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Evaluation of suitable reference genes for expression profile analyses of target genes in the coffee berry borer, Hypothenemus hampei (Ferrari) (Coleoptera: Curculionidae)

Published online by Cambridge University Press:  05 January 2024

Shaohua Zhang ,
Enhang Zhu ,
Zheng Wang ,
Yaofeng Zhong ,
Xuezong Zha ,
Hengqing Ji  and
Qianqian Meng Open the ORCID record for Qianqian Meng [Opens in a new window]
Shaohua Zhang
Affiliation:
Hainan Provincial Key Laboratory of Genetic Improvement and Quality Regulation for Tropical Spice and Beverage Crops, Spice and Beverage Research Institute, Chinese Academy of Tropical Agricultural Sciences, Wanning 571533, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
Enhang Zhu
Affiliation:
Hainan Provincial Key Laboratory of Genetic Improvement and Quality Regulation for Tropical Spice and Beverage Crops, Spice and Beverage Research Institute, Chinese Academy of Tropical Agricultural Sciences, Wanning 571533, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
Zheng Wang*
Affiliation:
Chongqing Municipal Key Laboratory for High Pathogenic Microbes, The First Batch of Key Disciplines On Public Health in Chongqing, Department of Disinfection and Vector Control, Chongqing Center for Disease Control and Prevention, Chongqing 40042, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
Yaofeng Zhong
Affiliation:
Hainan Provincial Key Laboratory of Genetic Improvement and Quality Regulation for Tropical Spice and Beverage Crops, Spice and Beverage Research Institute, Chinese Academy of Tropical Agricultural Sciences, Wanning 571533, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
Xuezong Zha
Affiliation:
Hainan Provincial Key Laboratory of Genetic Improvement and Quality Regulation for Tropical Spice and Beverage Crops, Spice and Beverage Research Institute, Chinese Academy of Tropical Agricultural Sciences, Wanning 571533, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
Hengqing Ji
Affiliation:
Chongqing Municipal Key Laboratory for High Pathogenic Microbes, The First Batch of Key Disciplines On Public Health in Chongqing, Department of Disinfection and Vector Control, Chongqing Center for Disease Control and Prevention, Chongqing 40042, P.R. China
Qianqian Meng*
Affiliation:
Institute of Agricultural Resources and Environment, Chongqing Academy of Agricultural Sciences, Chongqing 40042, P.R. China School of Plant Protection, Hainan University, Haikou 570228, P.R. China
*
Corresponding authors: Qianqian Meng; Email: mengzouzou@163.com; Zheng Wang; Email: sallywz618@163.com
Corresponding authors: Qianqian Meng; Email: mengzouzou@163.com; Zheng Wang; Email: sallywz618@163.com
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Abstract

The coffee berry borer, Hypothenemus hampei (Ferrari) (Coleoptera: Curculionidae), is a major destructive insect pest of coffee, which impacts the coffee crops negatively. As a draft genome has been completed for this insect, most molecular studies on gene transcriptional levels under different experimental conditions will be conducted using real-time reverse-transcription quantitative polymerase chain reactions (RT-qPCR). However, the lack of suitable internal reference genes will affect the accuracy of RT-qPCR results. In this study, the expression stability of nine candidate reference genes was evaluated under different developmental stages, temperature stress, and Beauveria bassiana infection. Data analyses were completed by four commonly used programs, BestKeeper, NormFinder, geNorm, and RefFinder. The result showed that RPL3 and EF1α combination were recommended as the most stable reference genes for developmental stages. EF1α and RPS3a combination were the top two stable reference genes for B. bassiana infection. RPS3a and RPL3 combination performed as the optimal reference genes both in temperature stress and all samples. Our results should provide a good foundation for the expression profile analyses of target genes in the future, especially for molecular studies on insect genetic development, temperature adaptability, and immune mechanism to entomogenous fungi in H. hampei.

Keywords

Beauveria bassiana infectiondevelopmental stagesexpression stabilityHypothenemus hampei (Ferrari)reference genestemperature stress
Type
Research Paper
Information
Bulletin of Entomological Research , Volume 114 , Issue 1 , February 2024 , pp. 57 - 66
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Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

The coffee berry borer (CBB), Hypothenemus hampei (Ferrari) (Coleoptera: Curculionidae), has been listed as a quarantine pest in many countries and considered as one of the most destructive insect pests in coffee. It is estimated that once CBB outbreak occurs, the coffee industry will suffer losses of up to 80% (Le Pelley, Reference Le Pelley1973; Vega et al., Reference Vega, Infante, Castillo and Jaramillo2009; Infante, Reference Infante2018). It is worth noting that CBB was firstly recorded invading the Chinese island of Hainan in 2019 (Sun et al., Reference Sun, Wang, Liu, Lai, Wang, Meng, Gou, Johnson and Li2020), which is a major producer of the species robusta coffee. The insect has a special breeding mode that most of its lifecycle occurs inside the coffee berries, making the control strategies difficult to implement (Baker, Reference Baker1999, Damon, Reference Damon2000; Aristizábal et al., Reference Aristizábal, Olga and Arthurs2012). Female adults bore into the endosperm of the berries and deposit their eggs. Special galleries are formed with the larvae develop within the beans, leading to reduced coffee yield and quality. All nutrients for young beetles come from the coffee berries, until the mated female beetles emerge from mature coffee berries to find new habitats for oviposition (Damon, Reference Damon2000; Duque and Baker, Reference Duque-O and Baker2003).

