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Open Access

Peer-reviewed

Research Article

Selection of Reference Genes for qRT-PCR Analysis of Gene Expression in Stipa grandis during Environmental Stresses

  • Dongli Wan ,

    Contributed equally to this work with: Dongli Wan, Yongqing Wan

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

  • Yongqing Wan ,

    Contributed equally to this work with: Dongli Wan, Yongqing Wan

    Affiliation College of Life Sciences, Inner Mongolia Agricultural University, Hohhot, China

  • Qi Yang,

    Affiliation College of Life Sciences, Inner Mongolia Agricultural University, Hohhot, China

  • Bo Zou,

    Affiliation College of Life Sciences, Inner Mongolia Agricultural University, Hohhot, China

  • Weibo Ren,

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

  • Yong Ding,

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

  • Zhen Wang,

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

  • Ruigang Wang,

    Affiliation College of Life Sciences, Inner Mongolia Agricultural University, Hohhot, China

  • Kai Wang,

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

  • Xiangyang Hou

    Houxy16@126.com

    Affiliation Key Laboratory of Grassland Resources and Utilization of Ministry of Agriculture, Institute of Grassland Research, Chinese Academy of Agricultural Sciences, Hohhot, China

Abstract

Stipa grandis P. Smirn. is a dominant plant species in the typical steppe of the Xilingole Plateau of Inner Mongolia. Selection of suitable reference genes for the quantitative real-time reverse transcription polymerase chain reaction (qRT-PCR) is important for gene expression analysis and research into the molecular mechanisms underlying the stress responses of S. grandis. In the present study, 15 candidate reference genes (EF1 beta, ACT, GAPDH, SamDC, CUL4, CAP, SNF2, SKIP1, SKIP5, SKIP11, UBC2, UBC15, UBC17, UCH, and HERC2) were evaluated for their stability as potential reference genes for qRT-PCR under different stresses. Four algorithms were used: GeNorm, NormFinder, BestKeeper, and RefFinder. The results showed that the most stable reference genes were different under different stress conditions: EF1beta and UBC15 during drought and salt stresses; ACT and GAPDH under heat stress; SKIP5 and UBC17 under cold stress; UBC15 and HERC2 under high pH stress; UBC2 and UBC15 under wounding stress; EF1beta and UBC17 under jasmonic acid treatment; UBC15 and CUL4 under abscisic acid treatment; and HERC2 and UBC17 under salicylic acid treatment. EF1beta and HERC2 were the most suitable genes for the global analysis of all samples. Furthermore, six target genes, SgPOD, SgPAL, SgLEA, SgLOX, SgHSP90 and SgPR1, were selected to validate the most and least stable reference genes under different treatments. Our results provide guidelines for reference gene selection for more accurate qRT-PCR quantification and will promote studies of gene expression in S. grandis subjected to environmental stress.

Citation: Wan D, Wan Y, Yang Q, Zou B, Ren W, Ding Y, et al. (2017) Selection of Reference Genes for qRT-PCR Analysis of Gene Expression in Stipa grandis during Environmental Stresses. PLoS ONE 12(1): e0169465. https://doi.org/10.1371/journal.pone.0169465

Editor: Hemachandra Reddy, Texas Technical University Health Sciences Center, UNITED STATES

Received: July 13, 2016; Accepted: December 16, 2016; Published: January 5, 2017

Copyright: © 2017 Wan et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This work was supported by the National Basic Research Program of China (973 program, 2014CB138804), the Natural Science Foundation of Inner Mongolia Autonomous Region of China (2014BS0330), and the Central Non-profit Research Institutes Fundamental Research Funds of China (1610332015004). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Stipa grandis P. Smirn. is a C3 perennial bunchgrass [1] that is distributed widely in eastern Eurasian steppes and the middle Eurasian steppe zone [2]. This species is dominant in the typical steppe of the Xilingole Plateau of Inner Mongolia [1]. The S. grandis steppe acts as a natural green barrier and plays an important role in sandstorm prevention [3]. To date, studies of S. grandis have mostly focused on ecological aspects, such as the relationship between the photosynthetic capacity of S. grandis and the soil moisture gradient [4], the effects of grazing intensity and duration on the biomass of S. grandis [5], and the effects of global warming and elevated CO2 on plant growth [6]. The physiological responses of S. grandis to high temperature and drought have also been reported [2]. Several genetic diversity studies have been carried out on S. grandis related to grazing and location [1, 3, 7]. Transcriptome analysis was carried out to reveal the gene expression profiles of overgrazed and non-grazed S. grandis in a typical grassland; the results showed that many stress-related genes had differential expression under long-term grazing conditions [8]. However, the mechanism underlying S. grandis’s responses to grazing and related stresses remain unclear. To further understand the stress response mechanism of S. grandis, details of the expression patterns of more stress-related genes are necessary.

Quantitative real-time reverse transcription PCR (qRT-PCR) is an efficient tool for expression analysis because of its high-throughput, accuracy, sensitivity, and ease of use compared with traditional methods, such as northern blotting and semi-quantitative reverse transcription-PCR [911]. The inevitable errors or experimental deviations caused by sample preparation and data analysis can affect the reliability of the results; therefore, it is essential to normalize the data using appropriate internal reference genes [12]. The stability of the reference gene’s expression is crucial for the accurate normalization of target gene expression following qRT-PCR quantification [13]. Extensive studies on reference gene stability and selection have been reported in various plants for different tissues and development stages, and under diverse stresses [1422]. Traditionally, reference genes such as 18S rRNA, GAPDH (glyceraldehyde-3-phosphate dehydrogenase), ACT (β or γ actin), TUB (α or β tubulin), EF1α (elongation factor 1α), and UBQ (poly-ubiquitin) have been used most frequently as internal control genes [13, 17]. Recently, taking advantage of a variety of databases comprising data from microarrays, expressed sequence tags, and transcriptomes, other stably expressed genes have been used as novel reference genes for qRT-PCR, such as CUL (Cullin), UBCP (ubiquitin carrier protein) [17], CAP (adenylyl cyclase-associated protein), SKIP1 (ASK-interacting protein 1) [22], F-BOX (F-box/kelch-repeat protein) [23], PP2A (protein phosphatase 2A) [24], SAMDC (s-adenosyl methionine decarboxylase) [12, 25], and SNF (sucrose non fermenting-1 protein kinase) [26]. However, the transcript levels of these reference genes vary among different conditions to some extent [20, 27]. Thus, the selection of ideal reference genes to normalize target gene expression is important to improve the reliability of qRT-PCR results.

