Abstract
Conventional differential expression analyses have been successfully employed to identify genes whose levels change across experimental conditions. One limitation of this approach is the inability to discover central regulators that control gene expression networks. In addition, while methods for identifying central nodes in a network are widely implemented, the bioinformatics validation process and the theoretical error estimates that reflect the uncertainty in each step of the analysis are rarely considered. Using the betweenness centrality measure, we identified Etv5 as a potential tissue-level regulator in murine neurofibromatosis type 1 (Nf1) low-grade brain tumors (optic gliomas). As such, the expression of Etv5 and Etv5 target genes were increased in multiple independently-generated mouse optic glioma models relative to non-neoplastic (normal healthy) optic nerves, as well as in the cognate human tumors (pilocytic astrocytoma) relative to normal human brain. Importantly, differential Etv5 and Etv5 network expression was not directly the result of Nf1 gene dysfunction in specific cell types, but rather reflects a property of the tumor as an aggregate tissue. Moreover, this differential Etv5 expression was independently validated at the RNA and protein levels. Taken together, the combined use of network analysis, differential RNA expression findings, and experimental validation highlights the potential of the computational network approach to provide new insights into tumor biology.
Highlights
Similar to other ecological systems, mammalian tissues can be considered as complex biological systems, composed of a multitude of cellular and acellular elements that each contribute to overall biosystem function
The edges of the transcription network are given weights based on expression data such that expression data from a normal control group (N, optic nerves from Nf1flox/flox mice, which are equivalent to wild-type mice [2]), result in a “normal” network, while data from a group of optic glioma tumor samples (OPG-1, optic nerves from Nf1flox/null; GFAP-Cre mice, [2]) comprise a “tumor” network
This validation was accomplished by comparing expression levels of Etv5 and its target genes in normal healthy optic nerves and optic gliomas, as well as by determining the cell type expression profiles of those genes
Summary
Similar to other ecological systems, mammalian tissues can be considered as complex biological systems, composed of a multitude of cellular and acellular elements that each contribute to overall biosystem function. The samples are publicly available at: https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi? Microarray Data for Pediatric Pilocytic Astrocytoma: The dataset is available at the NCBI GEO repository, GSE42656 [33] Microarray Data for Juvenile Pilocytic Astrocytoma: The dataset is available at the NCBI GEO repository, GSE12907 The gene expression samples were measured using an Affymetrix Human Genome U133A array. [34]
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