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Literature DB >> 31978211

Development and survival of MYC-driven lymphomas require the MYC antagonist MNT to curb MYC-induced apoptosis.

Hai Vu Nguyen^1,2, Cassandra J Vandenberg^1,2, Ashley P Ng^1,2, Mikara R Robati¹, Natasha S Anstee^1,2, Joel Rimes^1,2, Edwin D Hawkins^1,2, Suzanne Cory^1,2.

Abstract

Deregulated overexpression of MYC is implicated in the development and malignant progression of most (∼70%) human tumors. MYC drives cell growth and proliferation, but also, at high levels, promotes apoptosis. Here, we report that the proliferative capacity of MYC-driven normal and neoplastic B lymphoid cells depends on MNT, a MYC-related transcriptional repressor. Our genetic data establish that MNT synergizes with MYC by suppressing MYC-driven apoptosis, and that it does so primarily by reducing the level of pro-apoptotic BIM. In Eμ-Myc mice, which model the MYC/IGH chromosome translocation in Burkitt's lymphoma, homozygous Mnt deletion greatly reduced lymphoma incidence by enhancing apoptosis and markedly decreasing premalignant B lymphoid cell populations. Strikingly, by inducing Mnt deletion within transplanted fully malignant Eμ-Myc lymphoma cells, we significantly extended transplant recipient survival. The dependency of lymphomas on MNT for survival suggests that drugs inhibiting MNT could significantly boost therapy of MYC-driven tumors by enhancing intrinsic MYC-driven apoptosis.

Entities: Disease Gene Species

Mesh：

Substances：

Year: 2020 PMID： 31978211 PMCID： PMC7118401 DOI： 10.1182/blood.2019003014

Source DB: PubMed Journal: Blood ISSN： 0006-4971 Impact factor: 22.113

61 in total

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Authors: W Y Langdon; A W Harris; S Cory; J M Adams
Journal: Cell Date: 1986-10-10 Impact factor: 41.582

Review 2. Reflecting on 25 years with MYC.

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Journal: Nucleic Acids Res Date: 2003-02-15 Impact factor: 16.971

5. Inhibition of Myc family proteins eradicates KRas-driven lung cancer in mice.

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Journal: Genes Dev Date: 2013-03-01 Impact factor: 11.361

6. High-resolution genomic profiling of chronic lymphocytic leukemia reveals new recurrent genomic alterations.

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Journal: Blood Date: 2012-10-09 Impact factor: 22.113

7. The dTAG system for immediate and target-specific protein degradation.

Authors: Behnam Nabet; Justin M Roberts; Dennis L Buckley; Joshiawa Paulk; Shiva Dastjerdi; Annan Yang; Alan L Leggett; Michael A Erb; Matthew A Lawlor; Amanda Souza; Thomas G Scott; Sarah Vittori; Jennifer A Perry; Jun Qi; Georg E Winter; Kwok-Kin Wong; Nathanael S Gray; James E Bradner
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8. Distinct thresholds govern Myc's biological output in vivo.

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Journal: Cancer Cell Date: 2008-12-09 Impact factor: 31.743

Review 9. Targeting oncogenic Myc as a strategy for cancer treatment.

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Journal: Signal Transduct Target Ther Date: 2018-02-23

10. T-cell acute leukaemia exhibits dynamic interactions with bone marrow microenvironments.

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Journal: Nature Date: 2016-10-17 Impact factor: 49.962

10 in total

1. MYC needs MNT to drive B cells over the edge.

Authors: Siegfried Janz
Journal: Blood Date: 2020-03-26 Impact factor: 22.113

Review 2. Normal and Neoplastic Growth Suppression by the Extended Myc Network.

Authors: Edward V Prochownik; Huabo Wang
Journal: Cells Date: 2022-02-21 Impact factor: 6.600

3. A novel role of MNT as a negative regulator of REL and the NF-κB pathway.

Authors: Judit Liaño-Pons; M Carmen Lafita-Navarro; Lorena García-Gaipo; Carlota Colomer; Javier Rodríguez; Alex von Kriegsheim; Peter J Hurlin; Fabiana Ourique; M Dolores Delgado; Anna Bigas; Lluis Espinosa; Javier León
Journal: Oncogenesis Date: 2021-01-08 Impact factor: 7.485

4. Adaptive Immune Response Signaling Is Suppressed in Ly6C^high Monocyte but Upregulated in Monocyte Subsets of ApoE ^-/- Mice - Functional Implication in Atherosclerosis.

Authors: Pingping Yang; Qinghua Wu; Lizhe Sun; Pu Fang; Lu Liu; Yong Ji; Joon-Young Park; Xuebin Qin; Xiaofeng Yang; Hong Wang
Journal: Front Immunol Date: 2021-12-20 Impact factor: 7.561

5. Polycomb group ring finger protein 6 suppresses Myc-induced lymphomagenesis.

Authors: Nina Tanaskovic; Mattia Dalsass; Marco Filipuzzi; Giorgia Ceccotti; Alessandro Verrecchia; Paola Nicoli; Mirko Doni; Daniela Olivero; Diego Pasini; Haruhiko Koseki; Arianna Sabò; Andrea Bisso; Bruno Amati
Journal: Life Sci Alliance Date: 2022-04-14

6. Biomimetic nanotherapy: core-shell structured nanocomplexes based on the neutrophil membrane for targeted therapy of lymphoma.

Authors: Qiangqiang Zhao; Duanfeng Jiang; Xiaoying Sun; Qiuyu Mo; Shaobin Chen; Wansong Chen; Rong Gui; Xianjun Ma
Journal: J Nanobiotechnology Date: 2021-06-13 Impact factor: 10.435

7. Loss of MGA repression mediated by an atypical polycomb complex promotes tumor progression and invasiveness.

Authors: Haritha Mathsyaraja; Jonathen Catchpole; Brian Freie; Emily Eastwood; Ekaterina Babaeva; Michael Geuenich; Pei Feng Cheng; Jessica Ayers; Ming Yu; Nan Wu; Sitapriya Moorthi; Kumud R Poudel; Amanda Koehne; William Grady; A McGarry Houghton; Alice H Berger; Yuzuru Shiio; David MacPherson; Robert N Eisenman
Journal: Elife Date: 2021-07-08 Impact factor: 8.140

Review 8. Mouse Models of c-myc Deregulation Driven by IgH Locus Enhancers as Models of B-Cell Lymphomagenesis.

Authors: Melissa Ferrad; Nour Ghazzaui; Hussein Issaoui; Jeanne Cook-Moreau; Yves Denizot
Journal: Front Immunol Date: 2020-07-23 Impact factor: 7.561

Review 9. Insights about MYC and Apoptosis in B-Lymphomagenesis: An Update from Murine Models.

Authors: Eleonora Vecchio; Giuseppe Fiume; Serena Correnti; Salvatore Romano; Enrico Iaccino; Selena Mimmi; Domenico Maisano; Nancy Nisticò; Ileana Quinto
Journal: Int J Mol Sci Date: 2020-06-15 Impact factor: 5.923

Review 10. Impact of MYC on Anti-Tumor Immune Responses in Aggressive B Cell Non-Hodgkin Lymphomas: Consequences for Cancer Immunotherapy.

Authors: A Vera de Jonge; Tuna Mutis; Margaretha G M Roemer; Blanca Scheijen; Martine E D Chamuleau
Journal: Cancers (Basel) Date: 2020-10-20 Impact factor: 6.639

10 in total