In this study, 15 candidate reference genes that could be used potentially as internal control genes to normalize gene expression were selected. The expression stabilities of these reference genes under various abiotic stresses and three hormone treatments were assessed using four algorithms (geNorm, NormFinder, Bestkeeper, and RefFinder). According to our analysis, we were able to recommend the most suitable reference genes to quantify gene expression in S. grandis under various experimental conditions.

Materials and Methods

Plant materials and growth conditions

S. grandis seeds were collected from the Baiyinxile Livestock Farm of Xilinhot, Inner Mongolia (116°40ʹE, 43°33ʹN). The seeds were sown in pots filled with a soil mixture (rich soil: vermiculite, 1:1, v/v), and incubated in a growth chamber at 23°C with a 16-h light/8-h dark cycle.

No specific permits were required for the described field studies.

Hormone and abiotic stress treatments

Four-week-old plants were used in the following experiments, and the different treatment conditions were mainly achieved according to methods described previously [12, 22, 28, 29]. Before treatment with hormones, salinity, high pH, and drought, S. grandis plants were removed from the soil gently, washed clean with tap water, and then immediately subjected to the different treatments. For plant hormone, high pH and salinity treatments, the plants were dipped separately in solutions of 100 μM salicylic acid (SA), 100 μM jasmonic acid (JA), 100 μM abscisic acid (ABA), high pH (pH 10), and 300 mM NaCl. For the drought treatment, the plants were placed on filter paper and incubated in a growth chamber. For the wounding treatment, plants growing in pots were wounded using tweezers and placed in a growth chamber. For cold and heat treatments, plants growing in pots were maintained at 4°C or 42°C, respectively. Untreated plants were used as the control. Shoot samples (from four to five plants) were taken at 1, 3, 6, 12, 24, and 48 h time points for all treatments, and an additional 0.5-h time point for drought and wounding treatments, and were frozen immediately in liquid nitrogen and stored at −80°C until RNA extraction. Three independent biological experiments were performed.

RNA isolation and cDNA synthesis

Total RNA was extracted from the samples using the Trizol regent. The purity and integrity of the RNA samples were estimated by calculating their A260/280 absorbance ratios and by agarose gel electrophoresis analysis. Total RNA (0.5 μg), pretreated with RNase-free DNase I (Takara, Dalian, China), was reverse transcribed into cDNA using an M-MLV reverse transcriptase kit (Takara) and oligo (dT) 18 primers (Takara) following the manufacturer’s instructions. The generated cDNAs were diluted 20-fold for qRT-PCR analysis.

Reference gene selection and primer design

The sequences of the candidate reference genes used in this study were selected based on our previous transcriptome analysis [8], and included EF1 beta, ACT, GAPDH, SamDC, CUL4, CAP, SNF2, SKIP1, SKIP5, SKIP11, UBC2, UBC15, UBC17, UCH, and HERC2. According to these sequences (S1 Text), specific primers for qRT-PCR were designed using the Premier5 software, with a melting temperature (T) of 59–61°C, a length of 18–25 bp, an amplicon product size of 75–160 bp, and a GC content of 40–60%; the primers are listed in Table 1.

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Table 1. Candidate reference genes and characteristics of qRT-PCR primers in S. grandis.

https://doi.org/10.1371/journal.pone.0169465.t001

qRT-PCR analysis

The qRT-PCR was performed on a LightCycler 480 Real Time PCR system (Roche, Basel, Switzerland) with a final volume of 20 μL per reaction, as previously described [30]. Each 20-μL reaction mixture contained 5 μL of diluted cDNA, 10 μL of SYBR Premix Ex Taq II (Takara), 0.8 μL of each primer, and 3.4 μL of sterile distilled water. The thermal cycling program was 95°C for 30 s, followed by 40 cycles of 95°C for 5 s, 60°C for 30 s, and 72°C for 15 s. Melt-curve analyses were performed using a program with constant heating from 70°C to 95°C, followed by 95°C for 15 s. Each reaction was carried out in three technical replicates.

Stability analysis of reference genes

First, three analytical tools, geNorm (version 3.5) [11], NormFinder (version 0.953) [31], and BestKeeper (version 1) [32], were used to calculate the expression stabilities of the 15 reference genes in all samples from the different treatments.

geNorm determines the most stable reference genes from a set of tested genes in a given sample set under a certain experimental condition and calculates the gene expression normalization factor via geometric averaging of all the reference genes [11]. geNorm evaluates gene expression stability by the M value, and ranks the tested genes according to their expression stability by stepwise exclusion of the gene with the highest M value. The lower the M value, the more stable the gene’s expression. The optimal number of reference genes was determined by pairwise variation (V) with a threshold of 0.15 [11]. If the value of Vn/n+1 was below 0.15, additional genes were not required for normalization. NormFinder is an algorithm based on a mathematical model of gene expression and uses a solid statistical framework to estimate the expression variation of candidate normalization genes, as well as the variation in sample subgroups, to identify the optimal normalization gene among a set of candidates [31]. A stability value, which is a direct measure of the estimated expression variation for each gene, is provided by NormFinder; thus, the systematic errors introduced during the process of normalization can be evaluated. In geNorm and NormFinder, the quantities obtained from Ct (cycle threshold) values via the delta-Ct method were used for data input, whereas Bestkeeper used raw Ct values. BestKeeper uses the standard deviation (SD) and coefficient of variance (CV) of the Ct values to calculate the stability of a candidate reference gene; the highest SD and CV values equate to the least stable reference genes [32].

