CoREST complex inhibition alters RNA splicing to promote neoantigen expression and enhance tumor immunity
Robert J. Fisher, Kihyun Park, Kwangwoon Lee, Katarina Pinjusic, Allison Vanasse, Christina S. Ennis, Parisa Farokh, Scott B. Ficaro, Jarrod A. Marto, Hanjie Jiang, Eunju Nam, Stephanie Stransky, Joseph Duke-Cohan, Melis A. Akinci, Anupa Geethadevi, Eric Raabe, Ana Fiszbein, Shadmehr Demehri, Simone Sidoli, Chad W. Hicks, Derin B. Keskin, Catherine J. Wu, Philip A. Cole, Rhoda M. Alani
Robert J. Fisher, Kihyun Park, Kwangwoon Lee, Katarina Pinjusic, Allison Vanasse, Christina S. Ennis, Parisa Farokh, Scott B. Ficaro, Jarrod A. Marto, Hanjie Jiang, Eunju Nam, Stephanie Stransky, Joseph Duke-Cohan, Melis A. Akinci, Anupa Geethadevi, Eric Raabe, Ana Fiszbein, Shadmehr Demehri, Simone Sidoli, Chad W. Hicks, Derin B. Keskin, Catherine J. Wu, Philip A. Cole, Rhoda M. Alani
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Research Article Dermatology Oncology Therapeutics

CoREST complex inhibition alters RNA splicing to promote neoantigen expression and enhance tumor immunity

Abstract

Epigenetic macromolecular enzyme complexes tightly regulate gene expression at the chromatin level and have recently been found to colocalize with RNA splicing machinery during active transcription; however, the precise functional consequences of these interactions are uncertain. Here, we identify unique interactions of the CoREST repressor complex (LSD1-HDAC1-CoREST) with components of the RNA splicing machinery and their functional consequences in tumorigenesis. Using mass spectrometry, in vivo binding assays, and cryo-EM, we find that CoREST complex–splicing factor interactions are direct and perturbed by the CoREST complex selective inhibitor, corin, leading to extensive changes in RNA splicing in melanoma and other malignancies. Moreover, these corin-induced splicing changes are shown to promote global effects on oncogenic and survival-associated splice variants, leading to a tumor-suppressive phenotype. Using machine learning models, MHC IP-MS, and ELISpot assays, we identify thousands of neopeptides derived from unannotated splice sites that generate corin-induced splice-neoantigens that are demonstrated to be immunogenic in vitro. Corin is further shown to reactivate the response to immune checkpoint blockade, effectively sensitizing tumors to anti–PD-1 immunotherapy. These data position CoREST complex inhibition as a unique therapeutic opportunity that perturbs oncogenic splicing programs while also creating tumor-associated neoantigens that enhance the immunogenicity of current therapeutics.

Authors

Robert J. Fisher, Kihyun Park, Kwangwoon Lee, Katarina Pinjusic, Allison Vanasse, Christina S. Ennis, Parisa Farokh, Scott B. Ficaro, Jarrod A. Marto, Hanjie Jiang, Eunju Nam, Stephanie Stransky, Joseph Duke-Cohan, Melis A. Akinci, Anupa Geethadevi, Eric Raabe, Ana Fiszbein, Shadmehr Demehri, Simone Sidoli, Chad W. Hicks, Derin B. Keskin, Catherine J. Wu, Philip A. Cole, Rhoda M. Alani

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Figure 2

Cryo-EM structure and AlphaFold prediction of U2AF2 bound to LSD1 + RCOR1.

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Cryo-EM structure and AlphaFold prediction of U2AF2 bound to LSD1 + RCOR...
(A) Size exclusion chromatography for cryo-EM sample preparation. The early fractions (fractions 22–25), containing LSD1, RCOR1, and U2AF2, were pooled, concentrated, and subsequently used for cryo-EM analysis. (B) Domain schematic of all protein components used for cryo-EM sample preparation. (C) Cryo-EM map of the RRM2 domain of U2AF2 bound to the LSD1 + RCOR1 complex. (D) Cryo-EM model in cartoon view representing the cryo-EM map shown in C. (E) AlphaFold model representing the prediction shown in D. (F) Predicted local distance difference test (pLDDT) plot of the AlphaFold multimer prediction incorporating LSD1, RCOR1, U2AF2, and RNA. (G) Superimposition of the RRM2 domain of U2AF2 from AlphaFold multimer over our cryo-EM structure of LSD1 + RCOR1 + U2AF2. Zoomed-in box shows the degree of similarity in position between the 2 RRM2 globular domain models.