Abstract

The genetic etiology of childhood cancers still remains largely unknown. It is therefore essential to develop novel strategies to unravel the spectrum of pediatric cancer genes. Statistical network modeling techniques have emerged as powerful methodologies for enabling the inference of gene-disease relationship and have been performed on adult but not pediatric cancers. We performed a deep multi-layer understanding of pan-cancer transcriptome data selected from the Treehouse Childhood Cancer Initiative through a co-expression network analysis. We identified six modules strongly associated with pediatric tumor histotypes that were functionally linked to developmental processes. Topological analyses highlighted that pediatric cancer predisposition genes and potential therapeutic targets were central regulators of cancer-histotype specific modules. A module was related to multiple pediatric malignancies with functions involved in DNA repair and cell cycle regulation. This canonical oncogenic module gathered most of the childhood cancer predisposition genes and clinically actionable genes. In pediatric acute leukemias, the driver genes were co-expressed in a module related to epigenetic and post-transcriptional processes, suggesting a critical role of these pathways in the progression of hematologic malignancies. This integrative pan-cancer study provides a thorough characterization of pediatric tumor-associated modules and paves the way for investigating novel candidate genes involved in childhood tumorigenesis.

Highlights

  • The genetic etiology of childhood cancers still remains largely unknown

  • We hypothesized that transcriptome data from pediatric cancer samples could provide a thorough understanding of the key genes and pathways implicated in childhood tumorigenesis

  • The median age at diagnosis (MAD) was higher compared to previous studies for Neuroblastoma (NBL; 2.9 years old in our study vs 1.5 years old reported previously)[18], Wilms Tumor (WT; 4 vs 3.5 years old)[19], Medulloblastoma (MBL; 7 vs 6 years old)[20] and Acute Myeloid Leukemia (AML; 8.8 vs 6.4 years old)[21]

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Summary

Introduction

The genetic etiology of childhood cancers still remains largely unknown. It is essential to develop novel strategies to unravel the spectrum of pediatric cancer genes. A module was related to multiple pediatric malignancies with functions involved in DNA repair and cell cycle regulation This canonical oncogenic module gathered most of the childhood cancer predisposition genes and clinically actionable genes. The driver genes were co-expressed in a module related to epigenetic and post-transcriptional processes, suggesting a critical role of these pathways in the progression of hematologic malignancies This integrative pan-cancer study provides a thorough characterization of pediatric tumor-associated modules and paves the way for investigating novel candidate genes involved in childhood tumorigenesis. A system-level understanding of how the genetic mutations affect transcriptional profile has been provided in adult pan-cancer data[16] Such analyses revealed common functional gene clusters that are shared by multiple adult cancer types

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