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Identification of QTLs for resistance to maize rough dwarf disease using two connected RIL populations in maize


Authors: Xintao Wang aff001;  Qing Yang aff001;  Ziju Dai aff001;  Yan Wang aff001;  Yingying Zhang aff001;  Baoquan Li aff001;  Wenming Zhao aff002;  Junjie Hao aff003
Authors place of work: Crop Designing Center, Henan Academy of Agricultural Sciences, Zhengzhou, China aff001;  Institute of Food Crops, Jiangsu Academy of Agricultural Sciences, Nanjing, China aff002;  Plant Protection Institute, Henan Academy of Agricultural Sciences, Zhengzhou, China aff003
Published in the journal: PLoS ONE 14(12)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0226700

Summary

Maize rough dwarf disease (MRDD) is a significant viral disease caused by rice black-streaked dwarf virus (RBSDV) in China, which results in 30% yield losses in affected summer maize-growing areas. In this study, two connected recombinant inbred line (RIL) populations were constructed to elucidate the genetic basis of resistance during two crop seasons. Ten quantitative trait loci (QTLs) for resistance to MRDD were detected in the two RILs. Individual QTLs accounted for 4.97–23.37% of the phenotypic variance explained (PVE). The resistance QTL (qZD-MRDD8-1) with the largest effect was located in chromosome bin 8.03, representing 16.27–23.37% of the PVE across two environments. Interestingly, one pair of common significant QTLs was located in the similar region on chromosome 4 in both populations, accounting for 7.11–9.01% of the PVE in Zheng58×D863F (RIL-ZD) and 9.43–13.06% in Zheng58×ZS301 (RIL-ZZ). A total of five QTLs for MRDD resistance trait showed significant QTL-by-Environment interactions (QEI). Two candidate genes associated with resistance (GDSL-lipase and RPP13-like gene) which were higher expressed in resistant inbred line D863F than in susceptible inbred line Zheng58, were located in the physical intervals of the major QTLs on chromosomes 4 and 8, respectively. The identified QTLs will be studied further for application in marker-assisted breeding in maize genetic improvement of MRDD resistance.

Keywords:

Maize – Genetic loci – Quantitative trait loci – Polymerase chain reaction – Leaves – Veterinary diseases – Inbred strains – Linkage mapping

Introduction

Maize (Zea mays L.) is an important food crop worldwide and is a major global source of protein and carbohydrates for humans and livestock. However, maize is the natural host of several viruses, some of which cause diseases that affect yield and quality in some maize production zones [1, 2]. In China, maize rough dwarf disease (MRDD) was first discovered in Xinjiang and Gansu in 1954, and then spread to other provinces [3, 4]. The main symptoms of MRDD include internode shortening, malformed tassels and significant delays in vegetative growth [57]. Four virus species in the genus Fijivirus, Mal de Río Cuarto virus (MRCV), maize rough dwarf virus (MRDV), rice black-streaked dwarf virus (RBSDV) and southern rice black-streaked dwarf virus (SRBSDV), are the causal pathogens of MRDD. MRDD is mainly caused by brown planthoppers carrying RBSDV in China [3, 4, 8].

No pesticides are available to cure RBSDV-infected maize [9]. Thus, MRDD resistance breeding is the most effective and environmentally friendly strategy for disease control [10, 11]. No genotypes with complete resistance to MRDD have ever been reported but a few highly resistant lines have been identified in China, most of which are mainly derived from P78599 (a US hybrid) [12, 13].

In recent years, some studies have been conducted to detect QTLs for MRDD resistance in maize, and a number of resistance QTLs distributed on all maize chromosomes have been identified [1420]. For example, Wang et al. [10] reported that resistance to MRDD is a quantitative trait that involves small individual effects. Di Renzo et al. [14] found two QTLs (chromosome bins 1.03 and 8.03) for resistance to Mal de Río Cuarto disease using a BLS14 × Mo17 population with 227 F2:3 families and 56 SSR markers. Additionally, using F2:3 populations and recombinant inbred lines (RILs) derived from 90110 × Ye478 crosses, Wang et al. [15] and Luan et al. [16] identified three and five QTLs for resistance to MRDD, respectively. A major QTL was located on chromosome 8 in these two populations. Moreover, the resistance QTL on chromosome 8.03 was consistently identified in two independent studies [17, 18], and the effect of this QTL was confirmed with a genome-wide association study (GWAS) by Chen et al. [19]. Recently, using SLAF-seq and SSR analysis, a major MRDD resistance locus on chromosome 6 was detected in F2 populations derived from a cross between the resistant line K36 and susceptible line S221 [20].

