Project description:Despite their long half-life, therapeutic antibodies are considered ineffective against intracellular antigens due to their perceived inability to penetrate epithelial cells. Using recombinant antibodies targeting common mutations in oncogenes, we show that dimeric IgA, but not the same antibody on an IgG backbone, penetrates human epithelial cancer cells through PIGR-dependent directional transcytosis, specifically neutralizing mutated oncodrivers and expelling antigens outside the cell, bound to secretory IgA. Accordingly, targeting of KRasG12D or IDH1R132H with antigen-specific dimeric IgA abrogated the growth of different carcinomas in a mutation-specific manner, including in syngeneic tumor-bearing immunocompetent mice. Our results provide a rationale for developing PIGR-targeting tumor cell-penetrating antibodies to effectively target common mutations in intracellular oncogenes that drive many aggressive and frequent human cancers.

Project description:The pathogenesis of Chlamydophila (C.) psittaci negative ocular adnexal extranodal marginal zone lymphomas (OAEMZLs) is poorly understood. OAEMZLs are monoclonal tumors expressing a biased repertoire of mutated surface immunoglobulins. Antigenic activation of the B cell receptor (BCR) may play a role in the pathogenesis of these lymphomas. We have analyzed the reactivity of recombinant OAEMZL immunoglobulins. OAEMZL antibodies reacted with self-human antigens, as demonstrated by enzyme-linked immunosorbent assays, HEp-2 immunofluorescence and human protein microarrays. All the analyzed recombinant antibodies (rAbs) exhibited polyreactivity by comprehensive protein array antibody reactivity and some rAbs also demonstrated rheumatoid factor activity. The identity of several reactive antigens was confirmed by microcapillary reverse-phase HPLC nano-electrospray tandem mass spectrometry. The tested rAbs frequently reacted with shared intracellular and extracellular self-antigens (e.g. galectin-3). Furthermore, these self-antigens induced BCR signaling in B cells expressing cognate surface immunoglobulins derived from OAEMZLs. These findings suggest that interactions between self-antigens and cognate OAEMZL tumor-derived BCRs are functional, inducing intracellular signaling. Overall our findings suggest that self-antigen-induced BCR stimulation may be implicated in the pathogenesis of C. psittaci negative OAEMZLs. Antibody Specificity Profiling with four OAEMZL rAbs (Ab4438, Ab4726, Ab5334, and Ab11274) performed on ProtoArray Human Protein Microarrays

Project description:The pathogenesis of Chlamydophila (C.) psittaci negative ocular adnexal extranodal marginal zone lymphomas (OAEMZLs) is poorly understood. OAEMZLs are monoclonal tumors expressing a biased repertoire of mutated surface immunoglobulins. Antigenic activation of the B cell receptor (BCR) may play a role in the pathogenesis of these lymphomas. We have analyzed the reactivity of recombinant OAEMZL immunoglobulins. OAEMZL antibodies reacted with self-human antigens, as demonstrated by enzyme-linked immunosorbent assays, HEp-2 immunofluorescence and human protein microarrays. All the analyzed recombinant antibodies (rAbs) exhibited polyreactivity by comprehensive protein array antibody reactivity and some rAbs also demonstrated rheumatoid factor activity. The identity of several reactive antigens was confirmed by microcapillary reverse-phase HPLC nano-electrospray tandem mass spectrometry. The tested rAbs frequently reacted with shared intracellular and extracellular self-antigens (e.g. galectin-3). Furthermore, these self-antigens induced BCR signaling in B cells expressing cognate surface immunoglobulins derived from OAEMZLs. These findings suggest that interactions between self-antigens and cognate OAEMZL tumor-derived BCRs are functional, inducing intracellular signaling. Overall our findings suggest that self-antigen-induced BCR stimulation may be implicated in the pathogenesis of C. psittaci negative OAEMZLs.