Finally, RefFinder (http://fulxie.0fees.us/?type=reference), which is a comprehensive web-based tool that integrates geNorm, NormFinder, BestKeeper, and the comparative delta Ct method, was applied to determine the most suitable reference genes for the overall final ranking [33].

Validation of reference gene expression

Peroxidase (POD/POX, EC:1.11.1.7), phenylalanine ammonia-lyase (PAL), late embryogenesis abundant protein (LEA), lipoxygenase (LOX), heat shock protein 90 (HSP90), and pathogenesis-related protein 1 (PR1) encoding genes were obtained from the S. grandis transcriptome library [8] and used to confirm the utility of the validated candidate reference genes for qRT-PCR.

The transcript levels of SgPOD and SgPAL under all treatments, SgLEA under drought, cold, salt, high pH and ABA treatments, SgLOX under wounding and JA treatments, SgHSP90 under heat treatment, and SgPR1 under SA treatment were quantified using the most and least stable reference genes, respectively. The primers were as follows:

SgPOD: TCGACTTCGCTGTTCCCACT/CCTTTTGCGGTGAAGTTTCC

SgPR1: GTCGTCTGCAACAACAACGG/GGGACTACTGCGAAGCAATCA

SgPAL: AGCAGCACAACCAGGACGTA/GTCACGCAGTTCTTGACGGA

SgLEA: CTTCCACTTCCATGATTTACGC/CATCCATACAGACCCCAGACAC

SgLOX: CTGGAGGGCATCGAGCAC/GGGTAGAGCAGCATGTAGGG

SgHSP90: CGGATCTTGTGAACAACCTCG/GTAGAAACCAACACCAAACTGACC

The 2−ΔΔCT method [34] was used to calculate the relative expression levels. Each biological sample was analyzed using three technical replicates.

Results

Performance of primers and expression profiles of candidate reference genes

Fifteen fragments of candidate reference genes (Table 1), obtained from previous S. grandis transcriptome data [8], that exhibited stable expression after grazing (within a 2-fold change in expression level) were selected. Agarose gel electrophoresis and melting curve analysis showed that a specific fragment of the expected size and a single peak were observed (S1 Fig), respectively, after reverse transcriptase-PCR amplification using cDNA templates with each primer pair. The PCR amplification efficiencies of each primer pair across all samples ranged from 99.3% to 107.3% (Table 1).

The expression levels of the candidate reference genes were determined by qRT-PCR across all samples (including normal and different stress conditions) (Fig 1), and a wide range of Ct values, from 15.25 to 30.03, were found, with the values for most of the genes lying between 20 and 26. SamDC exhibited the highest expression abundance, with a mean Ct of 16.91, while SKIP5 had the lowest expression level, with a mean Ct of 26.08 across all samples.

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Fig 1. Distribution of Ct values of candidate reference genes in S. grandis plants obtained by qRT-PCR.

Ct values for each reference gene are tested in all samples. Boxes represent the first and third quartiles of the data. Red lines across the boxes indicate the median Ct values. Whiskers show the maximum and minimum values.

https://doi.org/10.1371/journal.pone.0169465.g001

SamDC (3.40 cycles) and UCH (4.33 cycles) showed the smallest expression variations across all the samples. In contrast, SKIP5 (6.34 cycles) and SKIP11 (6.21 cycles) exhibited the largest relative expression variations among all the samples.

geNorm analysis of reference genes

The geNorm results are shown in Fig 2. For the drought treatment, UBC15 and UBC17 were the most stably expressed genes with the lowest M value of 0.0844. For ABA, salt, and JA treatments, the most stably expressed genes were EF1beta and UBC15, with M values of 0.096, 0.106, and 0.117, respectively. For heat treatment, HERC2 and ACT had the lowest M value of 0.137. Under cold treatment, UBC17 and SKIP5 had the lowest M value, and for high pH treatment, UBC17 and CUL4 were the most stable genes. After SA and wounding treatments, the M values of the combinations EF1beta and HERC2, and UBC2 and UBC15 were the lowest, respectively. Under heat and cold treatments, the least stable genes were SKIP5 and SKIP1, respectively. In the other seven treatments, SKIP11 was the most unstable gene. Across all samples, UBC17 and CUL4 ranked as the most stable genes, while SKIP11 was the least stable gene.

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Fig 2. Average expression stability (M) evaluated using geNorm.

M values and rankings are indicated for S. grandis under different stresses. (A) Drought treatment. (B) Heat treatment. (C) Cold treatment. (D) Salt treatment. (E) High pH treatment. (F) Wounding treatment. (G) JA treatment. (H) ABA treatment. (I) SA treatment. (J) Total.

https://doi.org/10.1371/journal.pone.0169465.g002

The optimal number of reference genes for normalization was calculated by pairwise variation (V). Under various conditions, the Vn/n+1 values were lower than 0.15 (Fig 3), which suggested that adding a further reference gene would not improve the normalization quality and a combination of the two most stable reference genes was sufficient for normalization.

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Fig 3. Pairwise variation (V) analysis of the reference genes in S. grandis using geNorm.

The pairwise variation (Vn/n+1) between the normalization factors NFn and NFn+1 was applied to determine the optimal number of reference genes recommended to normalize qRT-PCR data in S. grandis under various stresses. If the Vn/n+1 values were below 0.15, an additional (n + 1) reference was not required.

https://doi.org/10.1371/journal.pone.0169465.g003

NormFinder analysis of reference gene expression stability

Based on the results calculated by NormFinder (Table 2), the three highest ranked genes under ABA treatment were CUL4, UBC15, and UBC17; under cold treatment were SKIP5, HERC2, and UBC17; under heat treatment were ACT, SKIP1, and GAPDH; under JA treatment were UBC17, EF1beta, and UBC15; under salt treatment were UBC15, EF1beta, and HERC2; under high pH treatment were UBC15, EF1beta, and SKIP5; under SA treatment were HERC2, UBC17, and EF1beta; under wounding treatment were UBC2, UBC15, and UBC17; and under drought treatment were EF1beta, UBC15, and GAPDH. According to all the samples in the study, UBC15, HERC2, and EF1beta were the most stable genes. In addition, the least stable genes ranked by NormFinder and geNorm were consistent: for cold and heat stresses they were SKIP1 and SKIP5, and for the other treatments it was SKIP11.