Most of the QTLs for MRDD resistance have been located at different chromosomal sites in diverse populations, suggesting that the inconsistent results in the above reports need to be further tested and validated [2127]. In this study, two maize RIL populations with a common female parent were used to detect QTLs for resistance to MRDD during two crop seasons. The major objectives of this study were to: (1) further reveal the genetic basis of resistance to MRDD in two connected RILs, (2) identify and characterize the QTL for MRDD resistance in these populations by inclusive and genome-wide composite interval mapping (ICIM and GCIM) approach, and (3) find consistent or major QTL for further fine mapping and marker-assisted breeding. These results will contribute to a better understanding of the genetic basis of resistance to MRDD in maize.

Materials and methods

Genetic materials

Two sets of RIL populations were used. One maize F8 RIL consisted of 241 lines derived from a cross between the Zheng58 and D863F lines. The second RIL population consisted of 242 F7 RILs derived from a cross between Zheng58 and ZS301. The two sets of RILs were developed by the single-seed descent method. The common parent (Zheng58) is one of the parental lines of the hybrid Zhengdan 958, an elite hybrid planted broadly in China. D863F and ZS301 were obtained from the Chinese Academy of Agricultural Sciences.

Evaluation of MRDD resistance in the field

The two populations and three parents were evaluated for MRDD resistance under natural infection over two years (2016 and 2017) in a high incidence area for MRDD: Kaifeng (N34°47′, E114°20′) in Henan Province. At the flowering stage, all plants were evaluated and scored for resistance to MRDD based on a disease rating scale of 0–4. The rating 0 indicates no symptom and 4 represents a highly susceptible phenotype [28, 29]. The disease severity index (DSI) of each RIL was calculated using the following equation: DSI (%) = ∑(disease rating scale score × number of plants in rating) × 100/(4 × total number of plants) [30].

Genotyping

Young leaves were collected from both RIL populations and their parents, and then genomic DNA for genotyping was isolated using a CTAB method [31]. In this study, 1,890 simple sequence repeat (SSR) primer pairs from the MaizeGDB (http://www.maizegdb.org/) and newly developed primers (S1 Table) were used to screen for polymorphisms between the two parental lines of each RIL population. Approximately 220 primer pairs showed polymorphisms between Zheng58 and D863F, and 190 primer pairs showed polymorphisms between Zheng58 and ZS301. Of these, 215 and 181 markers were used to construct genetic linkage maps in RIL-ZD and RIL-ZZ, respectively. The amplified PCR products were examined using a 3500xl DNA Analyzer (Applied Biosystems, Foster City, CA, USA). The reaction volume was 10 μl, consisting of 0.1 μl Taq DNA polymerase, 0.15 μl 10 mmol L−1 dNTP, 1.6 μl 10× PCR buffer (Mg2+), 0.4 μl forward, reverse and M13 primers, 2 μl DNA template, and 5.75 μl water.

Linkage map construction and QTL analysis

Genetic linkage maps were constructed from the SSR genotypes in both RILs using the JoinMap software version 4.0. To maximize the accuracy of mapping data, QTL IciMapping 4.0 based on a inclusive composite interval mapping (ICIM) model and QTL.gCIMapping via genome-wide composite interval mapping (GCIM) method were used to detect the QTL [3234]. A joint analysis of the two RIL populations was performed using the joint inclusive composite interval mapping (JICIM) method in IciMapping 4.0 [35]. QTL×environment interaction effects (QEI) in two connected RIL populations were estimated for MRDD resistance using the QTL IciMapping 4.0 [36].

Phenotypic data analysis

Phenotypic data were subjected to analysis of variance using the software package SPSS 12.0 (Chicago, IL, USA). The broad-sense heritability (h2) of MRDD resistance in each environment was calculated as follows: h2=σg2/(σg2+σgy2/n+σe2/nr), where σg2 represents the genotype variance, σgy2 represents the genotype-by-environment interaction variance, σe2 represents the error variance, and n and r are the number of environments and replications per environment, respectively.

Quantitative real-time PCR

The plants of Zheng58 and D863F were sown in 15 cm pots (three plants per pot) in a growth chamber under LD condition (15 h light and 9 h dark). The seedlings at the third leaf stage were exposed for 3 d in inoculation chambers with brown planthoppers. The leaves at 0 h, 24 h and 72 h after treatment were harvested, immediately frozen in liquid nitrogen and stored at –80°C. Three biological replicates, each consisting of leaves from three plants per sample, were performed.

Total RNA was isolated using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) followed by a treatment with RNase-free DNase (TaKaRa, Dalian, China) according to the manufacturer’s instructions. Complementary DNA was reverse-transcribed from 2 μg of total RNA using PrimeScript 1st Strand cDNA Synthesis Kit (TaKaRa) following the manufacturer's instructions. Quantitative real-time PCR (qPCR) was performed on a Bio-Rad real-time PCR detection system (Bio-Rad, Hercules, CA, USA). The reaction volume was 15 μl, consisting of SYBR Premix Ex Taq, 7.5 μl; gene-specific primers (forward; reverse), 0.6 μl for a final 20 pmol/L concentration; water, 5.3 μl and cDNA template, 1 μl. Each reaction was performed in triplicate.