Project description:While immune checkpoint blockade (ICB) therapy has significantly improved the outcome of metastatic melanoma and non-small cell lung cancer (NSCLC), most patients do not derive long-term benefits. Previous studies suggest that treatment failure is partly due to insufficient immune recognition of tumor antigens (TAs). Notably, immune targeting of TAs has focused on TAs derived from non-synonymous genomic mutations. We used a proteogenomic approach combining RNA-sequencing and mass spectrometry to study the MHC I-immunopeptidome of cutaneous melanoma and NSCLC samples. The RNA-sequencing of each sample was used to construct sample-specific databases for the mass spectrometry-based identification of MHC I-associated peptides (MAPs). MAPs were then filtered based on their RNA expression in the respective cancer types from The Cancer Genome Atlas (TCGA-SKCM for melanoma MAPs, or TCGA-LUSC and TCGA-LUAD for NSCLC MAPs) vs. benign tissues (from the Genotype-Tissue Expression (GTEx) Project, medullary thymic epithelial cells, purified blood and bone marrow cells, and normal melanocytes for melanoma or bronchial brushing samples for NSCLC). MAPs were classified as mutated tumor-specific antigens (mTSAs, derived from non-synonymous mutations expressed in the sample of origin), or unmutated tumor antigens: aberrantly expressed tumor-specific antigens (aeTSAs, no/low expression in benign tissues and at least two times higher expression in TCGA), tumor-associated antigens (TAAs, significant expression in benign tissues and at least two times higher expression in TCGA), lineage-associated antigens (LSAs, specific expression to cancer and normal tissue of origin, i.e., lung and bronchial brushing samples for NSCLC or skin and melanocytes for melanoma). The tumor antigens described here represent attractive targets for immunotherapy of melanoma and NSCLC.

Project description:While immune checkpoint blockade (ICB) therapy has significantly improved the outcome of metastatic melanoma and non-small cell lung cancer (NSCLC), most patients do not derive long-term benefits. Previous studies suggest that treatment failure is partly due to insufficient immune recognition of tumor antigens (TAs). Notably, immune targeting of TAs has focused on TAs derived from non-synonymous genomic mutations. We used a proteogenomic approach combining RNA-sequencing and mass spectrometry to study the MHC I-immunopeptidome of cutaneous melanoma and NSCLC samples. The RNA-sequencing of each sample was used to construct sample-specific databases for the mass spectrometry-based identification of MHC I-associated peptides (MAPs). MAPs were then filtered based on their RNA expression in the respective cancer types from The Cancer Genome Atlas (TCGA-SKCM for melanoma MAPs, or TCGA-LUSC and TCGA-LUAD for NSCLC MAPs) vs. benign tissues (from the Genotype-Tissue Expression (GTEx) Project, medullary thymic epithelial cells, purified blood and bone marrow cells, and normal melanocytes for melanoma or bronchial brushing samples for NSCLC). MAPs were classified as mutated tumor-specific antigens (mTSAs, derived from non-synonymous mutations expressed in the sample of origin), or unmutated tumor antigens: aberrantly expressed tumor-specific antigens (aeTSAs, no/low expression in benign tissues and at least two times higher expression in TCGA), tumor-associated antigens (TAAs, significant expression in benign tissues and at least two times higher expression in TCGA), lineage-associated antigens (LSAs, specific expression to cancer and normal tissue of origin, i.e., lung and bronchial brushing samples for NSCLC or skin and melanocytes for melanoma). The tumor antigens described here represent attractive targets for immunotherapy of melanoma and NSCLC.

Project description:Intratumoral B cell responses are associated with more favorable clinical outcomes in human pancreatic ductal adenocarcinoma cancer (PDAC). However, the antigens driving these B cell responses are largely unknown. We sought to discover these antigens by using single-cell RNA (sc-RNASeq) and immunoglobulin (Ig) sequencing of tumor-infiltrating immune cells from seven primary PDAC samples. We identified activated T and B cell responses and evidence of germinal center reactions. Ig sequencing identified plasma cell (PC) clones expressing isotype-switched and hyper-mutated Igs, suggesting the occurrence of T cell-dependent B cell responses. We assessed the reactivity of 41 recombinant antibodies that represented the products of 235 PCs and 12 B cells toward multiple cell lines and PDAC tissue, and identified frequent staining of intracellular self-antigens. Three of these antigens were identified: the filamentous actin (F-actin), the nucleic protein, RUVBL2, and the mitochondrial protein, HSPD1. Antibody titers to F-actin and HSPD1 were frequently elevated in the plasma of PDAC patients, and also detectable in healthy donors. Thus, PCs in PDAC frequently produce auto-antibodies reacting with intracellular self-antigens, which may result from promotion of pre-existing autoreactive B cell responses. These observations indicate that the chronic inflammatory microenvironment of PDAC can support the adaptive immune responses.

