Graph Signal Processing For Cancer Gene Co-Expression Network Analysis

Abstract

Cancer heterogeneity arises from complex molecular interactions. Elucidating systems-level properties of gene interaction networks distinguishing cancer from normal cells is critical for understanding disease mechanisms and developing targeted therapies. Previous works focused only on identifying differences in network structures. In this study, we used graph frequency analysis of cancer genetic signals defined on a co-expression network to describe the spectral properties of underlying cancer systems. We demonstrated that cancer cells exhibit distinctive signatures in the graph frequency content of their gene expression signals. Applying graph frequency filtering, graph Fourier transforms, and its inverse to gene expression from different cancer stages resulted in significant improvements in average F-statistics of the genes compared to using their unfiltered expression levels. We propose graph spectral properties of cancer genetic signals defined on gene co-expression networks as cancer hallmarks with potential application for differential co-expression analysis