For invasive insects, temperature plays an important role throughout their whole lifecycle. The adaptability to different temperatures allows insects to successfully invade and spread (Wallner, Reference Wallner1987; Renault et al., Reference Renault, Laparie, McCauley and Bonte2018; Umeda and Paine, Reference Umeda and Paine2019). Temperature variation significantly affected the fecundity and development time of CBB. Females of CBB successfully oviposited in the temperature range 15–30℃, with the highest fecundity observed at 23℃ (Azrag and Babin, Reference Azrag and Babin2023). The maximum and minimum temperature threshold have also been estimated for egg, larva, pupa, and the total development from egg to adult, respectively (Azrag et al., Reference Azrag, Yusuf, Pirk, Niassy, Mbugua and Babin2020). Studies on the adaptability of CBB to temperature will help understand and predict the pest population dynamics and distribution in coffee plantations and as such, will contribute to a more efficient management of the pest. In terms of prevention and control strategies for CBB, three African parasitoids have been introduced to many CBB invaded countries, including Prorops nasuta Waterston (Bethylidae), Cephalonomia stephanoderis Betrem (Bethylidae), and Phymastichus coffea LaSalle (Eulophidae) (Barrera et al., Reference Barrera, Moore, Abraham, Murphy and Prior1990; Infante et al., Reference Infante, Valdéz, Penagos and Barrera1994, Reference Infante, Pérez and Vega2012; Chiu-Alvarado and Rojas, Reference Chiu-Alvarado and Rojas2008; Espinoza et al., Reference Espinoza, Infante, Castillo, Pérez, Nieto, Pinson and Vega2009). Besides, an entomopathogen, Beauveria bassiana (Balsamo) Vuillemin (Ascomicota: Hypocreales), has been widely used to control CBB throughout the world. It has been verified to be highly infective to the adult beetles in coffee plantations wherever the borer is present (Infante, Reference Infante2018). In recent years, more and more studies on the use of volatile compounds extracted from either coffee trees themselves or companion plants have been reported. Among these volatiles, some are attractive compounds that can be used as lure traps to capture and monitor CBB populations in the field (Pereira et al., Reference Pereira, Vilela, Tinoco, de Lim and Frana2012; Cruz Roblero and Malo, Reference Cruz Roblero and Malo2013; Jaramillo et al., Reference Jaramillo, Torto, Mwenda, Troeger, Borgemeiste, Poehlingr and Francke2013; Cruz-López et al., Reference Cruz-López, Díaz-Díaz and Rojas2016; Sinaga et al., Reference Sinaga and Tobing2020). Moreover, some monoterpene and sesquiterpene compounds elicited from secondary metabolites are identified as repellent to CBB (Jaramillo et al., Reference Jaramillo, Torto, Mwenda, Troeger, Borgemeiste, Poehlingr and Francke2013; Vega et al., Reference Vega, Simpkins, Miranda, Harnly, Infante, Castillo, Wakarchuk and Cossé2017; Mafra-Neto et al., Reference Mafra-Neto, Ponce, Urrutia, Bernardi and Silva2018). Carmenza et al. (Reference Carmenza, Tapias, Jaramillo, Medina, Gonzalez, Casanova, Ortiz and Benavides2020) reported terpene-volatile compounds as a promising compound repellent for CBB control.

A better understanding of gene function and expression will reveal insights into relevant molecular pathways, informing updated pest control strategies. However, little research has been done on the molecular mechanism of CBB. The mechanisms of the invasion and diffusion of CBB are still unclear. Elucidating the adaptation mechanism to the environment of CBB and the infection mechanism of entomogenous fungi could help improve their control effectiveness against CBB. Moreover, as the genome draft of CBB has been sequenced, it will provide important genetic information for research on such molecular mechanisms (Vega et al., Reference Vega, Brown, Chen, Shen, Nair, Ceja-Navarro, Brodie, Infante, Dowd and Pain2015). Real-time quantitative polymerase chain reaction (RT-qPCR) is a reliable and useful method for the transcriptional expression level analyses of target genes, which has high specificity, accuracy, sensitivity, and reproducibility (Heid et al., Reference Heid, Stevens, Livak and Williams1996; Bustin, Reference Bustin2010). However, the result is easily affected by the RNA extraction quality, the efficiency of cDNA production using reverse transcription, the primer amplification efficiency, and so on. Therefore, introducing suitable reference genes for target gene expression normalisation is necessary for RT-qPCR analysis (Hu et al., Reference Hu, Fu, Hui, Sun, Zhang, Jin, Jiang, Gong, Xiong and Wu2018; Wang et al., Reference Wang, Meng, Zhu, Sun and Liu2019). No suitable ‘universal’ reference gene could be expressed constantly in all the organism and experimental conditions (Lee et al., Reference Lee, Sladek, Greenwood and Hudson2002). Therefore, it is essential to perform internal reference gene stability testing before performing RT-qPCR experiments. The ideal internal reference gene should express stably under whatever experimental conditions. To date, no single reference gene has been found suitable for all the experimental treatments, nor among species. Even though actin (ACT), β-tubulin (β-tub) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) were identified as traditional reference genes for a long time they expressed unstably in response to diverse experimental conditions or different species. For example, ACT, β-tub and GAPDH were identified as unstable reference genes in all treatments in Xylotrechus quadripes (Meng et al., Reference Meng, Shu, Sun, Wang, Yang, Zhu, Liu, Gao, Gou and Wang2022), In Helopeltis theivora, ACT was considered as the best reference gene only in tissues, and GAPDH only expressed stably in developmental stages. However, β-tub was unstable in all experimental conditions (Wang et al., Reference Wang, Meng, Zhu, Sun and Liu2019). GAPDH and β-tub were indicated unstable in all the treatments in Adelphocoris suturalis except ACT as the ideal reference gene in dsRNA infection (Luo et al., Reference Luo, Ma, Li, Zhu, Zhang, Lei, Jin, Joe and Chen2018). Besides, some novel reference genes such as ribosomal protein genes, elongation factor, eukaryotic translation initiation factor were verified as a set of potential internal control genes in the insect mentioned above. However, their stability was also influenced by different treatments or different species. Therefore, whether it is traditional internal reference or novel ones, we still need to verify the stability of these genes if we want to use them in CBB.

So far, no validated reference gene has been reported in CBB for differential experimental conditions. Thus, the object of this study is to identify the optimal reference genes of CBB in developmental stages, temperature stress, and B. bassiana infection treatment. Our study tests and validates a set of candidate reference genes for RT-qPCR in CBB. This should be useful for gene expression analysis in modern molecular genetic research in CBB.

Materials and methods

Insect colletion

The CBB was collected from the coffee plantation located in Wanning (Hainan province, China). Coffee berries with shotholes were brought back to the laboratory until the adults emerged. The newly emerged adults were reared singly with a fresh coffee berry in plastic cylindrical bottles. The laboratory condition was maintained at (26 ± 2) °C, (75 ± 5)% relative humidity, and a photoperiod cycle of 16 h L:8 h D.

