HArmonized single-cell RNA-seq Cell type Assisted Deconvolution (HASCAD)

Yen-Jung Chiu; Chung-En Ni; Yen-Hua Huang

doi:10.1186/s12920-023-01674-w

HArmonized single-cell RNA-seq Cell type Assisted Deconvolution (HASCAD)

BMC Med Genomics. 2023 Oct 31;16(Suppl 2):272. doi: 10.1186/s12920-023-01674-w.

Authors

Yen-Jung Chiu^{1

2}, Chung-En Ni¹, Yen-Hua Huang^{3

4}

Affiliations

¹ Institute of Biomedical Informatics, National Yang Ming Chiao Tung University, Taipei, 112, Taiwan.
² Department of Biomedical Engineering, Ming Chuan University, Taoyuan, 333, Taiwan.
³ Institute of Biomedical Informatics, National Yang Ming Chiao Tung University, Taipei, 112, Taiwan. yhhuang@nycu.edu.tw.
⁴ Center for Systems and Synthetic Biology, National Yang Ming Chiao Tung University, Taipei, 112, Taiwan. yhhuang@nycu.edu.tw.

Abstract

Background: Cell composition deconvolution (CCD) is a type of bioinformatic task to estimate the cell fractions from bulk gene expression profiles, such as RNA-seq. Many CCD models were developed to perform linear regression analysis using reference gene expression signatures of distinct cell types. Reference gene expression signatures could be generated from cell-specific gene expression profiles, such as scRNA-seq. However, the batch effects and dropout events frequently observed across scRNA-seq datasets have limited the performances of CCD methods.

Methods: We developed a deep neural network (DNN) model, HASCAD, to predict the cell fractions of up to 15 immune cell types. HASCAD was trained using the bulk RNA-seq simulated from three scRNA-seq datasets that have been normalized by using a Harmony-Symphony based strategy. Mean square error and Pearson correlation coefficient were used to compare the performance of HASCAD with those of other widely used CCD methods. Two types of datasets, including a set of simulated bulk RNA-seq, and three human PBMC RNA-seq datasets, were arranged to conduct the benchmarks.

Results: HASCAD is useful for the investigation of the impacts of immune cell heterogeneity on the therapeutic effects of immune checkpoint inhibitors, since the target cell types include the ones known to play a role in anti-tumor immunity, such as three subtypes of CD8 T cells and three subtypes of CD4 T cells. We found that the removal of batch effects in the reference scRNA-seq datasets could benefit the task of CCD. Our benchmarks showed that HASCAD is more suitable for analyzing bulk RNA-seq data, compared with the two widely used CCD methods, CIBERSORTx and quanTIseq. We applied HASCAD to analyze the liver cancer samples of TCGA-LIHC, and found that there were significant associations of the predicted abundance of Treg and effector CD8 T cell with patients' overall survival.

Conclusion: HASCAD could predict the cell composition of the PBMC bulk RNA-seq and classify the cell type from pure bulk RNA-seq. The model of HASCAD is available at https://github.com/holiday01/HASCAD .

Keywords: Cell composition deconvolution; Deep learning; Harmonization; RNA-seq.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Gene Expression Profiling / methods
Humans
Leukocytes, Mononuclear* / metabolism
Neoplasms* / metabolism
RNA-Seq
Sequence Analysis, RNA / methods
Single-Cell Gene Expression Analysis
Transcriptome