Comparison of Microarray Platforms for Measuring Differential MicroRNA Expression in Paired Normal/cancer Colon Tissues

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2012 Oct 3

PMID 23028787

Citations 29

Authors

Maurizio Callari

Matteo Dugo

Valeria Musella

Edoardo Marchesi

Giovanna Chiorino

Maurizia Mello Grand

Marco Alessandro Pierotti

Maria Grazia Daidone

Silvana Canevari

Loris De Cecco

Affiliations

Soon will be listed here.

Abstract

Background: Microarray technology applied to microRNA (miRNA) profiling is a promising tool in many research fields; nevertheless, independent studies characterizing the same pathology have often reported poorly overlapping results. miRNA analysis methods have only recently been systematically compared but only in few cases using clinical samples.

Methodology/principal Findings: We investigated the inter-platform reproducibility of four miRNA microarray platforms (Agilent, Exiqon, Illumina, and Miltenyi), comparing nine paired tumor/normal colon tissues. The most concordant and selected discordant miRNAs were further studied by quantitative RT-PCR. Globally, a poor overlap among differentially expressed miRNAs identified by each platform was found. Nevertheless, for eight miRNAs high agreement in differential expression among the four platforms and comparability to qRT-PCR was observed. Furthermore, most of the miRNA sets identified by each platform are coherently enriched in data from the other platforms and the great majority of colon cancer associated miRNA sets derived from the literature were validated in our data, independently from the platform. Computational integration of miRNA and gene expression profiles suggested that anti-correlated predicted target genes of differentially expressed miRNAs are commonly enriched in cancer-related pathways and in genes involved in glycolysis and nutrient transport.

Conclusions: Technical and analytical challenges in measuring miRNAs still remain and further research is required in order to increase consistency between different microarray-based methodologies. However, a better inter-platform agreement was found by looking at miRNA sets instead of single miRNAs and through a miRNAs - gene expression integration approach.

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