Experimental treatments

Developmental stages

Different developmental stages of CBB including eggs, larvae, pupae, and adults were collected into RNase-free centrifuge tubes and stored at −80 °C for RNA extraction. Three biological replicates were set for each developmental stage. Each replicate included one hundred eggs, twenty larvae including all the instar, twenty pupae, and twenty adults.

Temperature stress

The CBB adults were exposed to three temperature treatments. Specifically, adults were acclimated for 4 h at low temperature 4℃, preference temperature 26℃ and high temperature 32℃. Twenty adults were collected for each treatment. Three biological replicates were set for each temperature exposure. Each replicate was collected into RNase-free centrifuge tubes and stored at −80 °C for RNA extraction.

B. bassiana infection treatment

The B. bassiana strain used was isolated from the CBB cadavers collected in a wild coffee field in Wanning (Hainan province, China). The strain was purified and cultured by PDA medium in the laboratory and stored at China centre for type culture collection (CCTCC NO: M2017045). A spore suspension with a concentration of 1 × 107 conidia ml−1 was prepared with 0.05% Tween-80 sterile water. In total, sixty CBB adults were immersed into the spore suspension for 5 s and raised in the sterilised dishes. Twenty treated adults were collected into RNase-free centrifuge tubes after 12 h, 24 h, and 48 h, respectively. Three replicates were obtained for each treatment. All the samples were stored at −80 °C for RNA extraction.

Total RNA extraction and cDNA synthesis

Total RNA from different treatments was extracted using TRIzol Reagent (Invitrogen, USA). Disrupt and homogenised each sample using 1 ml TRIzol reagent, and then incubated for 5 min at room temperature. 200 μl of chloroform was added and each sample shaken vigorously for 15 s, before further incubation at room temperature for 3 min. Samples were centrifuged for 15 min at 13,400 × g at 4 °C, and the aqueous phase was transferred to a new centrifuge tube with the same volume of isopropanol added. Following incubation for 10 min, the samples were centrifuged with 13,400 × g for 10 min at 4 °C and the supernatant was discarded. The resulting precipitation was resuspended and vortexed briefly with 1 ml 75% ethanol for 2~3 times. The supernatant was discarded and the RNA pellet was air-dried and an appropriate amount of RNase-free water was added to dissolve the precipitate. Finally, the quality and purity of total RNA was determined by fluorescence microplate reader (BioTek, USA).

The cDNA synthesis was conducted following the protocol of PrimeScript RT reagent Kit (TIANGEN, China). Specifically, we mixed 1 μg of total RNA, 2 μl of 5 × gDNA Eraser Buffer, and additional RNase free water up to 10 μl in an RNase-free tube, incubated the mixture at 42 °C for 3 min and chilled immediately in ice. Another RNase-free tube was prepared containing 10 μl mixture that included 2 μl 10 × King RT Buffer, 1 μl FastKing RT Enzyme Mix, 2 μl FQ-RT Primer Mix, and 5 μl RNase free water. The two 10 μl solutions were then mixed to make a final volume up of 20 μl. The reverse transcription reaction was performed at 42 °C for 15 min, then 95 °C for 3 min using a PCR Amplifier. Finally, the products were stored at −20 °C before use.

Reference gene selection and primer design

Nine candidate reference genes were selected for stability evaluation in this study, including GAPDH, elongation factor EF-1 alpha (EF1α), 60S ribosomal protein L3 (RPL3), 60S ribosomal protein L10 (RPL10), 40S ribosomal protein S3a (RPS3a), 40S ribosomal protein S9 (RPS9), alpha-actinin (α-ACT), eukaryotic translation initiation factor 4A (EIF4A), TATA box-binding protein (TATA). The accession numbers were listed in Table 1. The primers were designed by an online tool (NCBI, http://www.ncbi.nlm.nih.gov/tools/primer-blast/). The amplification efficiency and primer specificity were assessed by standard curves and melt curve analyses. To be specific, the PCR products were firstly confirmed to be the target fragments by bidirectional sequencing and alignment with the uploaded sequence, and then detected and purified using 1% agarose gel electrophoresis and the E.Z.N.A.™ Gel Extraction Kit (Omega, USA) respectively. The DNA fragments were ligate with pMD-19 T, and the products were transformed into Escherichia coli DH5α (TaKaRa, China), before extraction of the plasmid by E.Z.N.A.™ Plasmid Miniprep Kit Ⅱ (Omega, USA). Finally, the plasmid was used as the templates for the standard curve and melt curve analysis.

Table 1. Primer characteristics of nine candidate reference genes for RT-qPCR in H. hampei

RT-qPCR analyses

RT-qPCR reactions were performed on the BioRad CFX96 Real-Time PCR detection system with 2 × TB Green Premix Ex Taq (TaKaRa, China). Three technical replicates were performed for each biological sample. A 20 μl reaction system included 10 μl TB Green Premix Ex Taq, 1 μl template, 0.5 μl forward primer, 0.5 μl reverse primer and 8 μl ddH2O. Amplification parameters were as follows: initial denaturation at 95 °C for 3 min, followed by 40 cycles at 95 °C for 10 s and 60 °C for 30 s. Finally, a melting curve analysis from 65 °C to 95 °C was formed to ensure the consistency and specificity of the amplified product. The standard curves were drawn by a ten-fold dilution series of the plasmid. The efficiency (E) and correlation coefficient (R2) of each primer pair were calculated by the regression equation (Pfaffl et al., Reference Pfaffl, Tichopad, Prgomet and Neuvians2004): E = (10[–1/slope] −1) × 100.

