RNA Expression Microarrays (REMs), a High-throughput Method to Measure Differences in Gene Expression in Diverse Biological Samples

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2004 Aug 27

PMID 15329382

Citations 4

Authors

Charles E Rogler

Tatyana Tchaikovskaya

Raquel Norel

Aldo Massimi

Christopher Plescia

Eugeny Rubashevsky

Paul Siebert

Leslie E Rogler

Affiliations

Soon will be listed here.

Abstract

We have developed RNA expression microarrays (REMs), in which each spot on a glass support is composed of a population of cDNAs synthesized from a cell or tissue sample. We used simultaneous hybridization with test and reference (housekeeping) genes to calculate an expression ratio based on normalization with the endogenous reference gene. A test REM containing artificial mixtures of liver cDNA and dilutions of the bacterial LysA gene cDNA demonstrated the feasibility of detecting transcripts at a sensitivity of four copies of LysA mRNA per liver cell equivalent. Furthermore, LysA cDNA detection varied linearly across a standard curve that matched the sensitivity of quantitative real-time PCR. In REMs with real samples, we detected organ-specific expression of albumin, Hnf-4 and Igfbp-1, in a set of mouse organ cDNA populations and c-Myc expression in tumor samples in paired tumor/normal tissue cDNA samples. REMs extend the use of classic microarrays in that a single REM can contain cDNAs from hundreds to thousands of cell or tissue samples each representing a specific physiological or pathophysiological state. REMs will extend the analysis of valuable samples by providing a common broad based platform for their analysis and will promote research aimed at defining gene functions, by broadening our understanding of their expression patterns in health and disease.

Citing Articles

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Preservation of ranking order in the expression of human Housekeeping genes.

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Assessment of gene expression in many samples using vertical arrays.

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DNA microarrays on a dendron-modified surface improve significantly the detection of single nucleotide variations in the p53 gene.

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