Glucosylceramide synthase modulation ameliorates murine renal pathologies and promotes macrophage effector function in vitro

Agnes Cheong; Florin Craciun; Hervé Husson; Joseph Gans; Javier Escobedo; Yi-Chien Chang; Lilu Guo; Mariana Goncalves; Nathan Kaplan; Laurie A. Smith; Sarah Moreno; Joseph Boulanger; Shiguang Liu; Jacqueline Saleh; Mindy Zhang; Anna S. Blazier; Weiliang Qiu; Andrew Macklin; Tejaswi Iyyanki; Clément Chatelain; Shameer Khader; Thomas A. Natoli; Oxana Ibraghimov-Beskrovnaya; Dimitry Ofengeim; Jonathan D. Proto

doi:10.1038/s42003-024-06606-7

Communications Biology (Aug 2024)

Glucosylceramide synthase modulation ameliorates murine renal pathologies and promotes macrophage effector function in vitro

Agnes Cheong,
Florin Craciun,
Hervé Husson,
Joseph Gans,
Javier Escobedo,
Yi-Chien Chang,
Lilu Guo,
Mariana Goncalves,
Nathan Kaplan,
Laurie A. Smith,
Sarah Moreno,
Joseph Boulanger,
Shiguang Liu,
Jacqueline Saleh,
Mindy Zhang,
Anna S. Blazier,
Weiliang Qiu,
Andrew Macklin,
Tejaswi Iyyanki,
Clément Chatelain,
Shameer Khader,
Thomas A. Natoli,
Oxana Ibraghimov-Beskrovnaya,
Dimitry Ofengeim,
Jonathan D. Proto

Affiliations

Agnes Cheong: Rare and Neurologic Diseases Research, Sanofi
Florin Craciun: Genomics Medicine Unit, Sanofi
Hervé Husson: Genomics Medicine Unit, Sanofi
Joseph Gans: Translational Sciences, Sanofi
Javier Escobedo: Genomics Medicine Unit, Sanofi
Yi-Chien Chang: Translational Sciences, Sanofi
Lilu Guo: Translational Sciences, Sanofi
Mariana Goncalves: Translational Sciences, Sanofi
Nathan Kaplan: Rare and Neurologic Diseases Research, Sanofi
Laurie A. Smith: Rare and Neurologic Diseases Research, Sanofi
Sarah Moreno: Rare and Neurologic Diseases Research, Sanofi
Joseph Boulanger: Research and Development Business Office, Sanofi
Shiguang Liu: Rare Diseases and Rare Blood Disorders Research, Sanofi
Jacqueline Saleh: Rare and Neurologic Diseases Research, Sanofi
Mindy Zhang: Translational Sciences, Sanofi
Anna S. Blazier: Rare and Neurologic Diseases Research, Sanofi
Weiliang Qiu: Non-Clinical Efficacy & Safety, Sanofi
Andrew Macklin: Rare and Neurologic Diseases Research, Sanofi
Tejaswi Iyyanki: Precision Medicine and Computational Biology, Sanofi
Clément Chatelain: Precision Medicine and Computational Biology, Sanofi
Shameer Khader: Precision Medicine and Computational Biology, Sanofi
Thomas A. Natoli: Rare and Neurologic Diseases Research, Sanofi
Oxana Ibraghimov-Beskrovnaya: Rare and Neurologic Diseases Research, Sanofi
Dimitry Ofengeim: Rare and Neurologic Diseases Research, Sanofi
Jonathan D. Proto: Rare and Neurologic Diseases Research, Sanofi

DOI: https://doi.org/10.1038/s42003-024-06606-7
Journal volume & issue: Vol. 7, no. 1
pp. 1 – 15

Abstract

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Abstract While significant advances have been made in understanding renal pathophysiology, less is known about the role of glycosphingolipid (GSL) metabolism in driving organ dysfunction. Here, we used a small molecule inhibitor of glucosylceramide synthase to modulate GSL levels in three mouse models of distinct renal pathologies: Alport syndrome (Col4a3 KO), polycystic kidney disease (Nek8 jck ), and steroid-resistant nephrotic syndrome (Nphs2 cKO). At the tissue level, we identified a core immune-enriched transcriptional signature that was shared across models and enriched in human polycystic kidney disease. Single nuclei analysis identified robust transcriptional changes across multiple kidney cell types, including epithelial and immune lineages. To further explore the role of GSL modulation in macrophage biology, we performed in vitro studies with homeostatic and inflammatory bone marrow-derived macrophages. Cumulatively, this study provides a comprehensive overview of renal dysfunction and the effect of GSL modulation on kidney-derived cells in the setting of renal dysfunction.

Published in Communications Biology

ISSN: 2399-3642 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General)
Website: https://www.nature.com/commsbio/

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