Frontiers in Molecular Biosciences (Jan 2024)

The IRAK-M death domain: a tale of three surfaces

  • Berke Gürkan,
  • Berke Gürkan,
  • Hessel Poelman,
  • Hessel Poelman,
  • Liza Pereverzeva,
  • Liza Pereverzeva,
  • Danielle Kruijswijk,
  • Danielle Kruijswijk,
  • Alex F. de Vos,
  • Alex F. de Vos,
  • Anouk G. Groenen,
  • Anouk G. Groenen,
  • Edgar E. Nollet,
  • Edgar E. Nollet,
  • Kanin Wichapong,
  • Esther Lutgens,
  • Tom van der Poll,
  • Tom van der Poll,
  • Tom van der Poll,
  • Jiangfeng Du,
  • W. Joost Wiersinga,
  • W. Joost Wiersinga,
  • W. Joost Wiersinga,
  • Gerry A. F. Nicolaes,
  • Gerry A. F. Nicolaes,
  • Cornelis van ‘t Veer,
  • Cornelis van ‘t Veer

DOI
https://doi.org/10.3389/fmolb.2023.1265455
Journal volume & issue
Vol. 10

Abstract

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The anti-inflammatory interleukin-1 receptor associated kinase-M (IRAK-M) is a negative regulator of MyD88/IRAK-4/IRAK-1 signaling. However, IRAK-M has also been reported to activate NF-κB through the MyD88/IRAK-4/IRAK-M myddosome in a MEKK-3 dependent manner. Here we provide support that IRAK-M uses three surfaces of its Death Domain (DD) to activate NF-κB downstream of MyD88/IRAK-4/IRAK-M. Surface 1, with central residue Trp74, binds to MyD88/IRAK-4. Surface 2, with central Lys60, associates with other IRAK-M DDs to form an IRAK-M homotetramer under the MyD88/IRAK-4 scaffold. Surface 3; with central residue Arg97 is located on the opposite side of Trp74 in the IRAK-M DD tetramer, lacks any interaction points with the MyD88/IRAK-4 complex. Although the IRAK-M DD residue Arg97 is not directly involved in the association with MyD88/IRAK-4, Arg97 was responsible for 50% of the NF-κB activation though the MyD88/IRAK-4/IRAK-M myddosome. Arg97 was also found to be pivotal for IRAK-M’s interaction with IRAK-1, and important for IRAK-M’s interaction with TRAF6. Residue Arg97 was responsible for 50% of the NF-κB generated by MyD88/IRAK-4/IRAK-M myddosome in IRAK-1/MEKK3 double knockout cells. By structural modeling we found that the IRAK-M tetramer surface around Arg97 has excellent properties that allow formation of an IRAK-M homo-octamer. This model explains why mutation of Arg97 results in an IRAK-M molecule with increased inhibitory properties: it still binds to myddosome, competing with myddosome IRAK-1 binding, while resulting in less NF-κB formation. The findings further identify the structure-function properties of IRAK-M, which is a potential therapeutic target in inflammatory disease.

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