Michael Rycyzyn

Toll-Like Receptor 9 Can Be Expressed at the Cell Surface of Distinct Populations of Tonsils and Human Peripheral Blood Mononuclear Cells

ABSTRACT Unmethlylated CpG dinucleotides induce a strong T-helper-1-like inflammatory response, presumably mediated by Toll-like receptor 9 (TLR9). However, the nature and cellular localization of TLR9 in primary human cells remain controversial. Here we demonstrate, using flow cytometry and immunofluorescence microscopy techniques, that TLR9 can be expressed at the cell surface. The primary human cell subsets that were positive for TLR9 expression were distinct depending on the tissues analyzed. Specifically, in human peripheral blood mononuclear cells (PBMC) the majority of cell surface TLR9+ cells were confined to the major histocompatibility complex (MHC) class II+ CD19− populations that express CD11c and/or CD14, whereas in tonsils the same gated population contained primarily MHC class II+ CD19+ cells. Cells positive for surface expression represented a minor fraction of the total cell populations examined, varying between 2 and 10%. In addition, we found that TLR9 expression at the surface of PBMC was up-regulated approximately fourfold following stimulation with the gram-negative bacterial cell wall component lipopolysaccharide, suggesting a potential modulatory role of TLR4 agonists on TLR9 expression. Taken together, these data validate human TLR9 expression at the surface of primary cells, in addition to the previously described intracellular localization. Further, our results suggest that human antigen-presenting cells comprise the major cell populations expressing cell surface TLR9.

Trastuzumab Triggers Phagocytic Killing of High HER2 Cancer Cells In Vitro and In Vivo by Interaction with Fcγ Receptors on Macrophages

Trastuzumab has been used for the treatment of HER2-overexpressing breast cancer for more than a decade, but the mechanisms of action for the therapy are still being actively investigated. Ab-dependent cell-mediated cytotoxicity mediated by NK cells is well recognized as one of the key mechanisms of action for trastuzumab, but trastuzumab-mediated Ab-dependent cellular phagocytosis (ADCP) has not been established. In this study, we demonstrate that macrophages, by way of phagocytic engulfment, can mediate ADCP and cancer cell killing in the presence of trastuzumab. Increased infiltration of macrophages in the tumor tissue was associated with enhanced efficacy of trastuzumab whereas depletion of macrophages resulted in reduced antitumor efficacy in mouse xenograft tumor models. Among the four mouse FcγRs, FcγRIV exhibits the strongest binding affinity to trastuzumab. Knockdown of FcγRIV in mouse macrophages reduced cancer cell killing and ADCP activity triggered by trastuzumab. Consistently, an upregulation of FcγRIV expression by IFN-γ triggered an increased ADCP activity by trastuzumab. In an analogous fashion, IFN-γ priming of human macrophages increased the expression of FcγRIII, the ortholog of murine FcγRIV, and increased trastuzumab-mediated cancer cell killing. Thus, in two independent systems, the results indicated that activation of macrophages in combination with trastuzumab can serve as a therapeutic strategy for treating high HER2 breast cancer by boosting ADCP killing of cancer cells.

IgG variable region and VH CDR3 diversity in unimmunized mice analyzed by massively parallel sequencing.

Most antigen-specific mouse antibodies have been derived by hybridoma technology, predominantly through use of the Balb/c strain. Much of the Balb/c germline repertoire of variable genes (V regions) is known. However, there is little information about the background expressed repertoire of IgG antibodies in mice, which reflects the baseline against which antigen-specific antibodies are generated through immunization. To assess this baseline repertoire, RNA was isolated from splenic B-cells enriched for expression of IgG from three mice. The RNA was individually amplified with three distinct PCR primer sets for comprehensive recovery of the heavy and light chain variable regions. Each PCR product was independently subjected to deep sequencing using 454 pyro-sequencing technology and analysed for redundancy, open reading frame, germline representation, and CDR3 sequence of the heavy chain variable region (VH CDR3) within and across the primer sets and mice. A highly skewed abundance of heavy and light chain variable gene usage was observed for all three primers in all three mice. While showing considerable overlap, there were differences among these profiles indicative of primer bias and animal-to-animal variation. VH CDR3 sequences were likewise highly skewed indicating that the heavy chain genes profiles substantially reflected individual antibodies. This observation was confirmed through analysis of randomly selected complete heavy chain variable sequences. However, there was very little redundancy in VH CDR3 sequences across the different mice. We conclude that the background IgG repertoire in young, unimmunized mice is highly skewed within individual mice and is diverse among them, a pattern similar to that observed in highly immunized mice.

