Neutralizing monoclonal antibodies elicited by mosaic RBD nanoparticles bind conserved sarbecovirus epitopes.

Increased immune evasion by SARS-CoV-2 variants of concern highlights the need for new therapeutic neutralizing antibodies. Immunization with nanoparticles co-displaying spike receptor-binding domains (RBDs) from eight sarbecoviruses (mosaic-8 RBD-nanoparticles) efficiently elicits cross-reactive polyclonal antibodies against conserved sarbecovirus RBD epitopes. Here, we identified monoclonal antibodies (mAbs) capable of cross-reactive binding and neutralization of animal sarbecoviruses and SARS-CoV-2 variants by screening single mouse B cells secreting IgGs that bind two or more sarbecovirus RBDs. Single-particle cryo-EM structures of antibody-spike complexes, including a Fab-Omicron complex, mapped neutralizing mAbs to conserved class 1/4 RBD epitopes. Structural analyses revealed neutralization mechanisms, potentials for intra-spike trimer cross-linking by IgGs, and induced changes in trimer upon Fab binding. In addition, we identified a mAb-resembling Bebtelovimab, an EUA-approved human class 3 anti-RBD mAb. These results support using mosaic RBD-nanoparticle vaccination to generate and identify therapeutic pan-sarbecovirus and pan-variant mAbs.

Antibody-based redirection of universal Fabrack-CAR T cells selectively kill antigen bearing tumor cells.

BACKGROUND: Chimeric antigen receptor (CAR) T cells engineered to recognize and target tumor associated antigens have made a profound impact on the quality of life for many patients with cancer. However, tumor heterogeneity and intratumoral immune suppression reduce the efficacy of this approach, allowing for tumor cells devoid of the target antigen to seed disease recurrence. Here, we address the complexity of tumor heterogeneity by developing a universal CAR. METHOD: We constructed a universal Fabrack-CAR with an extracellular domain composed of the non-tumor targeted, cyclic, twelve residue meditope peptide that binds specifically to an engineered binding pocket within the Fab arm of monoclonal antibodies (mAbs). As this site is readily grafted onto therapeutic mAbs, the antigen specificity of these universal Fabrack-CAR T cells is simply conferred by administering mAbs with specificity to the heterogeneous tumor. RESULTS: Using in vitro and in vivo studies with multiple meditope-engineered mAbs, we show the feasibility, specificity, and robustness of this approach. These studies demonstrate antigen- and antibody-specific T cell activation, proliferation, and IFNγ production, selective killing of target cells in a mixed population, and tumor regression in animal models. CONCLUSION: Collectively, these findings support the feasibility of this universal Fabrack-CAR T cell approach and provide the rationale for future clinical use in cancer immunotherapy.

Manipulating mIgD-expressing B cells with anti-migis-δ monoclonal antibodies.

Surface IgD and IgM doubly positive cells comprise the major population of B cells in the human immune system. The heavy chain of membrane-bound IgD (mδ) differs from that of IgD (δ) in that mδ contains a C-terminal membrane-anchor peptide. Our group previously proposed that the N-terminal extracellular segment of 27 aa residues of the membrane-anchor peptide of mδ, referred to as the mIg isotype-specific-δ (migis-δ) segment, may provide a unique antigenic site for isotype-specific targeting of mIgD(+) B cells. Here we report the preparation of mouse mAbs specific for human migis-δ. The mAbs bound to human migis-δ-containing recombinant proteins in an ELISA and to mIgD-expressing transfectants of a CHO cell line as analyzed by flow cytometry. MAb 20E6, which binds to an epitope toward the N-terminal of human migis-δ, could stain human B cell line MC116, which expressed mIgD and mIgM. MC116 cells could be induced to undergo apoptosis by treatment with 20E6 in the presence of a second crosslinking antibody. Chimeric 20E6 caused antibody-dependent cellular cytotoxicity of MC116 cells in the presence of human PBMCs as the source of effector cells. In cultures of PBMCs, 20E6 down-regulated the population of mIgD(+) B cells. The production of human IgM by transplanted MC116 cells in NOD-SCID (NOD.CB17-Prkdc(scid)/IcrCrlBltw) mice could be suppressed by 20E6. These results encourage further investigation of the potential of anti-migis-δ mAbs to control mIgD(+) B cells, when such a manipulation may alleviate a disease state.

