Litcius/Paper detail

Targeting MEF2D-fusion Oncogenic Transcriptional Circuitries in B-cell Precursor Acute Lymphoblastic Leukemia

Shinobu Tsuzuki, Takahiko Yasuda, Shinya Kojima, Masahito Kawazu, Koshi Akahane, Takeshi Inukai, Masue Imaizumi, Takanobu Morishita, Koichi Miyamura, Toshihide Ueno, Sivasundaram Karnan, Akinobu Ota, Toshinori Hyodo, Hiroyuki Konishi, Masashi Sanada, Hirokazu Nagai, Keizo Horibe, Akihiro Tomita, Kyogo Suzuki, Hideki Muramatsu, Yoshiyuki Takahashi, Yasushi Miyazaki, Itaru Matsumura, Hitoshi Kiyoi, Yoshitaka Hosokawa, Hiroyuki Mano, Fumihiko Hayakawa

2020Blood Cancer Discovery31 citationsDOIOpen Access PDF

Abstract

Abstract The cellular context that integrates gene expression, signaling, and metabolism dictates the oncogenic behavior and shapes the treatment responses in distinct cancer types. Although chimeric fusion proteins involving transcription factors (TF) are hallmarks of many types of acute lymphoblastic leukemia (ALL), therapeutically targeting the fusion proteins is a challenge. In this work, we characterize the core regulatory circuitry (CRC; interconnected autoregulatory loops of TFs) of B-ALL involving MEF2D-fusions and identify MEF2D-fusion and SREBF1 TFs as crucial CRC components. By gene silencing and pharmacologic perturbation, we reveal that the CRC integrates the pre-B-cell receptor (BCR) and lipid metabolism to maintain itself and govern malignant phenotypes. Small-molecule inhibitors of pre-BCR signaling and lipid biosynthesis disrupt the CRC and silence the MEF2D fusion in cell culture and show therapeutic efficacy in xenografted mice. Therefore, pharmacologic disruption of CRC presents a potential therapeutic strategy to target fusion protein–driven leukemia. Significance: Cancer type–specific gene expression is governed by transcription factors involved in a highly interconnected autoregulatory loop called CRC. Here, we characterized fusion protein–driven CRC and identified its pharmacologic vulnerabilities, opening therapeutic avenues to indirectly target fusion-driven leukemia by disrupting its CRC. See related commentary by Sadras and Müschen, p. 18. This article is highlighted in the In This Issue feature, p. 5

Topics & Concepts

BiologyFusion geneFusion proteinCancer researchTranscription factorLeukemiaGene silencingGeneCell biologyGeneticsRecombinant DNAAcute Lymphoblastic Leukemia researchProtein Degradation and InhibitorsCell death mechanisms and regulation