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Loss of embryonically-derived Kupffer cells during hypercholesterolemia accelerates atherosclerosis development

Author

Listed:
  • Rebecca Fima

    (INSERM, UMRS 1166)

  • Sébastien Dussaud

    (INSERM, UMRS 1166)

  • Cheïma Benbida

    (INSERM, UMRS 1166)

  • Margault Blanchet

    (INSERM, UMRS 1166)

  • François Lanthiez

    (Sorbonne Université)

  • Lucie Poupel

    (INSERM, UMRS 1166)

  • Claudia Brambilla

    (INSERM, UMRS 1166)

  • Adélaïde Gélineau

    (INSERM, UMRS 1166)

  • Mattia Dessena

    (INSERM, UMRS 1166
    University of Parma)

  • Marina Blanc

    (INSERM, UMRS 1166)

  • Cédric Lerévérend

    (INSERM, UMRS 1166)

  • Martine Moreau

    (INSERM, UMRS 1166)

  • Alexandre Boissonnas

    (Sorbonne Université)

  • Emmanuel L. Gautier

    (INSERM, UMRS 1166)

  • Thierry Huby

    (INSERM, UMRS 1166)

Abstract

Hypercholesterolemia is a major risk factor for atherosclerosis and associated cardiovascular diseases. The liver plays a key role in the regulation of plasma cholesterol levels and hosts a large population of tissue-resident macrophages known as Kupffer cells (KCs). KCs are located in the hepatic sinusoids where they ensure key functions including blood immune surveillance. However, how KCs homeostasis is affected by the build-up of cholesterol-rich lipoproteins that occurs in the circulation during hypercholesterolemia remains unknown. Here, we show that embryo-derived KCs (EmKCs) accumulate large amounts of lipoprotein-derived cholesterol, in part through the scavenger receptor CD36, and massively expand early after the induction of hypercholesterolemia. After this rapid adaptive response, EmKCs exhibit mitochondrial oxidative stress and their numbers gradually diminish while monocyte-derived KCs (MoKCs) with reduced cholesterol-loading capacities seed the KC pool. Decreased proportion of EmKCs in the KC pool enhances liver cholesterol content and exacerbates hypercholesterolemia, leading to accelerated atherosclerotic plaque development. Together, our data reveal that KC homeostasis is perturbed during hypercholesterolemia, which in turn alters the control of plasma cholesterol levels and increases atherosclerosis.

Suggested Citation

  • Rebecca Fima & Sébastien Dussaud & Cheïma Benbida & Margault Blanchet & François Lanthiez & Lucie Poupel & Claudia Brambilla & Adélaïde Gélineau & Mattia Dessena & Marina Blanc & Cédric Lerévérend & M, 2024. "Loss of embryonically-derived Kupffer cells during hypercholesterolemia accelerates atherosclerosis development," Nature Communications, Nature, vol. 15(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-52735-2
    DOI: 10.1038/s41467-024-52735-2
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    References listed on IDEAS

    as
    1. Anita Gola & Michael G. Dorrington & Emily Speranza & Claudia Sala & Rochelle M. Shih & Andrea J. Radtke & Harikesh S. Wong & Antonio P. Baptista & Jonathan M. Hernandez & Gastone Castellani & Iain D., 2021. "Author Correction: Commensal-driven immune zonation of the liver promotes host defence," Nature, Nature, vol. 597(7874), pages 1-1, September.
    2. Xuchu Que & Ming-Yow Hung & Calvin Yeang & Ayelet Gonen & Thomas A. Prohaska & Xiaoli Sun & Cody Diehl & Antti Määttä & Dalia E. Gaddis & Karen Bowden & Jennifer Pattison & Jeffrey G. MacDonald & Sepp, 2018. "Publisher Correction: Oxidized phospholipids are proinflammatory and proatherogenic in hypercholesterolaemic mice," Nature, Nature, vol. 561(7724), pages 43-43, September.
    3. Xuchu Que & Ming-Yow Hung & Calvin Yeang & Ayelet Gonen & Thomas A. Prohaska & Xiaoli Sun & Cody Diehl & Antti Määttä & Dalia E. Gaddis & Karen Bowden & Jennifer Pattison & Jeffrey G. MacDonald & Sepp, 2018. "Oxidized phospholipids are proinflammatory and proatherogenic in hypercholesterolaemic mice," Nature, Nature, vol. 558(7709), pages 301-306, June.
    4. Charlotte L. Scott & Fang Zheng & Patrick De Baetselier & Liesbet Martens & Yvan Saeys & Sofie De Prijck & Saskia Lippens & Chloé Abels & Steve Schoonooghe & Geert Raes & Nick Devoogdt & Bart N. Lambr, 2016. "Bone marrow-derived monocytes give rise to self-renewing and fully differentiated Kupffer cells," Nature Communications, Nature, vol. 7(1), pages 1-10, April.
    5. Anita Gola & Michael G. Dorrington & Emily Speranza & Claudia Sala & Rochelle M. Shih & Andrea J. Radtke & Harikesh S. Wong & Antonio P. Baptista & Jonathan M. Hernandez & Gastone Castellani & Iain D., 2021. "Commensal-driven immune zonation of the liver promotes host defence," Nature, Nature, vol. 589(7840), pages 131-136, January.
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