Stability evaluation of candidate reference genes

The stability of expression levels of nine candidate reference genes was assessed using the following four software tools (or algorithms), including NormFinder, BestKeeper, geNorm, and ReFinder. NormFinder determines the expression stability by considering intra-and inter-group variations and provides a stability value (SV) for each gene. The lower the value, the more stable the gene (Andersen et al., Reference Andersen, Jensen and Ørntoft2004). BestKeeper uses the standard deviations (SD) of the Ct values and PCR efficiency to determine the optimal reference genes. The stable reference genes are always with SD values below 1 (Pfaffl et al., Reference Pfaffl, Tichopad, Prgomet and Neuvians2004). The geNorm software calculate the pairwise variation of every control gene with all other control genes as the SD of the logarithmically transformed expression ratios, and defined the internal control gene-stability measure M as the average pairwise variation of a particular gene with all other control genes. Gene expression is considered stable when the M value is below 1.5, and the lowest M values are produced by genes with the most stable expression. Furthermore, the pairwise variation (V) can be calculated by geNorm. The optimal normalisation reference gene number is determined by Vn/Vn +1. The ‘n’ represents the number of internal reference genes introduced when calculating Vn/Vn +1. And 0.15 is the threshold of Vn/Vn +1. The value of Vn/Vn +1 below 0.15 means that the optimal number of reference gene recommended is n. If Vn/Vn +1 is greater than 0.15, a new internal reference gene needs to be added until Vn/V (n + 1) is less than 0.15 (Vandesompele et al., Reference Vandesompele, Preter, Pattyn, Poppe, Roy, Paepe and Speleman2002). Due to the different ranking of reference genes analysed by the three algorithms above, the web-based program RefFinder, which is a comprehensive platform integrating the above three algorithms, is needed to provide an overall ranking of the stability of candidate reference genes (Xie et al., Reference Xie, Xiao, Chen, Xu and Zhang2012).

Validation of recommended reference genes

To verify the reliability of recommended reference genes, an important defence gene Lysozyme (Accession number: OR129683) was selected as a target gene. Lysozyme is an important defence gene in insects responses to pathogenic microorganism infection. Its expression level may vary with developmental stages, temperature stress, especially in pathogenic microorganism infection. So we chose it to detect its transcription levels normalised by different combination of the recommend reference genes in the three different treatments mentioned above. The specific primers for RT-qPCR were also designed by the online tool NCBI, the forward primer: (GATTACGTGGGCCTACTGGG) and the reverse primer: (GCACAATAAACGTCTCCGGC). Relative expression levels of Lysozyme were determined by the 2−ΔΔCt method (Livak and Schmittgen, Reference Livak and Schmittgen2001). All the treatments were performed with three biological and technical replicates. The one-way ANOVA test was used for data analyses. Expression differences of target genes in different treatments were performed by Student's t-tests using SPSS 20.0 (SPSS, Inc., United States).

Results

Amplification efficiency, primer specificity and expressional levels of candidate genes

To ensure the amplification efficiency and specificity of the primers, RT-qPCR amplifications and standard curves of each candidate reference gene were conducted. All products were sequenced and aligned to the target sequence. The amplification efficiencies of all primers were between 91.3% and 108.2%, and the associated R2 ranged from 0.931~0.999 (Table 1). Furthermore, the melt curve of each gene with one single peak also validated the primer specificities (fig. 1A-I).

Figure 1. Melt curve analysis of nine candidate reference genes.

Transcriptional profiles of nine candidate reference genes

The Ct values of nine candidate reference genes in different treatment conditions were obtained to compare the transcript abundance. The mean Ct values of different genes varied significantly and ranged from 17.82 to 25.74 in different treatment conditions (fig. 2), which indicated that it was reliable for further evaluation of expression stability.

Figure 2. Average Ct values of nine candidate reference genes for all experimental groups in H. hampei.

Stability assessment of the candidate reference genes in developmental stages

BestKeeper, Normfinder, and geNorm are three commonly algorithms used for identification of reference genes. In developmental stages, GAPDH was revealed to be the most stable reference gene based on BestKeeper, followed by EF1α, RPL3, RPS3a, TATA, α-ACT, RPS9, EIF4A, and RPL10. However, NormFinder recommended RPL3 as the best reference gene, EF1α ranked as the second stable gene, and the most unstable reference gene was α-ACT. The top two stable genes evaluated by geNorm were RPL3 and RPS3a, respectively, with α-ACT also identified as the least stable gene (Table 2). Besides, the number of optimal reference genes recommended for normalisation in developmental stages was two based on the V 2/V 3 < 0.15 (fig. 3A). Therefore, RPL3 and EF1α were recommended as the most stable reference genes according to the comprehensive analysis of RefFinder combined with the three algorithms above. The stability rank of the remaining genes was in order as RPL3, EF1α, RPS3a, TATA, GAPDH, RPS9, RPL10, EIF4A, and α-ACT, respectively (fig. 3B).

Table 2. Expression stability of candidate reference gene in developmental stages analysed by BestKeeper, NomFinder and geNorm.

Figure 3. Comprehensive ranking of expression stability of nine candidate reference genes in developmental stages of H. hampei. (a) Optimal number of reference genes for normalisation in developmental stages. (b) The stability of the nine housekeeping genes in developmental stages determined by RefFinder.

Evaluation of the optimal reference genes in temperature stress

The stability rankings obtained by BestKeeper and geNorm were almost the same. The two algorithms both recognised RPL10 and RPL3 as the top two stable genes. However, the result analysed by NormFinder was different. RPS3a and TATA were identified as the first and the second stable reference genes, respectively. EIF4A was indicated as the most unstable reference gene by the three algorithms (Table 3). Based on the value of Vn/Vn +1 calculated by geNorm, two optimal reference genes were recommended for gene expression normalisation (fig. 4A). The comprehensive analysis of the three software mentioned above using RefFinder showed that RPS3a and RPL3 were the two suitable reference genes, followed by RPL10, RPS9, TATA, EF1α, GAPDH, α-ACT and EIF4A, respectively (fig. 4B).

Table 3. Expression stability of candidate reference gene in temperature stress analysed by BestKeeper, NomFinder and geNorm

Figure 4. Comprehensive ranking of expression stability of nine candidate reference genes in H. hampei exposed to temperature stress. (a) Optimal number of reference genes for normalisation in temperature stress. (b) The stability of the nine housekeeping genes in temperature stress determined by RefFinder.

