Abstract
Subpopulation identification, usually via some form of unsupervised clustering, is a fundamental step in the analysis of many single-cell RNA-seq data sets. This has motivated the development and application of a broad range of clustering methods, based on various underlying algorithms. Here, we provide a systematic and extensible performance evaluation of 12 clustering algorithms, including both methods developed explicitly for scRNA-seq data and more general-purpose methods. The methods were evaluated using 9 publicly available scRNA-seq data sets as well as three simulations with varying degree of cluster separability. The same feature selection approaches were used for all methods, allowing us to focus on the investigation of the performance of the clustering algorithms themselves. We evaluated the ability of recovering known subpopulations, the stability and the run time of the methods. Additionally, we investigated whether the performance could be improved by generating consensus partitions from multiple individual clustering methods. We found substantial differences in the performance, run time and stability between the methods, with SC3 and Seurat showing the most favorable results. Additionally, we found that consensus clustering typically did not improve the performance compared to the best of the combined methods, but that several of the top-performing methods already perform some type of consensus clustering. The R scripts providing an extensible framework for the evaluation of new methods and data sets are available on GitHub (https://github.com/markrobinsonuzh/scRNAseq_clustering_comparison).
Highlights
Recent advances in single-cell RNA-seq technologies have enabled the simultaneous measurement of expression levels of thousands of genes across hundreds to thousands of individual cells[1,2,3,4,5,6,7,8]
Computational analyses are complicated by the high variability, low capture efficiency and high dropout rates of scRNA-seq assays[9,10,11], as well as by strong batch effects that are often confounded by the experimental factor of interest[12]
We evaluate 12 clustering algorithms, including both methods developed for scRNA-seq data, methods developed for other types of single-cell data, and more general approaches, on a total of 12 different data sets
Summary
Recent advances in single-cell RNA-seq (scRNA-seq) technologies have enabled the simultaneous measurement of expression levels of thousands of genes across hundreds to thousands of individual cells[1,2,3,4,5,6,7,8]. This opens up new possibilities for deconvolution of expression patterns seen in bulk samples, detection of previously unknown cell populations and deeper characterization of known ones. A large number of clustering approaches designed for or adapted to these types of assays are available in the literature
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