A novel therapeutic strategy to rescue the immune effector function of proteolytically-inactivated cancer therapeutic antibodies

Primary and acquired resistance to anticancer antibody immunotherapies presents significant clinical challenges. Here, we demonstrate that proteolytic inactivation of cancer-targeting antibodies is an unappreciated contributor to cancer immune evasion, and the finding presents novel opportunities for therapeutic intervention. A single peptide bond cleavage in the IgG1 hinge impairs cancer cell killing due to structural derangement of the Fc region. Hinge-cleaved trastuzumab gradually accumulated on the surfaces of HER2-expressing cancer cell lines in vitro, and was greatly accelerated when the cells were engineered to express the potent bacterial IgG-degrading proteinase (IdeS). Similar to cancer-related matrix metalloproteinases (MMP), IdeS exposes a hinge neoepitope that we have developed an antibody, mAb2095-2, to specifically target the epitope. In in vitro studies, mAb2095-2 restored the lost antibody-dependent cell-mediated cytotoxicity functionality of cell-bound single-cleaved trastuzumab (scIgG-T). In vivo, mAb2095-2 rescued the impaired Fc-dependent tumor-suppressive activity of scIgG-T in a xenograft tumor model and restored the recruitment of immune effector cells into the tumor microenvironment. More importantly, an Fc-engineered proteinase-resistant version of mAb2095-2 rescued trastuzumab antitumor efficacy in a mouse tumor model with human cancer cells secreting IdeS, whereas trastuzumab alone showed significantly reduced antitumor activity in the same model. Consistently, an Fc-engineered proteinase-resistant version of trastuzumab also greatly improved antitumor efficacy in the xenograft tumor model. Taken together, these findings point to a novel cancer therapeutic strategy to rescue proteolytic damage of antibody effector function by an Fc-engineered mAb against the hinge neoepitope and to overcome cancer evasion of antibody immunity. Mol Cancer Ther; 14(3); 681–91. ©2014 AACR.

Surrogate antibodies that specifically bind and neutralize CCL17 but not CCL22.

The chemokines CCL17 (TARC) and CCL22 (MDC) function through the same receptor, CCR4, but have been proposed to differentially affect the immune response. To better understand the role of the individual ligands, a panel of rat anti-mouse CCL17 surrogate antibodies was generated that can be used to differentiate CCL17 and CCL22 function in vitro and in vivo. We have successfully identified a panel of neutralizing antibodies by screening hybridomas for the ability to inhibit CCL17-mediated calcium mobilization. Chemotaxis in response to CCL17 is also inhibited, providing further evidence that the antibodies in this panel are antagonistic. Using a recombinant cell line expressing human CCR4, we show that the antibodies block β-arrestin recruitment as evidence that the antibodies are specifically blocking CCL17 signaling through CCR4. The antibodies within this panel inhibit calcium mobilization with varying potency in the calcium flux assay, having apparent IC50 ranging from approximately 1 to >400 ng/mL. Although both CCL17 and CCL22 function through CCR4, only a single antibody was identified as having detectable binding to CCL22. This panel of CCL17-specific antibodies provides tools that can be used to differentiate CCL17 and CCL22 function through CCR4 interaction in vitro and in vivo.

Generation and Characterization of Rat Anti-mouse ST2L Monoclonal Antibodies

ST2L is a transmembrane receptor that belongs to the IL-1 receptor family. The receptor is expressed on various cell types including Th2 cells, mast cells, basophils, growth-activated fibroblasts, and vascular endothelial cells. ST2L activation by its ligand IL-33 has been implicated in Th2-mediated immunity, inflammation, and allergic responses in vivo. Inhibition of ST2L activity can attenuate Th2-dominated immune responses such as lung eosinophilia, airway hyper-responsiveness, and arthritis in animal models. Here we report the generation and in vitro characterization of a panel of rat anti-mouse ST2L monoclonal antibodies. We demonstrate that the antibodies specifically bind to recombinant receptor protein and that a subset of the binders inhibits mouse ST2L activity in multiple in vitro assays. Four of the identified anti-mouse ST2L antibodies were shown to prevent IL-33 from binding to ST2L, down-regulate IL-33-induced NF-κB signaling, and neutralize the ability of IL-33 to stimulate mouse Th2 cell proliferation. The characterized monoclonal antibodies are important tools that will be used to study mouse ST2L receptor functionality in vivo.

