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HDAC8-mediated inhibition of EP300 drives a transcriptional state that increases melanoma brain metastasis

Author

Listed:
  • Michael F. Emmons

    (Moffitt Cancer Center)

  • Richard L. Bennett

    (UF Health Cancer Center)

  • Alberto Riva

    (University of Florida)

  • Kanchan Gupta

    (UF Health Cancer Center)

  • Larissa Anastasio Da Costa Carvalho

    (Moffitt Cancer Center)

  • Chao Zhang

    (Moffitt Cancer Center)

  • Robert Macaulay

    (Moffitt Cancer Center)

  • Daphne Dupéré-Richér

    (UF Health Cancer Center)

  • Bin Fang

    (Moffitt Cancer Center)

  • Edward Seto

    (George Washington University)

  • John M. Koomen

    (Moffitt Cancer Center)

  • Jiannong Li

    (Moffitt Cancer Center)

  • Y. Ann Chen

    (Moffitt Cancer Center)

  • Peter A. Forsyth

    (Moffitt Cancer Center)

  • Jonathan D. Licht

    (UF Health Cancer Center)

  • Keiran S. M. Smalley

    (Moffitt Cancer Center
    Moffitt Cancer Center)

Abstract

Melanomas can adopt multiple transcriptional states. Little is known about the epigenetic drivers of these cell states, limiting our ability to regulate melanoma heterogeneity. Here, we identify stress-induced HDAC8 activity as driving melanoma brain metastasis development. Exposure of melanocytes and melanoma cells to multiple stresses increases HDAC8 activation leading to a neural crest-stem cell transcriptional state and an amoeboid, invasive phenotype that increases seeding to the brain. Using ATAC-Seq and ChIP-Seq we show that increased HDAC8 activity alters chromatin structure by increasing H3K27ac and enhancing accessibility at c-Jun binding sites. Functionally, HDAC8 deacetylates the histone acetyltransferase EP300, causing its enzymatic inactivation. This, in turn, increases binding of EP300 to Jun-transcriptional sites and decreases binding to MITF-transcriptional sites. Inhibition of EP300 increases melanoma cell invasion, resistance to stress and increases melanoma brain metastasis development. HDAC8 is identified as a mediator of transcriptional co-factor inactivation and chromatin accessibility that drives brain metastasis.

Suggested Citation

  • Michael F. Emmons & Richard L. Bennett & Alberto Riva & Kanchan Gupta & Larissa Anastasio Da Costa Carvalho & Chao Zhang & Robert Macaulay & Daphne Dupéré-Richér & Bin Fang & Edward Seto & John M. Koo, 2023. "HDAC8-mediated inhibition of EP300 drives a transcriptional state that increases melanoma brain metastasis," Nature Communications, Nature, vol. 14(1), pages 1-18, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-43519-1
    DOI: 10.1038/s41467-023-43519-1
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    References listed on IDEAS

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    1. Panagiotis Karras & Ignacio Bordeu & Joanna Pozniak & Ada Nowosad & Cecilia Pazzi & Nina Raemdonck & Ewout Landeloos & Yannick Herck & Dennis Pedri & Greet Bervoets & Samira Makhzami & Jia Hui Khoo & , 2022. "Author Correction: A cellular hierarchy in melanoma uncouples growth and metastasis," Nature, Nature, vol. 611(7934), pages 4-4, November.
    2. Christophe Dhalluin & Justin E. Carlson & Lei Zeng & Cheng He & Aneel K. Aggarwal & Ming-Ming Zhou & Ming-Ming Zhou, 1999. "Structure and ligand of a histone acetyltransferase bromodomain," Nature, Nature, vol. 399(6735), pages 491-496, June.
    3. Panagiotis Karras & Ignacio Bordeu & Joanna Pozniak & Ada Nowosad & Cecilia Pazzi & Nina Raemdonck & Ewout Landeloos & Yannick Herck & Dennis Pedri & Greet Bervoets & Samira Makhzami & Jia Hui Khoo & , 2022. "A cellular hierarchy in melanoma uncouples growth and metastasis," Nature, Nature, vol. 610(7930), pages 190-198, October.
    4. Judith Müller & Oscar Krijgsman & Jennifer Tsoi & Lidia Robert & Willy Hugo & Chunying Song & Xiangju Kong & Patricia A. Possik & Paulien D. M. Cornelissen-Steijger & Marnix H Geukes Foppen & Kristel , 2014. "Low MITF/AXL ratio predicts early resistance to multiple targeted drugs in melanoma," Nature Communications, Nature, vol. 5(1), pages 1-15, December.
    5. Annelien Verfaillie & Hana Imrichova & Zeynep Kalender Atak & Michael Dewaele & Florian Rambow & Gert Hulselmans & Valerie Christiaens & Dmitry Svetlichnyy & Flavie Luciani & Laura Van den Mooter & So, 2015. "Decoding the regulatory landscape of melanoma reveals TEADS as regulators of the invasive cell state," Nature Communications, Nature, vol. 6(1), pages 1-16, May.
    6. Matthew A. Deardorff & Masashige Bando & Ryuichiro Nakato & Erwan Watrin & Takehiko Itoh & Masashi Minamino & Katsuya Saitoh & Makiko Komata & Yuki Katou & Dinah Clark & Kathryn E. Cole & Elfride De B, 2012. "HDAC8 mutations in Cornelia de Lange syndrome affect the cohesin acetylation cycle," Nature, Nature, vol. 489(7415), pages 313-317, September.
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