The constitutive gene glyceraldehyde-3-phosphate dehydrogenase(GAPDH) was used as endogenous control to normalize expression in maize leaves. The quantification of gene expression levels was calculated relative to GAPDH using a 2 –ΔΔCT method [37]. The primers for the qPCR assay for each candidate gene and GAPDH were designed using the Primer5.0 software (S2 Table).

Results

Phenotypic analysis of the parental lines and two RIL populations

The performance of the three parents used to develop the RIL populations was evaluated in 2016 and 2017 (Table 1). The parental lines D863F, ZS301, and Zheng58 exhibited significant differences for resistance to MRDD under natural infection over the two years (Fig 1). Among the three parental lines, D863F was most resistant to MRDD (2016 DSI: 2.82%, 2017 DSI: 4.20%), followed by ZS301 (2016 DSI: 23.55%, 2017 DSI: 18.75%) and Zheng58 (2016 DSI: 90.25%, 2017 DSI: 93.96%). As shown in Table 1, the 241 RIL-ZD lines and 242 RIL-ZZ lines were also characterized by high variation in DSI, which ranged from 3.85 to 100% in RIL-ZD and 15.28 to 100% in RIL-ZZ. The heritability of MRDD resistance in RIL-ZD and RIL-ZZ was 0.82 and 0.87, respectively.

Fig. 1. The phenotypes of RBSDV-inoculated maize.
The phenotypes of RBSDV-inoculated maize.
(a) The RIL-ZZ parental lines ZS301 and Zheng58 during the flowering stage. (b) The RIL-ZD parental lines Zheng58 and D863F during the flowering stage.
Tab. 1. General statistics and heritability for DSI in the two RIL populations and their parents.
General statistics and heritability for DSI in the two RIL populations and their parents.

Linkage maps

A total of 1890 SSR markers were screened, and 215 and 181 were polymorphic between the Zheng58/D863F and Zheng58/ZS301 parental genotypes. The total lengths of the linkage maps for RIL-ZD and RIL-ZZ were 1832.35 cM and 1968.48 cM, respectively. The average interval lengths were 8.52 cM (RIL-ZD) and 10.87 cM (RIL-ZZ).

QTL identification for resistance to MRDD in the RIL-ZD population

Five QTLs for MRDD resistance were found in the RIL-ZD population by ICIM method (Table 2). The resistance QTLs were located on chromosomes 2 (bin 2.07–2.08), 4 (bin 4.07–4.08), 7 (bin 7.03–7.05), and 8 (bin 8.03 and bin 8.05). These QTLs were derived from the resistant inbred line D863F. The resistance QTL (qZD-MRDD8-1) with the largest effect was located in chromosome bin 8.03, linked with and flanked by SSR markers M105 and M108, representing 16.27–21.88% of the phenotypic variance explained (PVE) across the two years (Table 2). The second largest-effect QTL for MRDD resistance, qZD-MRDD7, which accounted for 8.48–10.73% of the PVE in the two environments, was located between SSR markers umc1841 and umc2333 in chromosome bin 7.03–7.05. The other three QTLs identified, qZD-MRDD2 on chromosome 2, qZD-MRDD4-1 on chromosome 4 and qZD-MRDD8-2 on chromosome 8, represented 6.08–8.93%, 7.11–7.21% and 10.05% of the PVE, respectively.

Tab. 2. QTLs for MRDD resistance detected in the RIL-ZD population in a 2-year experiment.
QTLs for MRDD resistance detected in the RIL-ZD population in a 2-year experiment.

By using QTL.gCIMapping, a total of six QTLs were detected in the RIL-ZD population(Table 2). Two on chromosome 8, and one each on chromosome 2, 4, 6 and 7, of which qZD-MRDD8-1 located on chromosome 8 accounted for the most phenotypic variation (23.37%).

QTL identification for resistance to MRDD in the RIL-ZZ population

Two QTLs for MRDD resistance were found in the RIL-ZZ population by ICIM method (Table 3). The resistance QTLs were located on chromosomes 2 (bin 2.02–2.03) and 4 (bin 4.08). These QTLs both came from the resistant line ZS301. The largest effect QTL (qZZ-MRDD4) was located in chromosome bin 4.08, linked with and flanked by SSR markers umc2285 and umc2041, accounting for 9.43–13.06% of the PVE across the two years (Table 3). The other QTL was a relatively minor QTL; qZZ-MRDD2 was flanked by SSR markers umc1261 and umc1185 and represented 9.04% and 7.19% of the PVE in 2016 and 2017, respectively.