Dysfunctional Antibodies in the Tumor Microenvironment Associate with Impaired Anticancer Immunity

Purpose: Studies have demonstrated that cancer-associated matrix metalloproteinases (MMP) can generate single peptide bond cleavages in the hinge region of immunoglobulin G1 (IgG1). This study investigated the cleavage of endogenous IgGs by MMPs in the tumor microenvironment and the consequences of the IgG hinge cleavage for humoral immunity. Experimental Design: We investigated the occurrence of single peptide bond cleaved IgGs (scIgG) in tumor tissues and plasma samples collected from a cohort of breast cancer patients (n = 60). Samples from healthy people (n = 20) were used as the control. Antibody hinge cleavage was detected by multiple assays, including IHC, ELISA, and flow cytometry. A correlation analysis was conducted between scIgG levels and patient clinical parameters. Results: Levels of scIgGs in tumors were significantly higher than in normal tissues. In addition, scIgG levels in tumors were enriched compared with that in the plasma of the same patients. The appearance of scIgGs in tumor tissues was associated with altered host IgG content and decreased IgG1. Increased tumor scIgGs were found to be positively correlated with adverse clinical factors, such as elevated tumor-associated macrophages, increased expression of MMP9 and other MMPs, and local metastasis to axillary lymph nodes. Conclusions: The study contributes to mounting evidence for the presence of hinge-cleaved antibodies with reduced Fc immune effector function in the tumor microenvironment. The results highlight a link between tumor scIgGs and poor patient outcomes, and reveal a component of compromised humoral immunity within tumors that could point to new immunotherapeutic strategies to rescue host immunity. Clin Cancer Res; 21(23); 5380–90. ©2015 AACR.

The Use of an Anti-CD40 Agonist Monoclonal Antibody During Immunizations Enhances Hybridoma Generation

ABSTRACT Herein we describe the use of an agonistic anti-murine CD40 MAb as a B cell proliferative agent to enhance the generation of monoclonal antibodies (MAbs) in Balb/c mice. While hybridoma technology has been validated repeatedly over the decades, little work has been described to improve upon the overall numbers of in vivo B cells and specific antibodies obtained from a fusion. To begin to address this situation, strategies to boost B lymphocyte yields for hybridoma production were employed. Anti-CD40 agonist antibodies have been reported to activate and amplify human resting B lymphocytes in vitro, resulting in increased cell numbers available for the generation of human hybridomas or B cell clones. An agonistic anti-murine CD40 MAb was administered to immunized mice 3 days prior to splenic harvest, and B lymphocyte yields were found to be approximately 2-fold higher in treated animals when compared to untreated animals. Moreover, the resulting hybridoma fusions using lymphocytes from treated animals yielded 5- to 10-fold more antigen reactive hybrids when compared to untreated animals. This novel addition to conventional approaches utilizes the proliferative effects of agonistic anti-CD40 MAbs to markedly enhance monoclonal antibody generation.

Antibody discovery from immune competent and immune transplanted mice.

Since Kohler and Milstein developed the process of generating hybridomas by fusing antibody secreting B cells with an immortal myeloma cell line, the techniques used to develop monoclonal antibodies for use as human therapeutics have progressed significantly. Here, we will briefly review hybridoma technology and the evolution of therapeutic antibodies for the treatment of human disease. We will focus on the evolution of humanized mouse models for the generation of therapeutic human antibodies, comparing the early models, such as severe combined immunodeficient (SCID) mice which do not engraft human leukocytes well due to residual innate immunity, to the more recently developed models such as non-obese diabetic (NOD)/SCID IL-2Rγ-deficient mice in which numerous human hematopoietic lineages can be cultivated. Building on the identification of suitable host strains for the reconstitution of human immune cells, focus has now shifted onto humanizing the murine microenvironment in order to support human immune cell function. Although several recent studies have shown that the provision of human soluble factors can support maturation and function of human immune cells, particularly within the myeloid compartment, this does not appear to impact antibody production significantly. Moreover, models in which grafting of human tissues is performed to provide human microenvironments which support human leukocyte maturation do show improved humoral immune function, but require several surgical manipulations for generation of the model. Ultimately the most desirable scenario is to generate transgenic models that can be bred efficiently and express a sufficient number of human molecules to support functional human immune cells and several groups have made progress in making this idea a reality. These studies in the context of the generation of human antibodies will be discussed.