• IRF4-C99R mutations are recurrent in PMBCL and lead to a differentiation block, elevated TARC expression, and regulatory T-cell chemotaxis.

  • IRF4 mutation–associated upregulation of EPHB1 leads to lymphoma organotropism favoring thymic involvement.

Subjects:
Lymphoid Neoplasia
Abstract

Disease-defining signatures in lymphomas, driven by intricate molecular mechanisms, have advanced molecular taxonomies, refined classification, and may guide clinical management; however, the role of these signatures in driving disease hallmarks, including subtype-specific organotropism, remains largely unexplored. Primary mediastinal large B-cell lymphoma (PMBCL) is an exemplary lymphoma characterized by disease manifestations in the thymic niche, unique genetic alterations, and immune escape. Here, we identified interferon regulatory factor 4 (IRF4)–C99R mutations uniquely occurring in PMBCL through mutational meta-analysis of large-scale data sets. By integrating multiomics approaches with genome editing in PMBCL cells, we revealed that IRF4-C99R contributes to a differentiation block phenotype. Specifically, we showed that IRF4-C99R reduces its binding to the interferon-stimulated response element (ISRE) motif within PRDM1, encoding a key transcriptional regulator of B-cell differentiation, resulting in decreased PRDM1 expression. Additionally, IRF4-C99R suppresses Traf2 and Nck-interacting kinase, a key interferon gamma (IFN-γ) pathway regulator, by impairing ISRE motif binding, thereby reducing IFN-γ signaling and increasing thymus and activation-regulated chemokine (TARC) expression, which drives TARC-mediated chemotaxis of T regulatory cells. We also revealed that IRF4-C99R upregulates ephrin type-B receptor 1 (EPHB1) through noncanonical activating protein 1–IRF composite motif binding and showed that overexpression of EPHB1 in an immunocompetent syngeneic lymphoma model influenced organotropism to favor thymic localization, without affecting overall tumor burden. IRF4-C99R mutation–induced phenotypes were validated in primary PMBCL tissues using single-nuclei RNA sequencing, confirming that the molecular mechanisms observed in vitro align with the pathophysiology of PMBCL in patients. Together, these findings demonstrate how a single genetic mutation orchestrates the coordinated regulation of hallmark traits including thymus-specific tropism in PMBCL.

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Lymphoid Neoplasia
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