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Table 2. Stabilities of candidate reference genes ranked by NormFinder.

https://doi.org/10.1371/journal.pone.0169465.t002

Bestkeeper analysis of reference gene expression stability

As shown in Table 3, Bestkeeper ranked UBC17 as the most stably expressed gene following cold, wounding, and ABA treatments, while UCH had the lowest SD value under drought and salt stresses. GAPDH, SamDC, UBC2, and SKIP1 were ranked as the most stably expressed genes under heat, high pH, JA, and SA treatments, respectively. When all the samples were analyzed together, UCH was rated as the most stable gene with the lowest SD value.

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Table 3. Stabilities of candidate reference genes ranked by Bestkeeper.

https://doi.org/10.1371/journal.pone.0169465.t003

RefFinder ranking of the most stable genes

RefFinder, which combines the geNorm, NormFinder, and BestKeeper outputs, was applied to generate a comprehensive final ranking of the candidate references. As shown in Table 4, EF1beta (drought and JA), ACT (heat), SKIP5 (cold), UBC15 (salt, high pH, and ABA), UBC2 (wounding), and HERC2 (SA) were ranked as the top stable genes under the different treatments. Across all samples, EF1beta, HERC2, and UCH were suggested as the three best reference genes for normalizing the expression of target genes.

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Table 4. Stabilities of candidate reference genes ranked by RefFinder.

https://doi.org/10.1371/journal.pone.0169465.t004

Validation of candidate reference genes

To validate the utility of the candidate reference genes selected using RefFinder, the expression patterns of six target genes identified from RNA-Seq data, including SgPOD, SgPAL, SgLEA, SgLOX, SgHSP90, and SgPR1, in response to different treatments were examined. When normalization was performed using the two most stable genes under each treatment, EF1beta and UBC15 (drought), SKIP5 and UBC17 (cold), UBC15 and EF1beta (salt), ACT and GAPDH (heat), UBC15 and HERC2 (high pH), UBC2 and UBC15 (wounding), EF1beta and UBC17 (JA), UBC15 and CUL4 (ABA), and HERC2 and UBC17 (SA), the expression of SgPOD was affected by different treatments (Fig 4), and peak points were observed at 3 h under drought, at 6 h under cold, at 3 h under salt, at 1 h under high pH, at 48 h under JA, and at 3 h under SA, whereas minimums were found at 24 h under heat and at 48 h under ABA and wounding treatments. It is worth noting that the transcripts of SgLEA were intensively induced by drought, cold, salt, high pH, and ABA treatments (Fig 5A–5E). Wounding and JA treatments caused transcript accumulation of SgLOX (Fig 5G and 5H), and heat stress increased the expression level of SgHSP90 (Fig 5F). An increased transcript level of SgPR1 was observed at 3 h after SA treatment compared with the control, and a peak point was observed at 12 h following a decrease in expression at 6 h (Fig 5I). Additionally, upregulated expression of SgPAL was observed after JA, high pH, and SA treatments, whereas SgPAL expression was downregulated by the other treatments (S2 Fig). Similar expression patterns were obtained using the most stable single genes and combinations of two genes for normalization under the above treatments, while different expression patterns were observed when using the least stable reference genes compared with the most stable genes for target gene normalization.

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Fig 4. Validation of the most and least stable reference genes for the normalization of SgPOD expression.

The most and least stable reference genes were selected for normalization following different stress treatments for 0, 1, 3, 6, 12, 24, and 48 h, with an additional 0.5-h time point for the drought and wounding treatments. (A) Drought. (B) Cold. (C) Salt. (D) High pH. (E) ABA. (F) Heat. (G) Wounding. (H) JA. (I) SA. The error bars represent the mean of three technical replicates ± SD.

https://doi.org/10.1371/journal.pone.0169465.g004

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Fig 5. Validation of the most and least stable reference genes for the normalization of SgLEA, SgLOX, SgHSP90, and SgPR1 expression.

The most and least stable reference genes were selected for normalization following different stress treatments for 0, 1, 3, 6, 12, 24, and 48 h, with an additional 0.5-h time point for the drought and wounding treatments. (A–E) SgLEA expression under drought, cold, salt, high pH, and ABA treatments. (F) SgHSP90 expression under heat treatment. (G and H) SgLOX expression under wounding and JA treatments. (I) SgPR1 expression under SA treatment. The error bars represent the mean of three technical replicates ± SD.

https://doi.org/10.1371/journal.pone.0169465.g005

Discussion

qRT-PCR combines reverse transcription (RT) with the quantitative real-time polymerase chain reaction (qPCR) [35]. The accuracy of qRT-PCR is influenced strongly by the stability of the reference gene chosen for normalization of gene expression data [22]; therefore, it is crucial to select stably expressed genes as internal references [13].

Base on previous transcriptome data [8], we selected 15 genes that exhibited relatively low levels of transcript variation after grazing stress and evaluated their expression stability under different stresses in S. grandis. Four statistical algorithms, geNorm, NormFinder, BestKeeper, and RefFinder, were used to evaluate the stability of these genes. All the genes displayed different expression patterns following the various treatments. Moreover, high stability levels were observed using geNorm analysis; all the M values were below the accepted threshold of 1.5 (Fig 2), which indicated that all the genes could be used as internal control genes for normalization. However, according to different algorithms and analytical procedures, several differences were observed in the ranking of the most stable genes, which was similar to the results for other species [1921]. For wounding treatment in S. grandis, UBC2 and UBC15 were selected by both geNorm and NormFinder as the two most stable reference genes (Fig 2 and Table 2), but UBC17 and CUL4 were ranked top by Bestkeeper (Table 3); UBC2, UBC15, and UBC17 were determined as the most stable by RefFinder’s comprehensive analysis (Table 4). Across all treatments under study, UBC17, CUL4, and HERC2 for geNorm (Fig 2), UBC15, HERC2, and EF1beta for NormFinder (Table 2), and UCH, SamDC, and SNF2 for Bestkeeper were considered the most suitable reference genes (Table 3). Overall, RefFinder recommended using EF1beta, HERC2, and UCH (Table 4).

