Simulation and analysis tools for single-cell RNA sequencing data

single-cell
rna-seq
simulation
database
splatter
scRNA-tools
software
Selected talk at the Genome Informatics 2017 conference describing Splatter and the scRNA-tools database
Authors

Luke Zappia

Belinda Phipson

Alicia Oshlack

Date

November 1, 2017

Event

Genome Informatics 2017 (Cold Spring Harbor Labs, Cold Spring Harbor, USA)

Links
Abstract

Single-cell RNA sequencing (scRNA-seq) is rapidly becoming a tool of choice for biologists who wish to investigate gene expression. In contrast to traditional bulk RNA-seq experiments, which measure expression averaged across millions of cells, single-cell experiments can be used to observe how genes are expressed in individual cells. Along with the dramatic increase in resolution provided by scRNA-seq comes an array of bioinformatics challenges. Single-cell data is relatively sparse (for both biological and technical reasons), quality control is difficult and it is unclear how to replicate measurements. Researchers have risen to address these challenges and there are currently more than 125 software tools available for analysing scRNA-seq data. We have catalogued these software tools in the scRNA-tools database (www.scRNA-tools.org). Analysis of this database shows that there are now methods available for a wide range of tasks, from pre-processing unique molecular identifiers to detecting allele-specific expression. However, the biggest areas of development have been in clustering cells to identify cell types and ordering of cells to understand dynamic processes. We also find that the R statistical programming language is the most popular platform for scRNA-seq analysis tools, followed by Python, and that the majority of tools have been described in peer-reviewed papers or preprints and are available under open-source software licenses.

With the ever increasing number of analysis methods available it is important to be able to assess and compare the performance, quality and limitations of an analysis tool. This is often done, at least in part, by testing methods on simulated datasets where the true answers are known. Unfortunately, current scRNA-seq simulations are frequently poorly documented, not reproducible and do not demonstrate similarity to real data or experimental designs. To address these concerns we have developed Splatter, a Bioconductor R package for reproducible simulation of scRNA-seq datasets. Splatter is a simulation framework that currently includes four previously published simulation models, allowing users to estimate parameters from real data in order to easily generate realistic synthetic scRNA-seq datasets. Here we discuss some of the challenges of simulating scRNA-seq data and present a comparison of the simulation methods available in Splatter (bioconductor.org/packages/splatter). As part of Splatter we also introduce our own simulation model, Splat, capable of reproducing scRNA-seq datasets with multiple groups of cells, differentiation paths or batch effects.