Optimized Design of Single-cell RNA Sequencing Experiments for Cell-type-specific EQTL Analysis

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Oct 31

PMID 33127880

Citations 28

Authors

Igor Mandric

Tommer Schwarz

Arunabha Majumdar

Kangcheng Hou

Leah Briscoe

Richard Perez

Meena Subramaniam

Christoph Hafemeister

Rahul Satija

Chun Jimmie Ye

Bogdan Pasaniuc

Eran Halperin

Affiliations

Soon will be listed here.

Abstract

Single-cell RNA-sequencing (scRNA-Seq) is a compelling approach to directly and simultaneously measure cellular composition and state, which can otherwise only be estimated by applying deconvolution methods to bulk RNA-Seq estimates. However, it has not yet become a widely used tool in population-scale analyses, due to its prohibitively high cost. Here we show that given the same budget, the statistical power of cell-type-specific expression quantitative trait loci (eQTL) mapping can be increased through low-coverage per-cell sequencing of more samples rather than high-coverage sequencing of fewer samples. We use simulations starting from one of the largest available real single-cell RNA-Seq data from 120 individuals to also show that multiple experimental designs with different numbers of samples, cells per sample and reads per cell could have similar statistical power, and choosing an appropriate design can yield large cost savings especially when multiplexed workflows are considered. Finally, we provide a practical approach on selecting cost-effective designs for maximizing cell-type-specific eQTL power which is available in the form of a web tool.

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