Traditional reference genes, such as ACT, GAPDH, and EF1α, which are involved in primary metabolism or other cellular processes [19], as well as new candidate reference genes derived from public databases [12, 17, 22, 25, 26], have been validated to allow precise interpretation of the qRT-PCR results for specific experimental conditions. However, fluctuating expression of reference genes has been observed under certain experimental conditions. For example, EF1α was identified as the best reference gene under salinity and drought stresses in Glycine max [36]. Nevertheless, EF1α exhibited poor performance in leaves and roots during abiotic stress treatments [15]. In the present study, we also found that the most suitable reference genes varied under different environmental stimuli. The comprehensive combined analysis by RefFinder showed that the top three ranked genes included the traditional genes EF1beta, ACT, UBC15, UBC2, GAPDH, and UBC17, as well as the novel genes UCH, SKIP5, HERC2, and CUL4 (Table 4).

Previously, EF1beta was identified as a stable reference gene in the developing seeds of the Tung Tree [37]. EF1beta has also been determined to be a good reference in soybean under various stresses [36]. Similarly, we found that EF1beta was in the three top ranked reference genes for drought, salt, high pH, JA, and SA treatments, as well as across all samples (Table 4). ACT, a traditional reference gene, is used commonly as an internal control to normalize target gene expression results from qRT-PCR in various species under different conditions. For instance, ACT was determined to be stably expressed during different floral developmental stages and different temperature treatments in Sweet Osmanthus (Osmanthus fragrans Lour.) [14]. In our study, ACT was identified as the best reference gene by the geNorm and RefFinder programs under heat stress (Fig 2 and Table 4).

Ubiquitination is related to post-translational modification of proteins, and three enzymes are involved in this cellular process: E1 (ubiquitin-activating enzymes), E2 (ubiquitin-conjugating enzymes), and E3 (ubiquitin ligases) [38]. Accumulated data indicate that ubiquitin-conjugating enzymes (UBC) exhibit stable expression in many experimental conditions; thus, they have been used widely as reference genes in different species [12, 14, 39]. Three UBC genes (UBC15, UBC2, and UBC17) were analyzed in this study. Notably, these UBC genes performed well under different treatments (excluding heat stress), especially when analyzed by geNorm and RefFinder (Fig 2 and Table 4). UBC15 and UBC17 exhibited better expression stability than UBC2. HERC2, a HECT domain E3 (ubiquitin ligases) encoding gene [40], also showed stable transcript levels under most experimental conditions. Additionally, the de-ubiquitinating protease UCH (ubiquitin carboxyl-terminal hydrolase) was the top ranked gene using Bestkeeper analysis under drought and salt treatments, as well as in the overall assessment (Table 3). Taken together, at least one of the ubiquitin-related genes was ranked in the top three stable genes (Fig 2, Tables 3 and 4). These results indicated the UBC genes could be used more often as an internal control for normalizing gene expression under various stress treatments. SKIP, a spliceosome component and transcriptional activator, is conserved in eukaryotes and has diverse functions in plant development associated with responses to environmental changes [41]. Among the three SKIP encoding genes examined in this study, SKIP5 was ranked as the most stable gene under cold stress using geNorm (Fig 2), NormFinder (Table 2), and RefFinder (Table 4), and SKIP1 was recommended as the best gene under JA treatment by Bestkeeper analysis (Table 3). Conversely, SKIP11 was ranked the least stable reference gene by the different programs (Fig 2 and Tables 24), except for heat and cold stresses by geNorm and NormFinder, heat, cold, ABA, and JA treatments by Bestkeeper, and heat, cold, and JA treatments by RefFinder. These results indicate that SKIP11 is the least suitable gene for use as an internal control in S. grandis under various environmental stimuli.

The effectiveness of the most stable reference genes selected using RefFinder was evaluated by normalization of six target genes in samples under different stress conditions. Peroxidases [POD/POX, EC:1.11.1.7] are heme-containing glycoproteins that oxidize a wide range of hydrogen donors, accompanied by the accumulation of H2O2 [42]. Many peroxidase isoenzymes are found in higher plants and they play roles in plant defense, growth, and development [42]. Guaiacol peroxidase (GPX, EC 1.11.1.7) [43], which is generally considered a stress-related enzyme, is involved in plant defense against various stresses, and the activity of GPX is thought to be induced by diverse environmental stimuli [44], such as drought, salinity, and chilling [43, 45, 46]. In the present work, the expression of a peroxidase encoding gene was detected under the different treatments (Fig 4), and the changes in its transcript levels suggested that peroxidase plays an important role in S. grandis defense against stressful conditions. The late embryogenesis abundant protein encoding gene LEA has been widely reported to participate in responses to drought, cold, and salt stresses, and ABA treatment, and plays an important role in plant tolerance to abiotic stress [4751]. The significantly increased expression of SgLEA under drought, cold, salt, high pH and ABA treatments (Fig 5A–5E) implies that SgLEA participates in S. grandis resistance responses against stresses. The expression level of SgLOX was elevated by wounding and JA treatments (Fig 5G and 5H), and SgHSP90 expression was enhanced by heat treatment (Fig 5F); the induction of these genes was in accordance with previously reported expression patterns of LOX2 [5254] and HSP90 [5557]. Additionally, a pathogenesis-related protein 1 encoding gene, SgPR1, which is widely accepted as an SA marker gene [58] and is induced by SA accumulation [59], was selected to assess the utility of the identified reference genes under SA treatment. As a critical defense signaling molecule, SA accumulation is associated with enhanced resistance to pathogen infection [60]. The changes in the transcript level of SgPR1 after SA treatment indicated that SgPR1 could be used as a molecular marker for disease resistance responses in S. grandis (Fig 5I). However, when the target gene normalization was performed with the least stable genes, the expression patterns varied in comparison with most stable reference genes. Taken together, these results suggest that appropriate selection of reference genes is necessary for the normalization of target gene expression to ensure the accuracy of qRT-PCR data.

