Flura-seq identifies organ-specific metabolic adaptations during early metastatic colonization

• Main Authors: Harihar Basnet, Lin Tian, Karuna Ganesh, Yun-Han Huang, Danilo G Macalinao, Edi Brogi, Lydia WS Finley, Joan Massagué
• Format: Article
• Language: English
• Published: eLife Sciences Publications Ltd 2019-03-01
• Series: eLife
• Subjects: In situ transcriptomics; oxidative stress; brain metastasis; lung metastasis; breast cancer
• Online Access: https://elifesciences.org/articles/43627
• ISSN: 2050-084X

Metastasis-initiating cells dynamically adapt to the distinct microenvironments of different organs, but these early adaptations are poorly understood due to the limited sensitivity of in situ transcriptomics. We developed fluorouracil-labeled RNA sequencing (Flura-seq) for in situ analysis with high sensitivity. Flura-seq utilizes cytosine deaminase (CD) to convert fluorocytosine to fluorouracil, metabolically labeling nascent RNA in rare cell populations in situ for purification and sequencing. Flura-seq revealed hundreds of unique, dynamic organ-specific gene signatures depending on the microenvironment in mouse xenograft breast cancer micrometastases. Specifically, the mitochondrial electron transport Complex I, oxidative stress and counteracting antioxidant programs were induced in pulmonary micrometastases, compared to mammary tumors or brain micrometastases. We confirmed lung metastasis-specific increase in oxidative stress and upregulation of antioxidants in clinical samples, thus validating Flura-seq’s utility in identifying clinically actionable microenvironmental adaptations in early metastasis. The sensitivity, robustness and economy of Flura-seq are broadly applicable beyond cancer research.