consisting of monoclonal antibody and optimized DOX were not more active than an equivalent dose of DOX administered alone. The antitumor activity of BR64-DOX conjugates was antigen specific; equivalent doses of nonbinding isotype-matched conjugates were not active against established tumor xenografts.

Cytotoxicity of chimeric (human-murine) monoclonal antibody BR96 IgG, F(ab')2, and Fab' conjugated to Pseudomonas exotoxin.

We have made antigen-specific cytotoxic reagents by conjugating the chimeric antibody BR96 (chiBR96) to Pseudomonas exotoxin A (PE), as either native PE or a truncated form (LysPE40) devoid of the cell-recognition region (domain I). PE kills cells by ADP-ribosylation of elongation factor 2, thereby inhibiting protein synthesis. Chimeric BR96 immunotoxins were constructed by chemical conjugation of the toxin to Fab', F(ab')2, and intact IgG and purified by anion-exchange and gel-filtration chromatography. Chimeric BR96 [IgG and F(ab')2] immunotoxins were cytotoxic against tumor cell lines displaying the BR96 antigen, with EC50 values ranging from 0.1 to 110 pM. Immunotoxins constructed with chiBR96 Fab' were 50-100-fold less cytotoxic. Competition analysis showed that the immunotoxins were specifically active through their BR96 antigen-binding ability. The binding of chiBR96-PE and chiBR96-LysPE40 to antigen was equivalent to that of BR96 itself and these immunotoxins were found to internalize very rapidly, displaying 90% of their cytotoxicity within 1 h. Binding assays determined that chiBR96 F(ab')2-LysPE40 bound as well as chiBR96-LysPE40; however, chiBR96 Fab'-LysPE40 bound 20-fold less efficiently. The chiBR96 Fab'-LysPE40 internalized similarly to the F(ab')2 or the IgG immunotoxins. Therefore, the chiBR96 Fab'-LysPE40 immunotoxin is less cytotoxic toward target cells because of reduced antigen binding. This is may be due to the monovalent nature of chiBR96 Fab'-LysPE40. This study shows that the monoclonal antibody chiBR96-Pseudomonas exotoxin A immunotoxins can be effective at inhibiting protein synthesis in target cells.

New hydrazone derivatives of adriamycin and their immunoconjugates--a correlation between acid stability and cytotoxicity.

New N-substituted hydrazine linkers were synthesized and their hydrazone derivatives of adriamycin were prepared. These functionalized adriamycin derivatives were conjugated with a monoclonal antibody, 5E9. The release rate of adriamycin from the hydrazones and from some of the conjugates was studied, and their relationship to the IC50's of the conjugate against 5E9-positive Daudi cells was investigated.

Adriamycin(hydrazone)-antibody conjugates require internalization and intracellular acid hydrolysis for antitumor activity.

Adriamycin hydrazone (ADM-Hzn) immunoconjugates have previously been shown to exhibit antibody-directed antitumor activity in vitro and in vivo. In this report, the biological and biochemical properties of the mAb and linker were investigated. Conjugates prepared with two antibodies 5E9 [anti-(transferrin receptor)] and G28.1 (anti-CD37), (which internalize from the surface of target cells following binding) were more cytotoxic in vitro and had greater antitumor activity against Daudi B lymphoma tumor xenografts than a non-internalizing immunoconjugate prepared with mAb 2H7 (anti-CD20). In addition, the 13-acylhydrazone bond linking the drug to the mAb was labile at pH 5 and released unmodified ADM at a rapid rate (t1/2 = 2.5 h). Immunoconjugates prepared with an oxime linkage at the C-13 position were stable to acid and were not cytotoxic. These findings suggest that internalization of ADM-Hzn immunoconjugates and release of free ADM from the mAb in acidic intracellular compartments were important steps in the mechanism of action of ADM-Hzn immunoconjugates.

Homodimeric forms of bombesin act as potent antagonists of bombesin on Swiss 3T3 cells.

Two Lys3-bombesin dimers were prepared by crosslinking epsilon-amino groups Lys3-bombesin with noncleavable (glutaraldehyde) and cleavable [dimethyl-3,3'-dithiobispropionimidate (DTBP)] crosslinkers. The dimers were purified by HPLC ion-exchange chromatography and were shown to have retained immunoreactivity with an anti-bombesin monoclonal antibody directed against the C-terminal binding region of bombesin. The glutaraldehyde cross-linked bombesin dimer specifically inhibited binding of 125I-GRP to its receptor on Swiss 3T3 cells. Bombesin, at 0.6-60 nM induced mitogenesis in quiescent Swiss 3T3 cells, whereas, incubation of cells with the glutaraldehyde bombesin dimer at concentrations up to 124 nM did not. In competition assays, the bombesin dimer exhibited a dose dependent inhibition of bombesin-induced mitogenic activity and intracellular Ca++ mobilization. The bombesin dimer was 100 to 1000-fold more potent than D-Phe12Leu14-bombesin and D-Phe12bombesin, respectively, in inhibiting bombesin-induced mitogenesis on quiescent Swiss 3T3 cells. Similarly, the DTBP-bombesin dimer was not mitogenic to Swiss 3T3 cells, however, cleavage of the disulfide crosslinker with DTT of cell bound DTBP dimer restored mitogenic activity. Finally, the glutaraldehyde bombesin dimer also inhibited growth of bombesin receptor positive H345 SCLC cells in vitro. These findings suggest that the dimeric forms of bombesin are potent antagonists of bombesin.

