Author
Listed:
- Chia-Kuei Mo
(Washington University in St Louis
Washington University in St Louis)
- Jingxian Liu
(Washington University in St Louis
Washington University in St Louis)
- Siqi Chen
(Washington University in St Louis
Washington University in St Louis)
- Erik Storrs
(Washington University in St Louis
Washington University in St Louis)
- Andre Luiz N. Targino da Costa
(Washington University in St Louis
Washington University in St Louis)
- Andrew Houston
(Washington University in St Louis
Washington University in St Louis)
- Michael C. Wendl
(Washington University in St Louis
Washington University in St Louis)
- Reyka G. Jayasinghe
(Washington University in St Louis
Washington University in St Louis)
- Michael D. Iglesia
(Washington University in St Louis
Washington University in St Louis)
- Cong Ma
(Princeton University)
- John M. Herndon
(Washington University in St Louis
Washington University in St Louis)
- Austin N. Southard-Smith
(Washington University in St Louis
Washington University in St Louis)
- Xinhao Liu
(Princeton University)
- Jacqueline Mudd
(Washington University in St Louis)
- Alla Karpova
(Washington University in St Louis
Washington University in St Louis)
- Andrew Shinkle
(Washington University in St Louis
Washington University in St Louis)
- S. Peter Goedegebuure
(Washington University in St Louis
Washington University in St Louis)
- Abdurrahman Taha Mousa Ali Abdelzaher
(Washington University in St Louis
Washington University in St Louis)
- Peng Bo
(Washington University in St Louis
Washington University in St Louis)
- Lauren Fulghum
(Washington University in St Louis
Washington University in St Louis)
- Samantha Livingston
(Washington University in St Louis
Washington University in St Louis)
- Metin Balaban
(Princeton University)
- Angela Hill
(Washington University in St Louis
Washington University in St Louis)
- Joseph E. Ippolito
(Washington University in St Louis)
- Vesteinn Thorsson
(Institute for Systems Biology)
- Jason M. Held
(Washington University in St Louis
Washington University School of Medicine)
- Ian S. Hagemann
(Washington University in St Louis
Washington University in St Louis)
- Eric H. Kim
(Washington University)
- Peter O. Bayguinov
(Washington University School of Medicine)
- Albert H. Kim
(Washington University in St Louis
Washington University School of Medicine)
- Mary M. Mullen
(Washington University)
- Kooresh I. Shoghi
(Washington University in St Louis
Washington University in St Louis)
- Tao Ju
(Washington University in St Louis)
- Melissa A. Reimers
(Washington University School of Medicine)
- Cody Weimholt
(Washington University in St Louis)
- Liang-I Kang
(Washington University in St Louis)
- Sidharth V. Puram
(Washington University in St Louis
Washington University in St Louis
Washington University School of Medicine)
- Deborah J. Veis
(Washington University in St Louis
Washington University in St Louis
Washington University in St Louis)
- Russell Pachynski
(Washington University in St Louis
Washington University in St Louis)
- Katherine C. Fuh
(Washington University in St Louis
University of California, San Francisco)
- Milan G. Chheda
(Washington University in St Louis
Washington University in St Louis)
- William E. Gillanders
(Washington University in St Louis
Washington University in St Louis)
- Ryan C. Fields
(Washington University in St Louis
Washington University in St Louis)
- Benjamin J. Raphael
(Princeton University)
- Feng Chen
(Washington University in St Louis
Washington University in St Louis)
- Li Ding
(Washington University in St Louis
Washington University in St Louis
Washington University in St Louis
Washington University in St Louis)
Abstract
To study the spatial interactions among cancer and non-cancer cells1, we here examined a cohort of 131 tumour sections from 78 cases across 6 cancer types by Visium spatial transcriptomics (ST). This was combined with 48 matched single-nucleus RNA sequencing samples and 22 matched co-detection by indexing (CODEX) samples. To describe tumour structures and habitats, we defined ‘tumour microregions’ as spatially distinct cancer cell clusters separated by stromal components. They varied in size and density among cancer types, with the largest microregions observed in metastatic samples. We further grouped microregions with shared genetic alterations into ‘spatial subclones’. Thirty five tumour sections exhibited subclonal structures. Spatial subclones with distinct copy number variations and mutations displayed differential oncogenic activities. We identified increased metabolic activity at the centre and increased antigen presentation along the leading edges of microregions. We also observed variable T cell infiltrations within microregions and macrophages predominantly residing at tumour boundaries. We reconstructed 3D tumour structures by co-registering 48 serial ST sections from 16 samples, which provided insights into the spatial organization and heterogeneity of tumours. Additionally, using an unsupervised deep-learning algorithm and integrating ST and CODEX data, we identified both immune hot and cold neighbourhoods and enhanced immune exhaustion markers surrounding the 3D subclones. These findings contribute to the understanding of spatial tumour evolution through interactions with the local microenvironment in 2D and 3D space, providing valuable insights into tumour biology.
Suggested Citation
Chia-Kuei Mo & Jingxian Liu & Siqi Chen & Erik Storrs & Andre Luiz N. Targino da Costa & Andrew Houston & Michael C. Wendl & Reyka G. Jayasinghe & Michael D. Iglesia & Cong Ma & John M. Herndon & Aust, 2024.
"Tumour evolution and microenvironment interactions in 2D and 3D space,"
Nature, Nature, vol. 634(8036), pages 1178-1186, October.
Handle:
RePEc:nat:nature:v:634:y:2024:i:8036:d:10.1038_s41586-024-08087-4
DOI: 10.1038/s41586-024-08087-4
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