CɛmX peptide-carrying HBcAg virus-like particles induced antibodies that down-regulate mIgE-B lymphocytes.

Type-I hypersensitivity reactions play a critical role in the pathogenesis of various allergic diseases. The successful development of the anti-IgE antibody, omalizumab, has validated IgE as an effective therapeutic target for the treatment of various IgE-mediated allergic diseases. Two research groups have reported that mAbs specific for certain parts of CɛmX, a domain of 52 aa residues in human membrane-bound IgE (mIgE), can cause the lysis of mIgE-B cells by apoptosis and antibody-dependent cellular cytotoxicity (ADCC). Herein, we explore virus-like particles formed by hepatitis B virus core antigen (HBcAg) that harbors the entire CɛmX peptide or its fragments as immunogens for inducing anti-CɛmX antibodies. The results showed that mice immunized subcutaneously with these immunogens produced antibodies that bind to recombinant CɛmX-containing human IgE.Fc in ELISA and Western blot analyses, and to genetically engineered human mIgE-expressing Ramos B cell line in fluorescence flow cytometric assays. The IgG antibodies purified from the sera of immunized mice were able to cause the apoptosis of mIgE-expressing Ramos cells through a BCR-dependent caspase pathway. Furthermore, the IgG could mediate ADCC in human mIgE-expressing A20 murine B-cell lymphoma. These studies suggest that HBcAg-CɛmX peptide immunogens warrant further investigation as a therapeutic modality for modulating IgE in patients with IgE-mediated allergic diseases.

An anti-IgE monoclonal antibody that binds to IgE on CD23 but not on high-affinity IgE.Fc receptors.

A new monoclonal antibody (mAb), specific for human IgE, the central mediator of immediate-type hypersensitivity reactions, has been shown to possess a unique set of binding specificities. The mAb, 8D6, binds to a conformational epitope on the CH3 domain of human e immunoglobulin and can compete with omalizumab for binding to IgE. Like omalizumab, it does not bind to IgE bound by the high-affinity IgE.Fc receptor (FcɛRI) on basophils and mast cells. It also does not cause activation and degranulation of IgE-pulsed, human FcɛRI-expressing rat basophilic leukemic cells (RBL SX-38). The mAb can inhibit IgE binding to recombinant α chain of human FcɛRI in ELISA and to human FcɛRI-expressing RBL SX38 cells in fluorescence flow cytometric analysis. However, unlike omalizumab, 8D6 can bind to IgE already bound by the low-affinity IgE.Fc receptors (FcɛRII, or CD23), as revealed in ELISA with recombinant CD23 and in flow cytometric analysis with human B cells. Since earlier investigators have shown that anti-CD23 mAbs can inhibit the synthesis of IgE in lymphocyte culture in vitro and can down-regulate IgE production in treated patients, 8D6 may offer pharmacological mechanisms in addition to those mediated by omalizumab, for controlling IgE in patients with allergic diseases.

Lipid rafts hinder binding of antibodies to the extracellular segment of the membrane-anchor peptide of mIgA.

Membrane-bound IgA (mIgA) is associated with Igα/Igß as the B cell receptor (BCR) complex on mIgA-expressing B cells. The α chain of mIgA (mα) contains a C-terminal membrane-anchor peptide, which encompasses extracellular, transmembrane and intracellular segments. The extracellular segment, referred to as the mIg isotype-specific (migis-α) segment or the extracellular membrane proximal domain of mα, has been proposed to be a specific antigenic site suitable for isotype-specific targeting of mIgA-expressing B cells by antibodies. In this study, we developed several anti-migis-α monoclonal antibodies (mAbs), such as mAb 29C11, specific to a segment towards the N-terminus of the 26 amino acid long migis-α. The mAbs bound strongly to synthetic peptides of migis-α and to various recombinant proteins containing migis-α as revealed by ELISA. On B cells, however, flow cytometric analysis suggested that these mAbs did not bind strongly to mIgA. After lipid rafts of B cells were disrupted by cholesterol extraction, the mAbs were able to bind strongly to the treated B cells. Moreover, immunoprecipitation analysis of these mAbs indicated that mIgA could only be pulled down by the mAbs when mIgA-expressing B cells were solubilized by strong detergents, such as sodium dodecyl sulfate (SDS), or when lipid rafts were disrupted. Together, these results suggest that the migis-α region of mIgA in the BCR is associated with lipid rafts, which hinder binding of migis-α-specific antibodies to mIgA on the cell surface. Further studies are in progress to evaluate the suitability of 29C11 or its affinity-improved variants for targeting mIgA-expressing B cells.

