Abstract
Differential gene expression profiles often provide important clues for gene functions. While reverse transcription quantitative real-time polymerase chain reaction (RT-qPCR) is an important tool, the validity of the results depends heavily on the choice of proper reference genes. In this study, we employed new and published RNA-sequencing (RNA-Seq) datasets (26 sequencing libraries in total) to evaluate reference genes reported in previous soybean studies. In silico PCR showed that 13 out of 37 previously reported primer sets have multiple targets, and 4 of them have amplicons with different sizes. Using a probabilistic approach, we identified new and improved candidate reference genes. We further performed 2 validation tests (with 26 RNA samples) on 8 commonly used reference genes and 7 newly identified candidates, using RT-qPCR. In general, the new candidate reference genes exhibited more stable expression levels under the tested experimental conditions. The three newly identified candidate reference genes Bic-C2, F-box protein2, and VPS-like gave the best overall performance, together with the commonly used ELF1b. It is expected that the proposed probabilistic model could serve as an important tool to identify stable reference genes when more soybean RNA-Seq data from different growth stages and treatments are used.
Highlights
Expression of a gene may be tied to its involvement in a particular developmental stage, a response to environmental signals, and other cellular functions [1]
Reverse transcription coupled with realtime quantitative polymerase chain reaction (RT-quantitative PCR (qPCR)) offers a more sensitive way to measure gene expression, which is an important tool in plant research [2]
For a quantitative comparison of gene expressions using RT-qPCR, one critical factor is to choose suitable reference genes to normalize the expressions of target genes under different conditions [3,4,5,6,7]
Summary
Expression of a gene may be tied to its involvement in a particular developmental stage, a response to environmental signals, and other cellular functions [1]. Tracking the changes in the expression level is an important initial step to study the possible functions of a gene. To compare the expression of a target gene in different samples, the expression should first be normalized to a common factor. For a quantitative comparison of gene expressions using RT-qPCR, one critical factor is to choose suitable reference genes to normalize the expressions of target genes under different conditions [3,4,5,6,7]. It is eventually known that many housekeeping genes do not express uniformly across different experimental settings [4, 6], and the choice of proper reference genes remains an important issue in gene expression analyses
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