Project description:We used microarrays to investigate gene expression changes in healthy and leukemic cells from Pax5+/- and IL6+/-;Pax5+/- mice in CF and SPF housing conditions. PAX5 is one of the most frequently mutated genes in B-cell acute lymphoblastic leukemia (B-ALL), and children with inherited preleukemic PAX5 mutations are at a higher risk of developing the disease. Abnormal profiles of inflammatory markers can be detected in neonatal blood spot samples of children who later developed B-cell precursor B-ALL. However, how inflammatory signals contribute to B-ALL development is unclear. Here, we demonstrate that Pax5 loss results in the enhanced production of the inflammatory cytokine interleukin-6 (IL-6), which appears to act in an autocrine fashion to promote leukemia growth. In vivo genetic downregulation of IL-6 in Pax5 mutant mice retards B-cell leukemogenesis. In vivo pharmacologic inhibition of IL-6 with a neutralizing IL-6 antibody in Pax5 mutant mice with B-ALL clears leukemic cells. This exciting novel IL 6 signaling paradigm identified in mice was also substantiated in humans. Altogether, our studies establish aberrant IL6 expression caused by Pax5 loss as a hallmark of Pax5-dependent B-ALL and the IL6 as a therapeutic vulnerability for B-ALL characterized by PAX5 loss.

Project description:Inhibition of Inflammatory Signaling in Pax5 Mutant Cells Mitigates B-cell leukemogenesis against leukemia

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Project description:B-cell receptor (BCR) signaling is essential for the diffuse large B-cell lymphoma (DLBCL) subtype that originates from activated B-cells (ABC). ABC-DLBCL cells are sensitive to Bruton tyrosine kinase intervention. However, ABC-DLBCL patients had overall response rates of 33-37% for Bruton tyrosine kinase inhibitors, suggesting the evaluation of combination-based treatment for improved efficacy. We investigated the efficacy and mechanism of AZD5153 combined with the Bruton tyrosine kinase inhibitor acalabrutinib in ABC-DLBCL preclinical models. AZD5153 is a bivalent BET inhibitor that simultaneously engages the two bromodomains of BRD4. Adding AZD5153 to acalabrutinib demonstrated a combination benefit in ABC-DLBCL cell lines and PDX models. Differential expression analyses in treated tumors identified significant alterations of BCR, PAX5, RELB/alternative NFκB, and toll-like receptor/interferon signaling. PAX5 is a transcription factor for BCR signaling genes and may be critical to the perpetually active BCR signaling in ABC-DLBCL. We demonstrate that AZD5153 decreases PAX5 expression, while acalabrutinib disruption to BCR signaling inhibits PAX5 activation. Furthermore, several interferons were decreased by AZD5153 and acalabrutinib in tumors. Adding IFNß1 to cells in vitro restored PAX5 activation. Our results demonstrate AZD5153 enhances the efficacy of acalabrutinib through PAX5 and BCR mechanisms that are critical for ABC-DLBCL.

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