Conclusions

This study comprehensively evaluated the utility of 15 potential reference genes for quantifying transcript levels in S. grandis exposed to diverse experimental conditions. The stable reference genes identified in this work will help to improve the accuracy of gene expression analysis and will aid the investigation of stress-response genes and the molecular mechanism of stress tolerance in this species.

Supporting Information

S1 Fig. Primer specificity and amplicon size for the candidate reference genes.

https://doi.org/10.1371/journal.pone.0169465.s001

(TIF)

S2 Fig. Validation of the most and least stable reference genes for the normalization of SgPAL expression under different treatments.

https://doi.org/10.1371/journal.pone.0169465.s002

(TIF)

S1 Text. Sequences of candidate reference genes.

https://doi.org/10.1371/journal.pone.0169465.s003

(TXT)

Acknowledgments

We thank Dr. Guojing Li (Inner Mongolia Agricultural University) for her valuable suggestions on the design of the experiment and the Plant Molecular Biology Laboratory of Inner Mongolia Agricultural University for help with the qRT-PCR analysis.

Author Contributions

  1. Conceptualization: DLW YQW XYH.
  2. Formal analysis: DLW YQW QY.
  3. Funding acquisition: XYH DLW.
  4. Investigation: YQW DLW BZ KW.
  5. Project administration: XYH DLW.
  6. Resources: DLW RGW WBR YD.
  7. Validation: DLW YQW.
  8. Visualization: DLW YQW ZW.
  9. Writing – original draft: DLW.
  10. Writing – review & editing: DLW XYH YQW.

