MitoSplitter: A Mitochondrial Variants-based Method for Efficient Demultiplexing of Pooled Single-cell RNA-seq

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2023 Sep 19

PMID 37725654

Authors

Xinrui Lin

Yingwen Chen

Li Lin

Kun Yin

Rui Cheng

Xin Lin

Xiaoyu Wang

Ye Guo

Zhaorun Wu

Yingkun Zhang

Jin Li

Chaoyong Yang

Jia Song

Affiliations

Soon will be listed here.

Abstract

Single-cell RNA-seq (scRNA-seq) analysis of multiple samples separately can be costly and lead to batch effects. Exogenous barcodes or genome-wide RNA mutations can be used to demultiplex pooled scRNA-seq data, but they are experimentally or computationally challenging and limited in scope. Mitochondrial genomes are small but diverse, providing concise genotype information. We developed "mitoSplitter," an algorithm that demultiplexes samples using mitochondrial RNA (mtRNA) variants, and demonstrated that mtRNA variants can be used to demultiplex large-scale scRNA-seq data. Using affordable computational resources, mitoSplitter can accurately analyze 10 samples and 60,000 cells in 6 h. To avoid the batch effects from separated experiments, we applied mitoSplitter to analyze the responses of five non-small cell lung cancer cell lines to BET (Bromodomain and extraterminal) chemical degradation in a multiplexed fashion. We found the synthetic lethality of inhibition and BET chemical degradation in BET inhibitor-resistant cells. The result indicates that mitoSplitter can accelerate the application of scRNA-seq assays in biomedical research.

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