Abstract
The identification of condition-specific genes is key to advancing our understanding of cell fate decisions and disease development. Differential gene expression analysis (DGEA) has been the standard tool for this task. However, the amount of samples that modern transcriptomic technologies allow us to study, makes DGEA a daunting task. On the other hand, experiments with low numbers of replicates lack the statistical power to detect differentially expressed genes. We have previously developed MGFM, a tool for marker gene detection from microarrays, that is particularly useful in the latter case. Here, we have adapted the algorithm behind MGFM to detect markers in RNA-seq data. MGFR groups samples with similar gene expression levels and flags potential markers of a sample type if their highest expression values represent all replicates of this type. We have benchmarked MGFR against other methods and found that its proposed markers accurately characterize the functional identity of different tissues and cell types in standard and single cell RNA-seq datasets. Then, we performed a more detailed analysis for three of these datasets, which profile the transcriptomes of different human tissues, immune and human blastocyst cell types, respectively. MGFR’s predicted markers were compared to gold-standard lists for these datasets and outperformed the other marker detectors. Finally, we suggest novel candidate marker genes for the examined tissues and cell types. MGFR is implemented as a freely available Bioconductor package (https://doi.org/doi:10.18129/B9.bioc.MGFR), which facilitates its use and integration with bioinformatics pipelines.
Highlights
Detection of biomarkers from gene expression datasets, that is, genes expressed in certain samples and not in others, is very useful for distinguishing between different cell types and tissues, as well as for the identificaton of genes with functions specific to those cells and tissues (Forrest et al, 2014)
Differential gene expression analysis (DGEA) has been the approach of choice for this task, in which pairs of samples are compared with fold changes and t -tests
We investigate whether the algorithm behind this tool can be applied to datasets derived from RNA sequencing (RNA-seq) and its single cell versions, which are being extensively applied in biomedical research for the genome-wide evaluation of gene expression levels
Summary
Detection of biomarkers from gene expression datasets, that is, genes expressed in certain samples and not in others, is very useful for distinguishing between different cell types and tissues, as well as for the identificaton of genes with functions specific to those cells and tissues (Forrest et al, 2014). Small sample size experiments lack the adequate power for detecting differential expression (Yu, Fernandez & Brock, 2017). This has led to the development of several methods to pinpoint genes with condition-specific functions. These techniques range from fixed thresholds on the RPKM or FPKM expression values of each sample (Hebenstreit et al, 2011; Wagner, Kin & Lynch, 2013; Will & Helms, 2016), to determination of genes that are significantly expressed in each condition (Kitsak et al, 2016), to information theory- and geometry-inspired methodologies (Schug et al, 2005; Pan et al, 2012)
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