Abstract
RNA microarrays and RNA-seq are nowadays standard technologies to study the transcriptional activity of cells. Most studies focus on tracking transcriptional changes caused by specific experimental conditions. Information referring to genes up- and downregulation is evaluated analyzing the behaviour of relatively large population of cells by averaging its properties. However, even assuming perfect sample homogeneity, different subpopulations of cells can exhibit diverse transcriptomic profiles, as they may follow different regulatory/signaling pathways. The purpose of this study is to provide a novel methodological scheme to account for possible internal, functional heterogeneity in homogeneous cell lines, including cancer ones. We propose a novel computational method to infer the proportion between subpopulations of cells that manifest various functional behaviour in a given sample. Our method was validated using two datasets from RNA microarray experiments. Both experiments aimed to examine cell viability in specific experimental conditions. The presented methodology can be easily extended to RNA-seq data as well as other molecular processes. Moreover, it complements standard tools to indicate most important networks from transcriptomic data and in particular could be useful in the analysis of cancer cell lines affected by biologically active compounds or drugs.
Highlights
RNA microarrays and RNA-seq are one of the most popular high-throughput methods used in the advanced medical diagnostics, personalized medicine, and basic research
We found that conditioned media were sufficient to trigger ovarian cancer cell divisions regardless of serum depletion
In this study we presented a novel methodological approach to quantify the functional heterogeneity of a homogeneous cell population based on transcriptomic data
Summary
RNA microarrays and RNA-seq are one of the most popular high-throughput methods used in the advanced medical diagnostics, personalized medicine, and basic research. An application of these methods provides an insight into the full transcriptome of examined sample, the knowledge gained in this way is based upon an averaged gene expression in a bulk population. This fact introduces a specific bias into the outcome of gene expression measurements, especially, because a biological material is rarely homogeneous. A couple of methods were proposed to deal with the problem of mixed cell types in biological samples, that is, tissues They are based on the expression matrix decomposition and yield the information about (i) proportions of different cell types in a given sample and (ii) expression profiles specific for each detected cell-type. In [3], authors introduce the method based on the least squares nonnegative matrix factorization
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