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METTL9 sustains vertebrate neural development primarily via non-catalytic functions

Author

Listed:
  • Azzurra Codino

    (Via Enrico Melen 83)

  • Luca Spagnoletti

    (Via Enrico Melen 83)

  • Claudia Olobardi

    (via Luca Ghini 13)

  • Alessandro Cuomo

    (European Institute of Oncology IRCCS)

  • Helena Santos-Rosa

    (Tennis Court Road)

  • Martina Palomba

    (Via Morego 30)

  • Natasha Margaroli

    (Via Morego 30)

  • Stefania Girotto

    (Via Morego 30)

  • Rita Scarpelli

    (Via Morego 30)

  • Shi-Lu Luan

    (10 Tennis Court Road
    MRC Laboratory of Molecular Biology)

  • Eleonora Crocco

    (Via Giuseppe Moruzzi)

  • Paolo Bianchini

    (Via Enrico Melen 83)

  • Andrew J. Bannister

    (Tennis Court Road)

  • Stefano Gustincich

    (Via Enrico Melen 83)

  • Tony Kouzarides

    (Tennis Court Road)

  • Riccardo Rizzo

    (Via Monteroni)

  • Isaia Barbieri

    (10 Tennis Court Road
    Via Nizza 52)

  • Federico Cremisi

    (Via Giuseppe Moruzzi)

  • Robert Vignali

    (via Luca Ghini 13)

  • Luca Pandolfini

    (Via Enrico Melen 83)

Abstract

METTL9 is an enzyme catalysing N1-methylation of histidine residues (1MH) within eukaryotic proteins. Given its high expression in vertebrate nervous system and its potential association with neurodevelopmental delay, we dissected Mettl9 role during neural development. We generated three distinct mouse embryonic stem cell lines: a complete Mettl9 knock-out (KO), an inducible METTL9 Degron and a line endogenously expressing a catalytically inactive protein, and assessed their ability to undergo neural differentiation. In parallel, we down-regulated mettl9 in Xenopus laevis embryos and characterised their neural development. Our multi-omics data indicate that METTL9 exerts a conserved role in sustaining vertebrate neurogenesis. This is largely independent of its catalytic activity and occurs through modulation of the secretory pathway. METTL9 interacts with key regulators of cellular transport, endocytosis and Golgi integrity; moreover, in Mettl9KO cells Golgi becomes fragmented. Overall, we demonstrate a developmental function of Mettl9 and link it to a 1MH-independent pathway, namely, the maintenance of the secretory system, which is essential throughout neural development.

Suggested Citation

  • Azzurra Codino & Luca Spagnoletti & Claudia Olobardi & Alessandro Cuomo & Helena Santos-Rosa & Martina Palomba & Natasha Margaroli & Stefania Girotto & Rita Scarpelli & Shi-Lu Luan & Eleonora Crocco &, 2025. "METTL9 sustains vertebrate neural development primarily via non-catalytic functions," Nature Communications, Nature, vol. 16(1), pages 1-29, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-62414-5
    DOI: 10.1038/s41467-025-62414-5
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