Evaluation in vitro of adriamycin immunoconjugates synthesized using an acid-sensitive hydrazone linker.

A novel method for linking Adriamycin (ADM) to monoclonal antibodies is described in which the 13-keto position of the anthracycline is used as the attachment site to the linker arm. A new ADM acylhydrazone derivative, Adriamycin 13-[3-(2-pyridyldithio)propionyl]hydrazone hydrochloride, which contains a pyridyl-protected disulfide, was synthesized and used for conjugation to monoclonal antibodies (MAbs) that were thiolated with N-succinimidyl 3-(pyridyldithiol)propionate or 2-iminothiolane. This resulted in formation of a linker between MAb and drug that contained a disulfide bond. Conjugation conditions were optimized to yield conjugates with high ADM:MAb molar ratios. The final immunoconjugate yields were found to decrease as the ADM:MAb molar ratio of the conjugates increased. Stability studies indicated that ADM was released from the immunoconjugates at mildly acidic pHs ranging from 4.5-6.5. Treatment of immunoconjugates with mild reducing agent dithiothreitol resulted in release of an acylhydrazone derivative of ADM. Flow-cytometric studies showed that the binding activity of various MAbs following conjugation to ADM was preserved at ADM:MAb molar ratios up to 10. Antibody-directed cytotoxicity was demonstrated under several assay conditions using combinations of antigen-positive and antigen-negative cells and binding and nonbinding immunoconjugates. In several experiments, ADM immunoconjugates were more potent than equivalent amounts of unconjugated ADM.

Antitumor activity of adriamycin (hydrazone-linked) immunoconjugates compared with free adriamycin and specificity of tumor cell killing.

Adriamycin (ADM) was chemically coupled to two monoclonal antibodies (MAb) expressed on human B-cell lymphomas. Immunoconjugates were prepared by linking to the MAb an ADM derivative, Adriamycin 13-[3-(2-pyridyldithio)propionyl]hydrazone (ADM-HZN), which releases ADM under mild acidic conditions (see preceding article). The (ADM-HZN) conjugates were tested for antitumor activity on two human B-lymphoma xenografts, Daudi and Ramos, which were growing as solid tumors in athymic mice. The conjugates, injected i.p., significantly inhibited tumor growth when antibody protein doses were greater than or equal to 500 mg/kg (approximately 10 mg/mouse). At these input antibody doses, (ADM-HZN) conjugates were more potent and had greater antitumor activity than free ADM given at an optimized dose and schedule. MAb-conjugated ADM was also tolerated to much higher levels than unconjugated drug. Antitumor activity was not obtained using mixtures of MAb plus free drug or with MAb-drug conjugates that did not bind to the tumor target cell. Thus, the antitumor activity of the immunoconjugate was directed by binding of the MAb portion of the conjugate to target tumor cells.

Monoclonal antibodies directed against rat tracheal epithelial cells transformed in vitro.

Cloned hybridoma cell lines were obtained by fusion of murine myeloma cells with spleen lymphocytes of either F344 rats or BALB/c mice immunized against the malignant F344 tracheal cell line, 2-10-1. Monoclonal antibodies were selected for their ability to bind to the immunizing cell line and not to normal tracheal epithelial cells. Results from quantitative binding assays indicated that such monoclonal antibodies recognized six epitopes. Each epitope was detected on four other malignant tracheal epithelial cell lines, and was also expressed during early preneoplastic cell passages (i.e. before the cells acquired the ability to produce carcinomas in vivo). Quantitative differences in epitope expression between non-tumorigenic and tumorigenic passages of individual cell lines could not be detected for five of the epitope groups. However, two monoclonal antibodies, recognizing the same epitope, did show quantitative binding differences between non-tumorigenic and tumorigenic cell passages on three of the five cell lines tested. Our results show that carcinogen-altered tracheal cell populations can be distinguished from non-altered cells (by our current assay methods) by use of monoclonal antibodies. The suggest that the antigen expression is an early event associated with the transformation of rat tracheal epithelial cells in culture.

Parametric analysis of histograms measured in flow cytometry.

Flow cytometric histograms frequently consist of several components that show various degrees of overlap. For many types of analysis it is of great importance to decompose the original histogram into its components. To that purpose, we investigated the maximum likelihood approach in detail. It is shown that the iterative method to solve the maximum likelihood equations is well behaved for a variety of initial values. Algorithms to obtain initial values are presented, and the performance of the method is tested when applied to the analysis of DNA measurements from heterogeneous cell populations that differ with respect to DNA content.

Direct binding of radioiodinated monoclonal antibody to tumor cells: significance of antibody purity and affinity for drug targeting or tumor imaging.

For MoAb to be used efficiently for drug targeting and tumor imaging, the fraction of antibody binding to tumor cells must be maximized. We have studied the binding of 125I MoAb in three different tumor systems. The fraction of antibody that could be bound to the cell surface was directly proportional to the antibody purity. The affinity constant also limits the fraction of antibody that can bind to cells at a given antigen concentration. Rearrangement of the standard expression for univalent equilibrium binding between two reactants shows that in antigen excess, the maximum fraction of antibody that can bind (formula; see text). Binding data using four different MoAb with three cell systems confirm this relationship. Estimates for reasonable concentrations of tumor antigens in vivo indicate that antibodies with binding constants less than 10(8) M-1 are not likely to be useful for drug targeting or tumor imaging.