Determination of the suitable reference genes in B. bassiana infection treatment

The gene stability ranking was significantly different by BestKeeper, NormFinder, and geNorm algorithms. Specifically, EF1α was the most stable reference gene based on the analysis of BestKeeper, followed by RPS9, RPL10, RPL3, RPS3a, TATA, EIF4A, α-ACT, and GAPDH. However, NormFinder recommended RPL10 as the most stable gene, followed by RPL3, RPS3a, α-ACT, RPS9, EF1α, TATA, EIF4A, and GAPDH. According to geNorm analysis, the top two stable reference genes identified were EF1α and TATA respectively, and the most unstable gene was also GAPDH (Table 4). Furthermore, geNorm suggested adding two internal reference genes for normalisation (fig. 5A). Finally, EF1α and RPS3a were identified by RefFinder as suitable reference genes for normalisation of gene expression (fig. 5B).

Table 4. Expression stability of candidate reference gene in B. bassiana infection analysed by BestKeeper, NomFinder and geNorm

Figure 5. Comprehensive ranking of expression stability of nine candidate reference genes in H. hampei infected with B. bassiana. (a) Optimal number of reference genes for normalisation in B. bassiana infection. (b) The stability of the nine housekeeping genes in B. bassiana infection determined by RefFinder.

The stability ranking of candidate reference genes in all samples

For all samples, BestKeeper analysis revealed that RPL3 was the most stable gene, followed by RPS9, EF1α, RPL10, RPS3a, TATA, α-ACT, GAPDH, and EIF4A. NormFinder analysis suggested RPS3a was the most stable gene, followed by RPL3, EF1α, RPS9, TATA, RPL10, α-ACT, EIF4A, and GAPDH. However, geNorm analysis indicated RPL10 and RPS9 should be the most stable genes, followed with RPL3, RPS3a, EF1α, TATA, α-ACT, EIF4A, and GAPDH (Table 5). Furthermore, according to geNorm analysis, also two reference genes were required for normalisation accurately (fig. 6A). Finally, a comprehensive assessment of RefFinder revealed that RPL3 and RPS3a could be the best combination of reference genes for all samples (fig. 6B).

Table 5. Expression stability of candidate reference gene in all samples analysed by BestKeeper, NomFinder and geNorm

Figure 6. Comprehensive ranking of expression stability of nine candidate reference genes in all samples of CBB. (a) Optimal number of reference genes for normalisation in all samples. (b) The stability of the nine housekeeping genes in all samples determined by RefFinder.

Validation of reference gene selection

The expression level of one target gene Lysozyme, an innate immune defence factor, was analysed across developmental stages, temperature stress and B. bassiana infection conditions to verify the reliability of reference gene selection. The most stable reference gene (RPL3), the two best reference genes (RPL3 & EF1α) combination and the most unstable reference gene (α-ACT) were used for normalisation in different developmental stages. The relative expression level of Lysozyme gene normalised by α-ACT in larva, pupa, and adult was significantly different compared to normalised by RPL3 and RPL3 & EF1α combination. Lysozyme exhibited similar expression profiles in all three developmental stages above, whether using RPL3 alone or RPL3 & EF1α combination (fig. 7A). In temperature stress, the best reference gene (RPS3a), the top two stable reference genes combination (RPS3a & RPL3) and the most unstable gene EIF4A were used for gene expression normalisation. For 4℃ treatment, The relative expression level of Lysozyme standardised by EIF4A showed significant difference with the results standardised by RPS3a and RPS3a & RPL3 combination. For the 32℃ treatment, there was a significant difference in Lysozyme expression levels when standardised by EIF4A compared to the RPS3a & RPL3 combination (fig. 7B). For the B. bassiana infection, the most stable reference gene (EF1α), the best reference gene combination (EF1α & RPS3a) and the most unstable reference gene (GAPDH) were tested. After infection for 24 h, the gene expression profiles of Lysozyme standardised by GAPDH exhibited highly significant difference to those of Lysozyme standardised by EF1α and the EF1α & RPS3a combination. The relative expression level normalised by EF1α was significantly different with GAPDH only after infection for 48 h (fig. 7C).

Figure 7. Validation of reference genes using Lysozyme gene. The relative expression levels of a target gene Lysozyme were normalised by the recommended stable reference genes and unstable gene in development stages (a), temperature stress (b) and B. bassiana infection (c). Asterisk indicated that Lysozyme relative expression normalised by one reference gene or combination of two references was significant differences among different treatment. One asterisk means P < 0.05 analysed by Duncan's test, and two asterisks means P < 0.01 analysed by Duncan's test.

Discussion

RT-qPCR is a widely used molecular technique for the analyses of target gene transcript levels in different experimental treatments. The stably expressed reference genes play an important role in normalising the expression level of a target gene. However, the stability of reference genes is usually affected by the experimental conditions, leading to inaccurate results. Therefore, the selection of reference genes is an essential step for molecular biology research in a specific organism under a specific experimental condition using RT-qPCR.

Although CBB is the most destructive pest of the coffee plant, the molecular biology research of this species is still in its infancy. The construction of the CBB genome draft and analysis of transposable elements provided enough gene information for molecular physiology study (Vega et al., Reference Vega, Brown, Chen, Shen, Nair, Ceja-Navarro, Brodie, Infante, Dowd and Pain2015; Hernandez-Hernandez et al., Reference Hernandez-Hernandez, Fernández-Medina, Navarro-Escalante, Nuňez, Benavides-Machado and Carareto2017). This study was the first to evaluate the expression stability of nine candidate reference genes under different conditions of developmental stages, temperature stress, and B. bassiana infection using BestKeeper, NormFinder, geNorm and RefFinder software. In terms of the results, the rankings of gene stability obtained by BestKeeper, NormFinder and geNorm algorithms were not exactly the same under the same condition. For example, GAPDH was recommended as the most stable reference gene by BestKeeper in developmental stages. However, NormFinder identified it was not. Under temperature stress, the top two stable genes based on BestKeeper and geNorm are the gene ranking were totally the same, namely RPL10 and PRL3. However, NormFinder indicated RPS3a and TATA as the most two stable genes. The situation in B. bassiana infection treatment was almost the same. The most stable genes recommended by the BestKeeper, NormFinder and geNorm were totally different. Therefore, to ensure the result reliability, the final determined results required an integrated evaluation of the three algorithms above using the online analysis software RefFinder, which could help to obtain the optimal reference genes.

