Nature Communications (May 2023)

Spatial metabolomics reveals glycogen as an actionable target for pulmonary fibrosis

  • Lindsey R. Conroy,
  • Harrison A. Clarke,
  • Derek B. Allison,
  • Samuel Santos Valenca,
  • Qi Sun,
  • Tara R. Hawkinson,
  • Lyndsay E. A. Young,
  • Juanita E. Ferreira,
  • Autumn V. Hammonds,
  • Jaclyn B. Dunne,
  • Robert J. McDonald,
  • Kimberly J. Absher,
  • Brittany E. Dong,
  • Ronald C. Bruntz,
  • Kia H. Markussen,
  • Jelena A. Juras,
  • Warren J. Alilain,
  • Jinze Liu,
  • Matthew S. Gentry,
  • Peggi M. Angel,
  • Christopher M. Waters,
  • Ramon C. Sun

DOI
https://doi.org/10.1038/s41467-023-38437-1
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 18

Abstract

Read online

Abstract Matrix assisted laser desorption/ionization imaging has greatly improved our understanding of spatial biology, however a robust bioinformatic pipeline for data analysis is lacking. Here, we demonstrate the application of high-dimensionality reduction/spatial clustering and histopathological annotation of matrix assisted laser desorption/ionization imaging datasets to assess tissue metabolic heterogeneity in human lung diseases. Using metabolic features identified from this pipeline, we hypothesize that metabolic channeling between glycogen and N-linked glycans is a critical metabolic process favoring pulmonary fibrosis progression. To test our hypothesis, we induced pulmonary fibrosis in two different mouse models with lysosomal glycogen utilization deficiency. Both mouse models displayed blunted N-linked glycan levels and nearly 90% reduction in endpoint fibrosis when compared to WT animals. Collectively, we provide conclusive evidence that lysosomal utilization of glycogen is required for pulmonary fibrosis progression. In summary, our study provides a roadmap to leverage spatial metabolomics to understand foundational biology in pulmonary diseases.