References

  1. 1. Wu JB, Gao YB, Bao XY, Gao H, Jia MQ, Li J, et al. Genetic variation among Stipa grandis P. Smirn populations with different durations of fencing in the Inner Mongolian Steppe. Rangeland J. 2010;32(4): 427–434.
  2. 2. Song XL, Wang YH and Lv XM. Responses of plant biomass, photosynthesis and lipid peroxidation to warming and precipitation change in two dominant species (Stipa grandis and Leymus chinensis) from North China Grasslands. Ecology and Evolution. 2016;6(6): 1871–1882. pmid:26933491
  3. 3. Zhao NX, Gao YB, Wang JL and Ren AZ. Population structure and genetic diversity of Stipa grandis P. Smirn, a dominant species in the typical steppe of northern China. Biochemical Systematics and Ecology. 2008;36(1): 1–10.
  4. 4. Xu Z and Zhou G. Responses of photosynthetic capacity to soil moisture gradient in perennial rhizome grass and perennial bunchgrass. BMC Plant Biol. 2011;11: 21. pmid:21266062
  5. 5. Ren H, Schonbach P, Wan H, Gierus M and Taube F. Effects of grazing intensity and environmental factors on species composition and diversity in typical steppe of Inner Mongolia, China. PLoS One. 2012;7(12): e52180. pmid:23284925
  6. 6. Xu Z, Shimizu H, Ito S, Yagasaki Y, Zou C, Zhou G, et al. Effects of elevated CO(2), warming and precipitation change on plant growth, photosynthesis and peroxidation in dominant species from North China grassland. Planta. 2014;239(2): 421–435. pmid:24463932
  7. 7. Wu JB, Gao YB, Bao XY, Gao H, Jia MQ, Li J, et al. Genetic diversity of Stipa grandis P Smirn populations across the species' range in the Inner Mongolia Plateau of China. Biochemical Systematics and Ecology. 2010;38(4): 471–477.
  8. 8. Wan D, Wan Y, Hou X, Ren W, Ding Y and Sa R. De novo assembly and transcriptomic profiling of the grazing response in Stipa grandis. PLoS One. 2015;10(4): e0122641. pmid:25875617
  9. 9. Udvardi MK, Czechowski T and Scheible WR. Eleven golden rules of quantitative RT-PCR. Plant Cell. 2008;20(7): 1736–1737. pmid:18664613
  10. 10. VanGuilder HD, Vrana KE and Freeman WM. Twenty-five years of quantitative PCR for gene expression analysis. Biotechniques. 2008;44(5): 619–626. pmid:18474036
  11. 11. Vandesompele J, De Preter K, Pattyn F, Poppe B, Van Roy N, De Paepe A, et al. Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome Biol. 2002;3(7): RESEARCH0034.
  12. 12. Hong SY, Seo PJ, Yang MS, Xiang F and Park CM. Exploring valid reference genes for gene expression studies in Brachypodium distachyon by real-time PCR. BMC Plant Biol. 2008;8: 112. pmid:18992143
  13. 13. Czechowski T, Stitt M, Altmann T, Udvardi MK and Scheible WR. Genome-wide identification and testing of superior reference genes for transcript normalization in Arabidopsis. Plant Physiol. 2005;139(1): 5–17. pmid:16166256
  14. 14. Zhang C, Fu J, Wang Y, Bao Z and Zhao H. Identification of Suitable Reference Genes for Gene Expression Normalization in the Quantitative Real-Time PCR Analysis of Sweet Osmanthus (Osmanthus fragrans Lour.). PLoS One. 2015;10(8): e0136355. pmid:26302211
  15. 15. Yang Z, Chen Y, Hu B, Tan Z and Huang B. Identification and validation of reference genes for quantification of target gene expression with quantitative real-time PCR for tall fescue under four abiotic stresses. PLoS One. 2015;10(3): e0119569. pmid:25786207
  16. 16. Muller OA, Grau J, Thieme S, Prochaska H, Adlung N, Sorgatz A, et al. Genome-Wide Identification and Validation of Reference Genes in Infected Tomato Leaves for Quantitative RT-PCR Analyses. PLoS One. 2015;10(8): e0136499. pmid:26313760
  17. 17. Ling H, Wu QB, Guo JL, Xu LP and Que YX. Comprehensive Selection of Reference Genes for Gene Expression Normalization in Sugarcane by Real Time Quantitative RT-PCR. PLoS One. 2014;9(5).
  18. 18. Kong Q, Yuan J, Niu P, Xie J, Jiang W, Huang Y, et al. Screening suitable reference genes for normalization in reverse transcription quantitative real-time PCR analysis in melon. PLoS One. 2014;9(1): e87197. pmid:24475250
  19. 19. Chen Y, Hu B, Tan Z, Liu J, Yang Z, Li Z, et al. Selection of reference genes for quantitative real-time PCR normalization in creeping bentgrass involved in four abiotic stresses. Plant Cell Rep. 2015;34(10): 1825–1834. pmid:26179072
  20. 20. Lacerda AL, Fonseca LN, Blawid R, Boiteux LS, Ribeiro SG and Brasileiro AC. Reference Gene Selection for qPCR Analysis in Tomato-Bipartite Begomovirus Interaction and Validation in Additional Tomato-Virus Pathosystems. PLoS One. 2015;10(8): e0136820. pmid:26317870
  21. 21. Bansal R, Mittapelly P, Cassone BJ, Mamidala P, Redinbaugh MG and Michel A. Recommended Reference Genes for Quantitative PCR Analysis in Soybean Have Variable Stabilities during Diverse Biotic Stresses. PLoS One. 2015;10(8): e0134890. pmid:26244340
  22. 22. Yang Q, Yin J, Li G, Qi L, Yang F and Wang R. Reference gene selection for qRT-PCR in Caragana korshinskii Kom. under different stress conditions. Mol Biol Rep. 2014;41(4): 2325–2334. pmid:24452712
  23. 23. Lin LY, Han XJ, Chen YC, Wu QK and Wang YD. Identification of appropriate reference genes for normalizing transcript expression by quantitative real-time PCR in Litsea cubeba. Mol Genet Genomics. 2013;288(12): 727–737. pmid:24162560
  24. 24. Lovdal T and Lillo C. Reference gene selection for quantitative real-time PCR normalization in tomato subjected to nitrogen, cold, and light stress. Anal Biochem. 2009;387(2): 238–242. pmid:19454243
  25. 25. Gimeno J, Eattock N, Van Deynze A and Blumwald E. Selection and Validation of Reference Genes for Gene Expression Analysis in Switchgrass (Panicum virgatum) Using Quantitative Real-Time RT-PCR. PLoS One. 2014;9(3).
  26. 26. Chandna R, Augustine R and Bisht NC. Evaluation of Candidate Reference Genes for Gene Expression Normalization in Brassica juncea Using Real Time Quantitative RT-PCR. PLoS One. 2012;7(5).
  27. 27. Gutierrez L, Mauriat M, Pelloux J, Bellini C and van Wuytswinkel O. Towards a systematic validation of references in real-time RT-PCR. Plant Cell. 2008;20(7): 1734–1735. pmid:18664615
  28. 28. Zhang Y and Turner JG. Wound-induced endogenous jasmonates stunt plant growth by inhibiting mitosis. PLoS One. 2008;3(11): e3699. pmid:19002244
  29. 29. Han X, Feng Z, Xing D, Yang Q, Wang R, Qi L, et al. Two NAC transcription factors from Caragana intermedia altered salt tolerance of the transgenic Arabidopsis. BMC Plant Biol. 2015;15: 208. pmid:26297025