The recommended reference genes for CBB were significantly different from species of the same family (Curculionidae) under the same treatment conditions. Specifically, Sympiezomias velatus (Li et al., Reference Li, Li, Cheng, Li, Sun, Gao, Ju, JIiang, Du, Qu and Qu2018) and Anthonomus eugenii Cano (Pinheiro and Siegfried, Reference Pinheiro and Siegfried2020), demonstrating that reference genes cannot be extrapolated across closely related species. In this study, the traditional reference gene, such as α-ACT and GAPDH, were not predicted as the most stable reference genes. Instead, they were both considered as the most unstable genes. Based on our results, the most stable reference genes were mainly RPL3, RPS3a, and RPL10, which all belong to ribosomal protein widely distributed and high conserved in eukaryotes (Deiorio-Haggar et al., Reference Deiorio-Haggar, Anthony and Meyer2013). Recently, numerous studies have indicated that ribosomal protein can be used as reference genes. For example, RPL32 and RPS15 were the most stable reference genes for developmental stages in A. suturalis (Luo et al., Reference Luo, Ma, Li, Zhu, Zhang, Lei, Jin, Joe and Chen2018), RPS27a and RPL10a for insecticide stress in X. quadripes (Meng et al., Reference Meng, Shu, Sun, Wang, Yang, Zhu, Liu, Gao, Gou and Wang2022), RPS20 for different temperatures in Diaphorina citri (Bin et al., Reference Bin, Pu, Shu, Luo, Kang, Tang, Wu and Lin2019), RPS3a for different sexes in Diaphania caesalis (Wang et al., Reference Wang, Meng, Zhu, Sun, Liu and Gou2020), RPL13A and RPS3A for developmental stages and tissues in H. theivora (Wang et al., Reference Wang, Meng, Zhu, Sun and Liu2019), RPS18 and RPL13 for Lipaphis erysimi (Koramutla et al., Reference Koramutla, Aminedi and Bhattacharya2016). This study supports the use of ribosomal protein genes as reference genes. Another gene TATA was unstable in all the treatment based on our result. But it was recommended as a suitable reference gene for efficient normalisation among treatments of host-plant resistance experiments, tissues, and developmental stages of Aphis glycines (Bansal et al., Reference Bansal, Mamidala, Rouf Mian, Mittapalli and MICHEL2012). Therefore, due to their stability vary within different organisms or under different conditions, this is also why we need to evaluate their stability in CBB.

In summary, the expression stability of nine candidate reference genes of CBB was comprehensively assessed by four common programs. The final results determined that the combination of RPL3 and EF1α were recommended as the most stable reference genes for developmental stages, the RPS3a and RPL3 combination were confirmed as the optimal reference genes for temperature stress and all samples, the EF1α and RPS3a combination were determined the ideal reference genes for B. bassiana infection. Our results should be beneficial for analysing the expression profiles of target genes in the future, especially for molecular studies on insect genetic development, temperature adaptability and immune responses to entomogenous fungi in H. hampei.

Acknowledgements

This work was supported by grants from National Key R & D Program of China (No. 2020YFD1001202), Belt & Road Program, CAST (Grant No. 2020ZZGJB072046) and The First Batch of Key Discipline on Public Health in Chongqing.

Footnotes

*

These authors contributed equally to this study.

