Reference Genes for Normalization: a Study of Rat Brain Tissue

Overview

Journal Synapse

Specialty Neurology

Date 2008 Feb 5

PMID 18241047

Citations 107

Authors

Birgit Egeskov Bonefeld

Betina Elfving

Gregers Wegener

Affiliations

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Abstract

Quantitative real-time polymerase chain reaction (qPCR) has become a widely used tool in the search for disease genes. When examining gene expression with qPCR in psychiatric diseases, endogenous reference gene(s) must be used for normalization. Traditionally, genes such as beta-actin (ActB), Gapd, and 18s rRNA, assumed to be stably expressed, have been used for normalization. However, it has become clear that expression of these genes is influenced by different experimental paradigms. Since stable gene expression of houskeeping genes (HKGs), therefore, cannot be expected, alternative strategies are warranted. With the overall aim to inspect the gene expression of three target genes, NMDAR1, SORT, and CREB, in rat hippocampus, we tested a panel of eight HKGs, 18s rRNA, ActB, CycA, Gapd, Hmbs, Hprt1, Rpl13A, and Ywhaz in order to select the most stably expressed gene, using the NormFinder and geNorm software applets. Additionally, we have applied four different normalization approaches for normalization of the three target genes. We found using the NormFinder software that Ywhaz is the most stably expressed gene among the eight tested HKGs. However, the results of the analysis of the target genes are highly dependent on the choice of normalization approach. Moreover, the number of HKGs, used for selection of the most stable HKG, also influences on the result of the gene expression analysis of target genes. These results underline the importance of choosing a proper normalization strategy when analyzing gene expression with qPCR. The strategy should be unbiased and carried out in every specific experimental setting.

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