  30. 30. Wan DL, Li RL, Zou B, Zhang X, Cong JY, Wang RG, et al. Calmodulin-binding protein CBP60g is a positive regulator of both disease resistance and drought tolerance in Arabidopsis. Plant Cell Rep. 2012;31(7): 1269–1281. pmid:22466450
  31. 31. Andersen CL, Jensen JL and Orntoft TF. Normalization of real-time quantitative reverse transcription-PCR data: a model-based variance estimation approach to identify genes suited for normalization, applied to bladder and colon cancer data sets. Cancer Res. 2004;64(15): 5245–5250. pmid:15289330
  32. 32. Pfaffl MW, Tichopad A, Prgomet C and Neuvians TP. Determination of stable housekeeping genes, differentially regulated target genes and sample integrity: BestKeeper—Excel-based tool using pair-wise correlations. Biotechnol Lett. 2004;26(6): 509–515. pmid:15127793
  33. 33. Xie F, Xiao P, Chen D, Xu L and Zhang B. miRDeepFinder: a miRNA analysis tool for deep sequencing of plant small RNAs. Plant Mol Biol. 2012.
  34. 34. Livak KJ and Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2−ΔΔCT method. Methods. 2001;25(4): 402–408. pmid:11846609
  35. 35. Bennett J, Hondred D and Register JC III. Keeping qRT-PCR rigorous and biologically relevant. Plant Cell Rep. 2015;34(1): 1–3. pmid:25304620
  36. 36. Ma S, Niu H, Liu C, Zhang J, Hou C and Wang D. Expression stabilities of candidate reference genes for RT-qPCR under different stress conditions in soybean. PLoS One. 2013;8(10): e75271. pmid:24124481
  37. 37. Han XJ, Lu MZ, Chen YC, Zhan ZY, Cui QQ and Wang YD. Selection of Reliable Reference Genes for Gene Expression Studies Using Real-Time PCR in Tung Tree during Seed Development. PLoS One. 2012;7(8).
  38. 38. Morreale FE and Walden H. Types of Ubiquitin Ligases. Cell. 2016;165(1): 248–248 e241. pmid:27015313
  39. 39. Chang E, Shi S, Liu J, Cheng T, Xue L, Yang X, et al. Selection of reference genes for quantitative gene expression studies in Platycladus orientalis (Cupressaceae) Using real-time PCR. PLoS One. 2012;7(3): e33278. pmid:22479379
  40. 40. Mohiuddin , Kobayashi S, Keka IS, Guilbaud G, Sale J, Narita T, et al. The role of HERC2 and RNF8 ubiquitin E3 ligases in the promotion of translesion DNA synthesis in the chicken DT40 cell line. DNA Repair (Amst). 2016;40: 67–76.
  41. 41. Li Y, Xia C, Feng J, Yang D, Wu F, Cao Y, et al. The SNW Domain of SKIP is Required for its Integration into the Spliceosome and its Interaction with the Paf1 Complex in Arabidopsis. Mol Plant. 2016.
  42. 42. Yoshida K, Kaothien P, Matsui T, Kawaoka A and Shinmyo A. Molecular biology and application of plant peroxidase genes. Appl Microbiol Biotechnol. 2003;60(6): 665–670. pmid:12664144
  43. 43. Prasad TK, Anderson MD, Martin BA and Stewart CR. Evidence for Chilling-Induced Oxidative Stress in Maize Seedlings and a Regulatory Role for Hydrogen Peroxide. Plant Cell. 1994;6(1): 65–74. pmid:12244221
  44. 44. Sharma P, Jha AB, Dubey RS and Pessarakli M. Reactive oxygen species, oxidative damage, and antioxidative defense mechanism in plants under stressful conditions. Journal of Botany. 2012;2012.
  45. 45. Sharma P and Dubey RS. Drought induces oxidative stress and enhances the activities of antioxidant enzymes in growing rice seedlings. Plant Growth Regul. 2005;46(3): 209–221.
  46. 46. Mishra P, Bhoomika K and Dubey RS. Differential responses of antioxidative defense system to prolonged salinity stress in salt-tolerant and salt-sensitive Indica rice (Oryza sativa L.) seedlings. Protoplasma. 2013;250(1): 3–19. pmid:22194018
  47. 47. Sharma A, Kumar D, Kumar S, Rampuria S, Reddy AR and Kirti PB. Ectopic Expression of an Atypical Hydrophobic Group 5 LEA Protein from Wild Peanut, Arachis diogoi Confers Abiotic Stress Tolerance in Tobacco. PLoS One. 2016;11(3): e0150609. pmid:26938884
  48. 48. Liu Y, Liang J, Sun L, Yang X and Li D. Group 3 LEA Protein, ZmLEA3, Is Involved in Protection from Low Temperature Stress. Front Plant Sci. 2016;7: 1011. pmid:27471509
  49. 49. Liu Y, Wang L, Xing X, Sun L, Pan J, Kong X, et al. ZmLEA3, a multifunctional group 3 LEA protein from maize (Zea mays L.), is involved in biotic and abiotic stresses. Plant Cell Physiol. 2013;54(6): 944–959. pmid:23543751
  50. 50. Babu RC, Zhang JX, Blum A, Ho THD, Wu R and Nguyen HT. HVA1, a LEA gene from barley confers dehydration tolerance in transgenic rice (Oryza sativa L.) via cell membrane protection. Plant Science. 2004;166(4): 855–862.
  51. 51. Xu DP, Duan XL, Wang BY, Hong BM, Ho THD and Wu R. Expression of a late embryogenesis abundant protein gene, HVA1, from barley confers tolerance to water deficit and salt stress in transgenic rice. Plant Physiol. 1996;110(1): 249–257. pmid:12226181
  52. 52. Wang CX, Zien CA, Afitlhile M, Welti R, Hildebrand DF and Wang XM. Involvement of phospholipase D in wound-induced accumulation of jasmonic acid in Arabidopsis. Plant Cell. 2000;12(11): 2237–2246. pmid:11090221
  53. 53. Reymond P, Weber H, Damond M and Farmer EE. Differential gene expression in response to mechanical wounding and insect feeding in Arabidopsis. Plant Cell. 2000;12(5): 707–720. pmid:10810145
  54. 54. Leon-Reyes A, Van der Does D, De Lange ES, Delker C, Wasternack C, Van Wees SC, et al. Salicylate-mediated suppression of jasmonate-responsive gene expression in Arabidopsis is targeted downstream of the jasmonate biosynthesis pathway. Planta. 2010;232(6): 1423–1432. pmid:20839007
  55. 55. Milioni D and Hatzopoulos P. Genomic organization of hsp90 gene family in Arabidopsis. Plant Mol Biol. 1997;35(6): 955–961. pmid:9426614
  56. 56. Xu J, Xue C, Xue D, Zhao J, Gai J, Guo N, et al. Overexpression of GmHsp90s, a heat shock protein 90 (Hsp90) gene family cloning from soybean, decrease damage of abiotic stresses in Arabidopsis thaliana. PLoS One. 2013;8(7): e69810. pmid:23936107
  57. 57. Yabe N, Takahashi T and Komeda Y. Analysis of tissue-specific expression of Arabidopsis thaliana HSP90-family gene HSP81. Plant Cell Physiol. 1994;35(8): 1207–1219. pmid:7697294
  58. 58. Fan J, Hill L, Crooks C, Doerner P and Lamb C. Abscisic Acid Has a Key Role in Modulating Diverse Plant-Pathogen Interactions. Plant Physiology. 2009;150(4): 1750–1761. pmid:19571312
  59. 59. Loake G and Grant M. Salicylic acid in plant defence-the players and protagonists. Curr Opin Plant Biol. 2007;10(5): 466–472. pmid:17904410
  60. 60. Vlot AC, Dempsey DA and Klessig DF. Salicylic Acid, a Multifaceted Hormone to Combat Disease. Annu Rev Phytopathol. 2009;47: 177–206. pmid:19400653