A Bispecific Antibody Antagonizes Prosurvival CD40 Signaling and Promotes Vγ9Vδ2 T cell–Mediated Antitumor Responses in Human B-cell Malignancies

Abstract Background Chimeric antigen receptor (CAR) T cell therapy has had great success in treating patients with relapsed or refractory B cell malignancies, with CD19-targeting therapies now approved in many countries. However, a subset of patients fails to respond or relapse after CD19 CAR T cell therapy, in part due to antigen loss, which has prompted the search for alternative antigen targets. CD22 is another antigen found on the surface of B cells. CARs targeting CD22 alone or in combination with other antigens have been investigated in several pre-clinical and clinical trials. Given the heterogeneity and small size of CAR T cell therapy clinical trials, systematic reviews are needed to evaluate their efficacy and safety. Here, we propose a systematic review of CAR T cell therapies targeting CD22, alone or in combination with other antigen targets, in B cell malignancies. Methods We will perform a systematic search of EMBASE, MEDLINE, Web of Science, Cochrane Register of Controlled Trials, clinicaltrials.gov, and the International Clinical Trials Registry Platform. Ongoing and completed clinical trials will be identified and cataloged. Interventional studies investigating CD22 CAR T cells, including various multi-antigen targeting approaches, in patients with relapsed or refractory B cell malignancies will be eligible for inclusion. Only full-text articles, conference abstracts, letters, and case reports will be considered. Our primary outcome will be a complete response, defined as absence of detectable cancer. Secondary outcomes will include adverse events, overall response, minimal residual disease, and relapse, among others. Quality assessment will be performed using a modified Institute of Health Economics tool designed for interventional single-arm studies. We will report a narrative synthesis of clinical studies, presented in tabular format. If appropriate, a meta-analysis will be performed using a random effects model to synthesize results. Discussion The results of the proposed review will help inform clinicians, patients, and other stakeholders of the risks and benefits of CD22 CAR T cell therapies. It will identify gaps or inconsistencies in outcome reporting and help to guide future clinical trials investigating CAR T cells. Systematic review registration PROSPERO registration number: CRD42020193027

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Inhibition of Nuclear Translocation of Nuclear Factor-κB Despite Lack of Functional IκBα Protein Overcomes Multiple Defects in Apoptosis Signaling in Human B-Cell Malignancies

Clinical Cancer Research ◽

10.1158/1078-0432.ccr-05-0224 ◽

2005 ◽

Vol 11 (22) ◽

pp. 8186-8194 ◽

Cited By ~ 14

Author(s):

Roman K. Thomas ◽

Martin L. Sos ◽

Thomas Zander ◽

Özlem Mani ◽

Alexey Popov ◽

...

Keyword(s):

B Cell ◽

Nuclear Translocation ◽

Nuclear Factor Κb ◽

Nuclear Factor ◽

B Cell Malignancies ◽

Multiple Defects ◽

Human B Cell

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Differentiation-dependent sensitivity of human B-cell-derived lines to major histocompatibility complex-restricted T-cell cytotoxicity.

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.83.15.5620 ◽

1986 ◽

Vol 83 (15) ◽

pp. 5620-5624 ◽

Cited By ~ 64

Author(s):

S. Torsteinsdottir ◽

M. G. Masucci ◽

B. Ehlin-Henriksson ◽

C. Brautbar ◽

H. Ben Bassat ◽

...

Keyword(s):

Major Histocompatibility Complex ◽

T Cell ◽

B Cell ◽

Cell Cytotoxicity ◽

Major Histocompatibility ◽

Histocompatibility Complex ◽

T Cell Cytotoxicity ◽

Human B Cell

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Optimized Protocols for in Vitro T Cell-Dependent and T Cell-Independent Activation for B Cell Differentiation Studies Using Limited Cells

10.20944/preprints202111.0365.v1 ◽

2021 ◽

Author(s):

Casper Marsman ◽

Dorit Verhoeven

Keyword(s):

Cell Differentiation ◽

T Cell ◽

B Cells ◽

B Cell ◽

Plasma Cells ◽

Cell Formation ◽

B Cell Differentiation ◽

Differentiation Potential ◽

Human B Cell

Background/methods: For mechanistic studies, in vitro human B cell differentiation and generation of plasma cells are invaluable techniques. However, the heterogeneity of both T cell-dependent (TD) and T cell-independent (TI) stimuli and the disparity of culture conditions used in existing protocols makes interpretation of results challenging. The aim of the present study was to achieve the most optimal B cell differentiation conditions using isolated CD19+ B cells and PBMC cultures. We addressed multiple seeding densities, different durations of culturing and various combinations of TD stimuli and TI stimuli including B cell receptor (BCR) triggering. B cell expansion, proliferation and differentiation was analyzed after 6 and 9 days by measuring B cell proliferation and expansion, plasmablast and plasma cell formation and immunoglobulin (Ig) secretion. In addition, these conditions were extrapolated using cryopreserved cells and differentiation potential was compared. Results: This study demonstrates improved differentiation efficiency after 9 days of culturing for both B cell and PBMC cultures using CD40L and IL-21 as TD stimuli and 6 days for CpG and IL-2 as TI stimuli. We arrived at optimized protocols requiring 2500 and 25.000 B cells per culture well for TD and TI assays, respectively. The results of the PBMC cultures were highly comparable to the B cell cultures, which allows dismissal of additional B cell isolation steps prior to culturing. In these optimized TD conditions, the addition of anti-BCR showed little effect on phenotypic B cell differentiation, however it interferes with Ig secretion measurements. Addition of IL-4 to the TD stimuli showed significantly lower Ig secretion. The addition of BAFF to optimized TI conditions showed enhanced B cell differentiation and Ig secretion in B cell but not in PBMC cultures. With this approach, efficient B cell differentiation and Ig secretion was accomplished when starting from fresh or cryopreserved samples. Conclusion: Our methodology demonstrates optimized TD and TI stimulation protocols for more indepth analysis of B cell differentiation in primary human B cell and PBMC cultures while requiring low amounts of B cells, making them ideally suited for future clinical and research studies on B cell differentiation of patient samples from different cohorts of B cell-mediated diseases.

