Abstract DLBCL originate from germinal center B cells (GCB). The ABC-DLBCL subtype, characterized by activation of B-cell receptor (BCR) signaling and downstream NF-kB pathway, carries a poor outcome. Up to 30% of ABC-DLBCL present TOXLOF mutations, suggesting that TOX function as a tumor suppressor. Our analysis of TOX expression along the germinal center B-cell differentiation program (naïve → GCB → plasma cells) showed that TOX expression paralleled NF-kB activity with highest levels in plasma cells (P<0.001, vs. either naïve and GCB). We thus propose that TOX acts as a transcriptional gatekeeper in GCB cells to prevent early activation of NF-kB thus enabling differentiation into plasma cells while restraining lymphomagenesis. We generated a conditional GCB TOX KO mouse model, induced the GC reaction with a T-cell antigen and found that TOX KO (vs. TOX WT, 10 mice per condition) had impaired differentiation of plasma cells (p<0.001) and hyperproliferative Ki67+ GCB cells (p<0.05). We then generated (by CRISPR) an isogenic TOXLOF ABC-DLBCL cell line (TMD8) and found upregulation of genes in the NF-kB pathway (q-value <0.05, vs. TMD8). Furthermore, TMD8-TOXLOF cells showed increased secretion of autocrine cytokines IL6 and IL10, and higher STAT3 phosphorylation (p<0.05 for all comparisons, vs. TMD8-TOXWT cells) all compatible with NF-kB activation. Tumor microenvironmental cues can hyperactivate BCR and downstream NF-kB in ABC-DLBCL. We thus implanted isogenic TMD8 cells in mice (n = 10) and determined pathway activation by phospho-flow. We found massive activation of SYK, BTK, PLCG2 (from the BCR) and p65 (from NF-kB) in TMD8-TOXLOF vs. TMD8-TOXWT tumors (all p<0.01), and vs. these cell lines cultured in vitro (all p<0.01). To determine whether these features can be therapeutically exploited, we conducted a viability screening using a panel of 20 clinical-phase targeted therapies relevant to ABC-DLBCL. We found that BTK inhibitor acalabrutinib (BCR pathway) and MALT1 inhibitor JNJ67690246 (NF-kB pathway) were 2-3 fold more active in TMD8-TOXLOF vs. TMD8-TOXWT cells (all p<0.05). We then xenografted isogenic TMD8 cells (n = 10 mice per condition) and, when tumors reached 150 mm3, we randomized mice to vehicle vs. acalabrutinib 30 mg/kg/day by oral gavage (human dose equivalent). Acalabrutinib was significantly more active in TMD8-TOXLOF tumors (vs. TMD8-TOXWT, p=0.0008), which translated into significantly prolonged survival (p<0.05). This acalabrutinib effect was accompanied by significant reduction of BTK, SYK and PLCG2 phosphorylation in TMD8-TOXLOF tumors (p<0.0001, all comparisons). Thus, TOXLOF leads to hyperactivation of the BCR and NF-kB signaling pathways in ABC-DLBCL cells, rendering them hypersensitive to BCR-targeted therapies, delineating a potential mechanism-based therapeutic approach for ABC-DLBCL TOXLOF patients. Citation Format: Eloisi Caldas Lopes, Maria Revuelta, Rossella Marullo, Leandro Cerchietti. TOX loss-of-function(TOXLOF)results in BCR hyperactivation andenhanced responses to BCR-targeting in diffuse large B cell lymphomas (DLBCL) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7586.
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