Unique epitopes on C epsilon mX in IgE-B cell receptors are potentially applicable for targeting IgE-committed B cells.

Membrane-bound IgE (mIgE) is part of the IgE-BCR and is essential for generating isotype-specific IgE responses. On mIgE(+) B cells, the membrane-bound epsilon-chain (mepsilon) exists predominantly in the long isoform, mepsilon(L), containing an extra 52 aa CepsilonmX domain between CH4 and the C-terminal membrane-anchoring segment; the short isoform of mepsilon, mepsilon(S), exists in minor proportions. CepsilonmX thus provides an attractive site for immunologic targeting of mIgE(+) B cells. In this study, we show that nine newly prepared CepsilonmX-specific mAbs, as well as the previously reported a20, bound to mIgE.Fc(L)-expressing CHO cells, while only 4B12 and 26H2 bound to mIgE.Fc(L)-expressing B cell line Ramos cells. The mAb 4B12 bound to the N-terminal part, 26H2 the middle part, and all others the C-terminal part of CepsilonmX. Expression of Igalpha and Igbeta on the mIgE.Fc(L)-CHO cells reduces the binding of a20 to CepsilonmX as compared with that of 4B12 and 26H2. The chimeric mAbs c4B12 and c26H2, when cross-linked by secondary antibodies, lysed mIgE.Fc(L)-Ramos cells by apoptosis through a BCR-dependent caspase pathway. Using PBMCs as the source of effector cells, c4B12 and c26H2 demonstrated Ab-dependent cellular cytotoxicity toward mIgE.Fc(L)-Ramos cells in a dose-dependent fashion. In cultures of PBMCs from atopic dermatitis patients, c4B12 and c26H2 inhibited the synthesis of IgE driven by anti-CD40 and IL-4. These results suggest that 4B12 and 26H2 and an immunogen using the peptide segments recognized by these mAbs are potentially useful for targeting mIgE(+) B cells to control IgE production.

Alleles and isoforms of human membrane-bound IgA1.

In humans, IgA exists as two subclasses, IgA1 and IgA2, which contain distinct alpha1 and alpha2 heavy chains, respectively. Both subclasses also have membrane-bound forms (mIgA1 and mIgA2) containing the corresponding malpha1 and malpha2 heavy chains, which differ from alpha1 and alpha2 by an additional "membrane-anchor" peptide segment extending from the CH3 domain of alpha1 and alpha2. The membrane-anchor segment has three parts: an extracellular, a transmembrane, and an intracellular segment. The heavy chain malpha1 exists in short and long isoforms, referred to as malpha1S and malpha1L, with the latter containing extra 6 amino acid residues, GSCSVA, at the N-terminus of the extracellular segment (residues 453-458). By studying the genomic and mRNA sequences of malpha1 and malpha2 from 30 individuals residing in Taiwan, we have found that, in addition to the known malpha1 allele, referred to as malpha1(456S), malpha1 also has a previously unknown allele, referred to as malpha1(456C) (GenBank accession no. EU431191). This newly identified allele is present in the donor population at a similar proportion to malpha1(456S), and appears to exist only as the long isoform, i.e. malpha1L, rather than the short isoform, malpha1S. Furthermore, we confirmed that malpha2 exists only as the short isoform. Future studies will examine whether these mIgA1 variations affect the regulation of IgA synthesis and whether mIgA1 can provide an antigenic site for the immunological targeting of IgA-expressing B cells.