References

Andersen, CL, Jensen, JL and Ørntoft, TF (2004) 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 Research 64, 52455250.CrossRefGoogle Scholar
Aristizábal, LF, Olga, L and Arthurs, SP (2012) Implementing an integrated pest management program for coffee berry borer in a specialty coffee plantation in Colombia. Journal of Integrated Pest Management 3, G1G5.CrossRefGoogle Scholar
Azrag, A and Babin, R (2023) Integrating temperature-dependent development and reproduction models for predicting population growth of the coffee berry borer, Hypothenemus hampei Ferrari. Bulletin of Entomological Research 113, 7985.CrossRefGoogle ScholarPubMed
Azrag, A, Yusuf, A, Pirk, C, Niassy, S, Mbugua, K and Babin, R (2020) Temperature-dependent development and survival of immature stages of the coffee berry borer Hypothenemus hampei(Coleoptera: Curculionidae). Bulletin of Entomological Research 110, 207218.CrossRefGoogle ScholarPubMed
Baker, PS (1999) The coffee berry borer in Colombia. Final report of the DIFI-Cenicafé-CABI Bioscience IPM for coffee project. Chinchiná, Colombia.Google Scholar
Bansal, R, Mamidala, P, Rouf Mian, MA, Mittapalli, O and MICHEL, AP (2012) Validation of reference genes for gene expression studies in Aphis glycines (Hemiptera: Aphididae). Entomological Society of America 105, 14321438.Google ScholarPubMed
Barrera, JF, Moore, D, Abraham, YJ, Murphy, ST and Prior, C (1990) Biological control of the coffee berry borer, Hypothenemus hampei, in Mexico and possibilities for further action. In Brighton Crop Protection Conference, Pests and Diseases, Vol. 1, pp. 391396.Google Scholar
Bin, SY, Pu, XH, Shu, B, Luo, S, Kang, C, Tang, Y, Wu, Z and Lin, J (2019) Selection of reference genes for optimal normalization of quantitative real-time polymerase chain reaction results for Diaphorina citri adults. Journal of Economic Entomology 112, 355363.CrossRefGoogle ScholarPubMed
Bustin, SA (2010) Developments in real-time PCR research and molecular diagnostics. Expert Review of Molecular Diagnostics 10, 713715.CrossRefGoogle ScholarPubMed
Carmenza, EG, Tapias, J, Jaramillo, J, Medina, R, Gonzalez, S, Casanova, H, Ortiz, A and Benavides, P (2020) Evaluation of terpene-volatile compounds repellent to the coffee berry borer, Hypothenemus hampei (Ferrari) (Coleoptera: Curculionidae). Journal of Chemical Ecology 46, 881890.Google Scholar
Chiu-Alvarado, P and Rojas, JC (2008) Host location behaviour by two Cephalonomia spp. (Hymenoptera: Bethylidae) wasps associated with the coffee berry borer Hypothenemus hampei (Coleoptera: Curculionidae: Scolytinae). International Journal of Tropical Insect Science 28, 179184.Google Scholar
Cruz-López, L, Díaz-Díaz, B and Rojas, JC (2016) Coffee volatiles induced after mechanical injury and beetle herbivory attract the coffee berry borer and two of its parasitoids. Arthropod-Plant Interact 10, 151159.CrossRefGoogle Scholar
Cruz Roblero, E.N. and Malo, E.A. (2013) Chemical analysis of coffee berry volatiles that elicit an antennal response from the coffee berry borer Hypothenemus hampei. Journal of the Mexican Chemical Society 57, 321327.Google Scholar
Damon, A (2000) A review of the biology and control of the coffee berry borer, Hypothenemus hampei (Coleoptera: Scolytidae). Bulletin of Entomological Research 90, 453465.CrossRefGoogle ScholarPubMed
Deiorio-Haggar, K, Anthony, J and Meyer, MM (2013) RNA structures regulating ribosomal protein biosynthesis in bacilli. RNA Biology 10, 11801184.CrossRefGoogle ScholarPubMed
Duque-O, H and Baker, PS (2003) Devouring Profit; the Socio-Economics of Coffee Berry Borer IPM, Chinchiná, Colombia. Colombia: The Commodities Press, CABI, Cenicafé.Google Scholar
Espinoza, JC, Infante, F, Castillo, A, Pérez, J, Nieto, G, Pinson, EP and Vega, FE (2009) The biology of Phymastichus coffea LaSalle (Hymenoptera: Eulophidae) under feld conditions. Biological Control 49, 227233.CrossRefGoogle Scholar
Heid, CA, Stevens, J, Livak, KJ and Williams, PM (1996) Real time quantitative PCR. Genome Research 6, 986994.CrossRefGoogle ScholarPubMed
Hernandez-Hernandez, EM, Fernández-Medina, RD, Navarro-Escalante, L, Nuňez, J, Benavides-Machado, P and Carareto, CMA (2017) Genome-wide analysis of transposable elements in the coffee berry borer Hypothenemus hampei (Coleoptera: Curculionidae): description of novel families. Molecular Genetics & Genomics Mgg 292, 565583.CrossRefGoogle ScholarPubMed
Hu, Y, Fu, H, Hui, Q, Sun, S, Zhang, W, Jin, S, Jiang, S, Gong, Y, Xiong, Y and Wu, Y (2018) Validation and evaluation of reference genes for quantitative real-time PCR in Macrobrachium nipponense. International Journal of Molecular Sciences 19, 22582273.CrossRefGoogle ScholarPubMed
Infante, F (2018) Pest management strategies against the coffee berry borer (Coleoptera: Curculionidae: Scolytinae). Journal of Agricultural and Food Chemistry 66, 52755280.CrossRefGoogle ScholarPubMed
Infante, F, Valdéz, J, Penagos, DI and Barrera, JF (1994) Description of the life stages of Cephalonomia stephanoderis (Hymenoptera: Bethylidae), a parasitoid of Hypothenemus hampei (Coleoptera: Scolytidae). Vedalia 1, 1318.Google Scholar
Infante, F, Pérez, J and Vega, FE (2012) Farming: redirect research to control coffee pest. Nature 489, 502.CrossRefGoogle ScholarPubMed
Jaramillo, J, Torto, B, Mwenda, D, Troeger, A, Borgemeiste, C, Poehlingr, HM and Francke, W (2013) Coffee berry borer joins bark beetles in coffee klatch. PLoS One 8, e74277.CrossRefGoogle ScholarPubMed
Koramutla, MK, Aminedi, R and Bhattacharya, R (2016) Comprehensive evaluation of candidate reference genes for qRT-PCR studies of gene expression in mustard aphid, Lipaphis erysimi (Kalt). Scientific Reports 6, 25883.CrossRefGoogle ScholarPubMed
Lee, PD, Sladek, R, Greenwood, CM and Hudson, TJ (2002) Control genes and variability: absence of ubiquitous reference transcripts in diverse mammalian expression studies. Genome Research 12, 292297.CrossRefGoogle ScholarPubMed
Le Pelley, R.H. (1973) Coffee insects. Annual Review of Entomology 18, 121142.CrossRefGoogle Scholar
Li, X, Li, JW, Cheng, B, Li, W, Sun, WX, Gao, HY, Ju, Q, JIiang, XJ, Du, L, Qu, CJ and Qu, MJ (2018) Screening of reference genes for quantitative real-time PCR in sympiezomias velatus (coleoptera: curculionidae). Acta Entomologica Sinica 61, 1284–1249.Google Scholar
Livak, KJ and Schmittgen, TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method. Methods (San Diego, Calif.) 25, 402408.CrossRefGoogle ScholarPubMed
Luo, J, Ma, C, Li, Z, Zhu, BQ, Zhang, J, Lei, CL, Jin, SX, Joe, JH and Chen, LZ (2018) Assessment of suitable reference genes for qRT-PCR analysis in Adelphocoris suturalis. Journal of Integrative Agriculture 17, 27452757.CrossRefGoogle Scholar
Mafra-Neto, A, Ponce, JI, Urrutia, WH, Bernardi, CR and Silva, ROD (2018) Compositions and methods for repelling coffee berry borer. U.S. Patent No. 9,877,477.Google Scholar
Meng, Q, Shu, B, Sun, S, Wang, Y, Yang, M, Zhu, E, Liu, A, Gao, S, Gou, Y and Wang, Z (2022) Selection of reference genes for quantitative real-time PCR normalization in the coffee white stem borer, Xylotrechus quadripes Chevrolat (Coleoptera: Cerambycidae). Bulletin of Entomological Research 112, 151161.CrossRefGoogle ScholarPubMed
Pereira, AE, Vilela, EF, Tinoco, RS, de Lim, JOG and Frana, CFM (2012) Correlation between numbers captured and infestation levels of the coffee berry-borer, Hypothenemus hampei: a preliminary basis for an action threshold using baited traps. International Journal of Pest Management 58, 183190.CrossRefGoogle Scholar
Pfaffl, MW, Tichopad, A, Prgomet, C and Neuvians, TP (2004) Determination of stable housekeeping genes, differentially regulated target genes and sample integrity: BestKeeper-Excel-based tool using pair-wise correlations. Biotechnology Letters 26, 509515.CrossRefGoogle ScholarPubMed
Pinheiro, DH and Siegfried, BD (2020) Selection of reference genes for normalization of RT-qPCR data in gene expression studies in Anthonomus eugenii Cano (Coleoptera: Curculionidae). Scientific Reports 10, 5070.CrossRefGoogle ScholarPubMed
Renault, D, Laparie, M, McCauley, SJ and Bonte, D (2018) Environmental adaptations, ecological filtering, and dispersal central to insect invasions. Annual Review of Entomology 63, 345368.CrossRefGoogle ScholarPubMed
Sinaga, M and Tobing, MC (2020) Comparison of attractants and height traps to coffee berry borer (Hypothenemus hampei Ferr. Coleoptera: Scolytidae) in Soban Village, Dairi Regency, North Sumatra, Indonesia. In Journal of Physics: Conference Series, Vol. 1485, pp. 012035Google Scholar
Sun, S, Wang, Z, Liu, A, Lai, C, Wang, J, Meng, Q, Gou, Y, Johnson, AJ and Li, Y (2020) First report of the coffee berry borer, Hypothenemus Hampei (Ferrari) (Coleoptera: Curculionidae: Scolytinae) on Hainan Island, China. The Coleopterists Bulletin 74, 710713.CrossRefGoogle Scholar
Umeda, C and Paine, T (2019) Temperature can limit the invasion range of the ambrosia beetle Euwallacea nr. fornicatus. Agricultural and Forest Entomology 21, 17.CrossRefGoogle Scholar
Vandesompele, J, Preter, KD, Pattyn, F, Poppe, B, Roy, NV, Paepe, AD and Speleman, F (2002) Accurate normalization of real-time quantitative rt-pcr data by geometric averaging of multiple internal control genes. Genome biology 3, 112.CrossRefGoogle ScholarPubMed
Vega, FE, Infante, F, Castillo, A and Jaramillo, J (2009) The coffee berry borer, Hypothenemus hampei (Ferrari) (Coleoptera: Curculionidae): a short review, with recent findings and future research directions. Terrestrial Arthropod Review 2, 129147.Google Scholar
Vega, FE, Brown, SM, Chen, H, Shen, E, Nair, MB, Ceja-Navarro, JA, Brodie, EL, Infante, F, Dowd, PF and Pain, A (2015) Draft genome of the most devastating insect pest of coffee worldwide: the coffee berry borer, Hypothenemus hampei. Scientific Reports 5, 12525.CrossRefGoogle ScholarPubMed
Vega, FE, Simpkins, A, Miranda, J, Harnly, JM, Infante, F, Castillo, A, Wakarchuk, D and Cossé, A (2017) A potential repellent against the coffee berry borer (Coleoptera: Curculionidae: Scolytinae). Journal of Insect Science 17, 122.CrossRefGoogle Scholar
Wallner, WE (1987) Factors affecting insect population dynamics: differences between outbreak and non-outbreak species. Annual Review of Entomology 32, 317340.CrossRefGoogle Scholar
Wang, Z, Meng, QQ, Zhu, X, Sun, SW and Liu, AQ (2019) Evaluation and validation of reference genes for quantitative real-time PCR in Helopeltis theivora waterhouse (Hemiptera: Miridae). Scientific Reports 9, 13291.CrossRefGoogle ScholarPubMed
Wang, Z, Meng, QQ, Zhu, X, Sun, SW, Liu, AQ and Gou, YF (2020) Identifcation and evaluation of reference genes for normalization of gene expression in developmental stages, sexes, and tissues of Diaphania caesalis (Lepidoptera, Pyralidae). Journal of Insect Science 20, 19.CrossRefGoogle Scholar
Xie, F, Xiao, P, Chen, D, Xu, L and Zhang, B (2012) miRDeepFinder: a miRNA analysis tool for deep sequencing of plant small RNAs. Plant Molecular Biology 80, 7584.CrossRefGoogle Scholar
Figure 0

