iScience (Jul 2024)

sNucConv: A bulk RNA-seq deconvolution method trained on single-nucleus RNA-seq data to estimate cell-type composition of human adipose tissues

  • Gil Sorek,
  • Yulia Haim,
  • Vered Chalifa-Caspi,
  • Or Lazarescu,
  • Maya Ziv-Agam,
  • Tobias Hagemann,
  • Pamela Arielle Nono Nankam,
  • Matthias Blüher,
  • Idit F. Liberty,
  • Oleg Dukhno,
  • Ivan Kukeev,
  • Esti Yeger-Lotem,
  • Assaf Rudich,
  • Liron Levin

Journal volume & issue
Vol. 27, no. 7
p. 110368

Abstract

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Summary: Deconvolution algorithms mostly rely on single-cell RNA-sequencing (scRNA-seq) data applied onto bulk RNA-sequencing (bulk RNA-seq) to estimate tissues’ cell-type composition, with performance accuracy validated on deposited databases. Adipose tissues’ cellular composition is highly variable, and adipocytes can only be captured by single-nucleus RNA-sequencing (snRNA-seq). Here we report the development of sNucConv, a Scaden deep-learning-based deconvolution tool, trained using 5 hSAT and 7 hVAT snRNA-seq-based data corrected by (i) snRNA-seq/bulk RNA-seq highly correlated genes and (ii) individual cell-type regression models. Applying sNucConv on our bulk RNA-seq data resulted in cell-type proportion estimation of 15 and 13 cell types, with accuracy of R = 0.93 (range: 0.76–0.97) and R = 0.95 (range: 0.92–0.98) for hVAT and hSAT, respectively. This performance level was further validated on an independent set of samples (5 hSAT; 5 hVAT). The resulting model was depot specific, reflecting depot differences in gene expression patterns. Jointly, sNucConv provides proof-of-concept for producing validated deconvolution models for tissues un-amenable to scRNA-seq.

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