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Duohexabody-CD37, a Novel Bispecific Antibody with a Hexamerization-Enhancing Mutation Targeting CD37, Demonstrates Superior Complement-Dependent Cytotoxicity in Preclinical B-Cell Malignancy Models

Blood ◽

10.1182/blood-2018-99-114723 ◽

2018 ◽

Vol 132 (Supplement 1) ◽

pp. 4170-4170

Author(s):

Simone C. Oostindie ◽

Hilma J. Van Der Horst ◽

Marije B. Overdijk ◽

Kristin Strumane ◽

Sandra Verploegen ◽

...

Keyword(s):

B Cell ◽

Research Funding ◽

Bispecific Antibody ◽

Lymphocytic Leukemia ◽

Single Point Mutation ◽

B Cell Malignancies ◽

Employment Equity ◽

Healthy Human ◽

Complement Dependent Cytotoxicity ◽

Equity Ownership

Abstract CD37 is a tetraspanin plasma membrane protein abundantly expressed on B-cells and represents a promising therapeutic target for the treatment of B-cell malignancies. Although complement-dependent cytotoxicity (CDC) has proven to be a powerful Fc-mediated effector function for killing hematological cancer cells, CD37 antibody-based therapeutics currently in clinical development are poor inducers of CDC. Here we present DuoHexaBody-CD37, a novel humanized IgG1 bispecific antibody targeting two different CD37 epitopes, with an E430G hexamerization-enhancing mutation, for the potential treatment of B-cell malignancies. The natural process of antibody hexamer formation through intermolecular Fc-Fc interactions between IgG molecules after cell surface antigen binding can be improved by introducing a single point mutation such as E430G in the IgG Fc domain, thereby facilitating more efficient C1q binding and complement activation (Diebolder et al., Science 2014; de Jong et al., PLoS Biol 2016). The hexamerization-enhancing mutation E430G was introduced into two humanized CD37 monoclonal antibodies (mAbs) that bind non-overlapping CD37 epitopes. Different antibody formats and combinations, including the single antibodies, combinations of the mAbs and bispecific mAbs were tested for their capacity to induce CDC and antibody-dependent cellular cytotoxicity (ADCC). The bispecific hexamerization-enhanced antibody variant DuoHexaBody-CD37, showed superior CDC activity compared to the single hexamerization-enhanced mAbs and the combination thereof, both in vitro over a range of different B-cell lines, and ex vivo in tumor cell samples obtained from patients with chronic lymphocytic leukemia (CLL). In a CDC assay using tumor cells obtained from a relapsed/refractory CLL patient who received prior treatment with rituximab, ibrutinib and idelalisib, DuoHexaBody-CD37 induced almost complete lysis (84% lysis at a concentration 100 µg/mL), thereby outperforming the single HexaBody molecules (15% and 23% lysis) and the combination (57%) (Figure 1). In addition to its potent CDC activity, DuoHexaBody-CD37 was also capable of inducing potent ADCC of Daudi cells (EC50 = 12.3 ± 9.5 ng/mL), as assessed using peripheral blood mononuclear cells from 8 healthy human donors in a standard chromium release assay. In assays using whole blood from 6 healthy human donors, DuoHexaBody-CD37 showed efficient B-cell binding and potent and specific depletion of the B-cell population (98% ± 1.3% depletion at 10 µg/mL, EC50 = 0.85 ± 0.284 µg/mL). Furthermore, DuoHexaBody-CD37 induced significant inhibition of tumor growth in vivo in Daudi-luc Burkitt's lymphoma and JVM-3 CLL mouse xenograft models, at doses as low as 0.1 and 1 mg/kg (p<0.05), respectively. In summary, we present a novel therapeutic antibody that, for the first time, combines proprietary DuoBody® and HexaBody® platforms. DuoHexaBody-CD37 induced highly potent CDC and efficient ADCC in preclinical models, suggesting that DuoHexaBody-CD37 may serve as a potential therapeutic mAb for the treatment of human B-cell malignancies. Disclosures Oostindie: Genmab: Employment, Equity Ownership. Van Der Horst:Genmab: Research Funding. Overdijk:Genmab: Employment, Equity Ownership. Strumane:Genmab: Employment, Equity Ownership. Verploegen:Genmab: Employment, Equity Ownership. Lindorfer:Genmab: Research Funding. Cook:Genmab: Research Funding. Chamuleau:Gilead: Research Funding; BMS: Research Funding; celgene: Research Funding; Genmab: Research Funding. Mutis:Gilead: Research Funding; Celgene: Research Funding; Janssen: Membership on an entity's Board of Directors or advisory committees, Research Funding; Genmab: Research Funding; Novartis: Research Funding; OnkImmune: Research Funding. Schuurman:Genmab: Employment, Other: Warrants. Sasser:Genmab: Employment, Equity Ownership. Taylor:Genmab: Research Funding. Parren:Genmab: Equity Ownership; Lava Therapeutics: Employment. Beurskens:Genmab: Employment, Equity Ownership. Breij:Genmab: Employment, Equity Ownership.

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