Table 1. Primer characteristics of nine candidate reference genes for RT-qPCR in H. hampei

Figure 1

Figure 1. Melt curve analysis of nine candidate reference genes.

Figure 2

Figure 2. Average Ct values of nine candidate reference genes for all experimental groups in H. hampei.

Figure 3

Table 2. Expression stability of candidate reference gene in developmental stages analysed by BestKeeper, NomFinder and geNorm.

Figure 4

Figure 3. Comprehensive ranking of expression stability of nine candidate reference genes in developmental stages of H. hampei. (a) Optimal number of reference genes for normalisation in developmental stages. (b) The stability of the nine housekeeping genes in developmental stages determined by RefFinder.

Figure 5

Table 3. Expression stability of candidate reference gene in temperature stress analysed by BestKeeper, NomFinder and geNorm

Figure 6

Figure 4. Comprehensive ranking of expression stability of nine candidate reference genes in H. hampei exposed to temperature stress. (a) Optimal number of reference genes for normalisation in temperature stress. (b) The stability of the nine housekeeping genes in temperature stress determined by RefFinder.

Figure 7

Table 4. Expression stability of candidate reference gene in B. bassiana infection analysed by BestKeeper, NomFinder and geNorm

Figure 8

Figure 5. Comprehensive ranking of expression stability of nine candidate reference genes in H. hampei infected with B. bassiana. (a) Optimal number of reference genes for normalisation in B. bassiana infection. (b) The stability of the nine housekeeping genes in B. bassiana infection determined by RefFinder.

Figure 9

Table 5. Expression stability of candidate reference gene in all samples analysed by BestKeeper, NomFinder and geNorm

Figure 10

Figure 6. Comprehensive ranking of expression stability of nine candidate reference genes in all samples of CBB. (a) Optimal number of reference genes for normalisation in all samples. (b) The stability of the nine housekeeping genes in all samples determined by RefFinder.

Figure 11

Figure 7. Validation of reference genes using Lysozyme gene. The relative expression levels of a target gene Lysozyme were normalised by the recommended stable reference genes and unstable gene in development stages (a), temperature stress (b) and B. bassiana infection (c). Asterisk indicated that Lysozyme relative expression normalised by one reference gene or combination of two references was significant differences among different treatment. One asterisk means P < 0.05 analysed by Duncan's test, and two asterisks means P < 0.01 analysed by Duncan's test.