PLoS Biology (Nov 2020)

SCRINSHOT enables spatial mapping of cell states in tissue sections with single-cell resolution.

  • Alexandros Sountoulidis,
  • Andreas Liontos,
  • Hong Phuong Nguyen,
  • Alexandra B Firsova,
  • Athanasios Fysikopoulos,
  • Xiaoyan Qian,
  • Werner Seeger,
  • Erik Sundström,
  • Mats Nilsson,
  • Christos Samakovlis

DOI
https://doi.org/10.1371/journal.pbio.3000675
Journal volume & issue
Vol. 18, no. 11
p. e3000675

Abstract

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Changes in cell identities and positions underlie tissue development and disease progression. Although single-cell mRNA sequencing (scRNA-Seq) methods rapidly generate extensive lists of cell states, spatially resolved single-cell mapping presents a challenging task. We developed SCRINSHOT (Single-Cell Resolution IN Situ Hybridization On Tissues), a sensitive, multiplex RNA mapping approach. Direct hybridization of padlock probes on mRNA is followed by circularization with SplintR ligase and rolling circle amplification (RCA) of the hybridized padlock probes. Sequential detection of RCA-products using fluorophore-labeled oligonucleotides profiles thousands of cells in tissue sections. We evaluated SCRINSHOT specificity and sensitivity on murine and human organs. SCRINSHOT quantification of marker gene expression shows high correlation with published scRNA-Seq data over a broad range of gene expression levels. We demonstrate the utility of SCRINSHOT by mapping the locations of abundant and rare cell types along the murine airways. The amenability, multiplexity, and quantitative qualities of SCRINSHOT facilitate single-cell mRNA profiling of cell-state alterations in tissues under a variety of native and experimental conditions.