Project description:Translocations involving FGFR2 gene fusions are common in cholangiocarcinoma and predict response to FGFR kinase inhibitors. However, response rates and durability of are limited due to the emergence of resistance, typically involving FGFR2 kinase domain mutations, and to sub-optimal dosing, relating to drug adverse effects. Here, we develop biparatopic antibodies targeting the FGFR2 extracellular domain (ECD), as candidate therapeutics. Biparatopic antibodies can overcome drawbacks of bivalent monospecific antibodies, which often show poor inhibitory or even agonist activity against oncogenic receptors. We show that oncogenic transformation by FGFR2 fusions requires an intact ECD. Moreover, by systematically generating biparatopic antibodies targeting distinct epitope pairs in FGFR2 ECD, we identified antibodies that effectively block signaling and malignant growth driven by FGFR2-fusions. Importantly, these antibodies demonstrate efficacy in vivo, synergy with FGFR inhibitors, and activity against FGFR2 fusions harboring kinase domain mutations. Thus, biparatopic antibodies may serve as new treatment options for patients with FGFR2-altered cholangiocarcinoma.

Project description:Although chimeric antigen receptor (CAR) T cells have demonstrated remarkable therapeutic activity in hematopoietic malignancies, antigen escape and tumor heterogeneity have in part impeded the durable efficacy of CAR T cells and their extension into successful solid tumor treatment. To address these challenges, induced pluripotent stem cell (iPSC) - derived T (iT) cells were specifically engineered to uniformly express both CAR and T cell receptors (TCR), enabling targeting of both surface and intracellular antigens, respectively, along with a high-affinity, non-cleavable variant of CD16a (hnCD16) to support antibody-dependent cell cytotoxicity (ADCC) when combined with therapeutic antibodies. Co-expression of each of these unique anti-tumor targeting strategies on engineered iT cells enabled independent and antigen-specific tumor cell killing across a diverse set of liquid and solid tumors. In heterogenous tumor models, coactivation of two or more of these effector modalities was required for measurable anti-tumor efficacy, with all three displaying maximal efficacy. These data highlight the therapeutic potential of an off-the-shelf engineered iPSC-derived Trimodal T cell expressing CAR, TCR, and hnCD16 to combat difficult to treat heterogeneous tumors.

Project description:Chimeric antigen receptor (CAR) T-cell immunotherapy in acute myeloid leukemia (AML) remains challenging, primarily due to the lack of specific cell surface antigens that are highly expressed on leukemic blasts but largely absent on hematopoietic stem/progenitor cells and healthy tissues. TCR-like CAR-T therapy targeting intracellular antigens provides a novel strategy for the treatment of AML. In this study, we aimed to develop nanobodies targeting the intracellular antigen PRAME and to establish a novel nanobody-based TCR-like CAR-T cell therapy directed against the peptide-MHC complex PRAME425-433/HLA-A2.

Project description:Early genetic changes during cancer initiation may provide targets for agents that delay, or even prevent, cancer. We hypothesized that cells bearing a single inherited “hit” in a tumor suppressor gene express an altered mRNA repertoire that may identify targets for measures that could delay or even prevent progression to carcinoma. Here, we report on the transcriptomes of primary breast and ovarian epithelial cells cultured from BRCA1 and BRCA2 mutation-carriers and controls. Our comparison analyses identified multiple changes in gene expression, in both tissues for both mutations that were independently validated by real-time RT-PCR analysis. Several of the differentially expressed genes had been previously proposed as cancer markers including, mammaglobin in breast cancer and serum amyloid in ovarian cancer. These findings demonstrate that heterozygosity for a mutant tumor suppressor gene can alter the expression profiles of phenotypically normal epithelial cells in a gene-specific manner, and that these detectable effects of “one-hit” represent early molecular changes in tumorigenesis that may serve as novel biomarkers of cancer risk and as targets for chemoprevention Using affymetrix U133 plus2 chips, we compare the transcriptome of primary breast and ovarian epithelial cultures derived from subjects predisposed to cancer, bearing monoallelic BRCA1 or BRCA2 mutations, with corresponding cultures from control individuals that do not have mutations. For both breast and ovarian samples, epithelial cell cultures were generated from 6 subjects that have both BRCA1 or BRCA2 mutations and 6 subjects that do not have mutations. Affymetrix U133 plus 2 chips were used to profile the transcriptome of BRCA1 or BRCA2 mutant and wild type. In total 36 chips were used to profile 18 samples from both breast and ovary, 6 mutant (BRCA1 and BRCA2) and 6 wild type.