Impact of Variable RNA-Sequencing Depth on Gene Expression Signatures and Target Compound Robustness: Case Study Examining Brain Tumor (Glioma) Disease Progression.

Alexey Stupnikov,Philip D Dunne,Aideen C Roddy,Estelle Healy,Caitriona E Mcinerney,Frank Emmert-Streib,Darragh G Mcart,Alan Gilmore,Kathreena M Kurian,Kevin M Prise,Tom Flannery,Manuel Salto-Tellez,Paul G O’Reilly,Kienan Savage,Stuart A Mcintosh,Hayley P Ellis

doi:10.1200/po.18.00014

Alexey Stupnikov, Philip D Dunne + Show 14 more

Open Access

https://doi.org/10.1200/po.18.00014

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Abstract

PurposeGene expression profiling can uncover biologic mechanisms underlying disease and is important in drug development. RNA sequencing (RNA-seq) is routinely used to assess gene expression, but costs remain high. Sample multiplexing reduces RNA-seq costs; however, multiplexed samples have lower cDNA sequencing depth, which can hinder accurate differential gene expression detection. The impact of sequencing depth alteration on RNA-seq–based downstream analyses such as gene expression connectivity mapping is not known, where this method is used to identify potential therapeutic compounds for repurposing.MethodsIn this study, published RNA-seq profiles from patients with brain tumor (glioma) were assembled into two disease progression gene signature contrasts for astrocytoma. Available treatments for glioma have limited effectiveness, rendering this a disease of poor clinical outcome. Gene signatures were subsampled to simulate sequencing alterations and analyzed in connectivity mapping to investigate target compound robustness.ResultsData loss to gene signatures led to the loss, gain, and consistent identification of significant connections. The most accurate gene signature contrast with consistent patient gene expression profiles was more resilient to data loss and identified robust target compounds. Target compounds lost included candidate compounds of potential clinical utility in glioma (eg, suramin, dasatinib). Lost connections may have been linked to low-abundance genes in the gene signature that closely characterized the disease phenotype. Consistently identified connections may have been related to highly expressed abundant genes that were ever-present in gene signatures, despite data reductions. Potential noise surrounding findings included false-positive connections that were gained as a result of gene signature modification with data loss.ConclusionFindings highlight the necessity for gene signature accuracy for connectivity mapping, which should improve the clinical utility of future target compound discoveries.

Highlights

Gene expression profiling examines the altering state of the transcriptome at many levels
In this study, published RNA sequencing (RNA-seq) profiles from patients with brain tumor were assembled into two disease progression gene signature contrasts for astrocytoma
Data loss to gene signatures led to the loss, gain, and consistent identification of significant connections

Summary

Introduction

Gene expression profiling examines the altering state of the transcriptome at many levels. Sequencing reads are aligned to a reference genome or transcriptome and mapped to an identified region. Transcript abundance is estimated, facilitating the comparison of gene expression profiles. RNA-seq has wider analytical capabilities, including single nucleotide variants, insertion-deletions, gene splice variants, post-transcriptional modifications, and gene fusion detection, but remains costly.[6,7] Experimental techniques developed to minimize sequencing costs include sample multiplexing. Multiplexing involves labeling each sample library with a barcode identifier, allowing multiple libraries to be pooled and sequenced simultaneously, reducing costs.[7,8,9,10] Smaller volumes of RNA are analyzed for multiplexed samples; the downside to multiplexing is reduced sequencing depth for this library type

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