Tab. 3. QTLs for MRDD resistance detected in the RIL-ZZ population in a 2-year experiment.
QTLs for MRDD resistance detected in the RIL-ZZ population in a 2-year experiment.

Four QTLs for MRDD resistance were found in the RIL-ZZ population by GCIM method (Table 3). The resistance QTLs were located on chromosomes 2, 4, 6 and10. The largest effect QTL (qZZ-MRDD4) was located on bin 4.08, accounting for 11.17–12.33% of the PVE across two years.

Comparison of QTLs between the two connected RILs

A total of ten QTLs (six in RIL-ZD and four in RIL-ZZ) for MRDD resistance were detected by QTL mapping in this study. Among these MRDD-resistance QTLs, one pair of QTLs was located in the similar region on chromosome 4: qZD-MRDD4-1 in RIL-ZD and qZZ-MRDD4 in RIL-ZZ. qZD-MRDD4-1 and qZZ-MRDD4 were derived from the resistant inbred lines D863F and ZS301, respectively, whereas the major QTL on chromosome 8 (qMRDD1-8) was only found in the RIL-ZD population.

QTL for MRDD resistance detected by JICIM in two RIL populations

The JICIM approach detected four QTLs on chromosomes 1, 2, 4 and 8 across the two connected RIL populations in the two environments (Table 4). The MRDD resistance QTLs on chromosomes 4 (qMRDD-4) and 8 (qMRDD-8) were detected in both years, while qMRDD-2 was only detected in 2016 and qMRDD-1 was only detected in 2017. qMRDD8 was located in chromosome bin 8.03, linked with and flanked by SSR markers M105 and M108, accounting for 12.32–16.03% of the PVE across the two years. qMRDD4 was in chromosome bin 4.07–4.08 and explained 5.32–7.78% of the phenotypic variance.

Tab. 4. QTLs for MRDD resistance detected by joint inclusive composite interval mapping (JICIM) in the two RIL populations.
QTLs for MRDD resistance detected by joint inclusive composite interval mapping (JICIM) in the two RIL populations.

QTL × environment interactions for MRDD resistance

In order to estimate the interaction between QTLs and environments for MRDD resistance, the QTL×environment interaction (QEI) analysis was conducted in two connected RILs (Table 5). In RIL-ZD, a total of four QEIs were identified and distributed on chromosomes 4, 8 and 10, the phenotypic variation explained by each QTL ranged from 3.35 to 6.74%, and the phenotypic variation explained by each QTL × environment interaction ranged from 0.02 to 3.63%.

In RIL-ZZ, one QEI for MRDD resistance was identified and distributed on chromosome 4, the phenotypic variation explained by QTL and QTL×environment interaction were 3.79% and 0.09%, respectively.

Tab. 5. QTL×environment interactions for resistance to MRDD in two RIL populations.
QTL×environment interactions for resistance to MRDD in two RIL populations.

Candidate gene prediction and qPCR analysis

To further explore the molecular mechanism of MRDD resistance in maize, we identified candidate genes through the National Center for Biotechnology Information (NCBI) and MaizeGDB databases. According to the BLAST results, several candidate genes associated with resistance were located in the physical intervals of the QTLs on chromosomes 4 and 8, such as GDSL-lipase and RPP13-like.

In order to further test the behavior of candidate genes, we used a qPCR assay to measure mRNA abundance in the leaves of Zheng58/D863F (Fig 2). In resistant inbred line D863F, the GDSL-lipase and RPP13-like expression began to rapidly increase after RBSDV infection, finally reaching highest level at 72 h. However, GDSL-lipase and RPP13-like expression had little change in susceptible inbred line Zheng58, and the expression level of these two genes was higher in resistant inbred line D863F than in susceptible inbred line Zheng58. The above results indicated that GDSL-lipase and RPP13-like might contribute to MRDD resistance in maize.

Fig. 2. Real-time PCR quantitative analysis of two candidate genes in Zheng58 and D863F plants.
Real-time PCR quantitative analysis of two candidate genes in Zheng58 and D863F plants.
(a) qPCR analysis of GDSL-lipase. (b) qPCR analysis of RPP13-like. The average values (mean ± SEM) are based on three independent experiments.

Discussion

Analyzing MRDD resistance in two connected populations

Identification of QTLs/genes conferring resistance to MRDD and resistance breeding are the most effective and economic measures for controlling this disease [20]. Thus, screening and evaluation of MRDD resistance in maize germplasm is necessary for breeding resistant maize hybrids. In our previous study, we identified some different resistant materials that might contain different resistance genes [38]. In this study, the paternal line D863F exhibited high resistance and ZS301 displayed moderate resistance, whereas the maternal line Zheng58 showed high susceptibility. The DSI results showed that the resistant lines D863F and ZS301 might each contain specific resistance genes.

Comparison of QTLs detected in the two RIL populations

We verified six and four QTLs for MRDD resistance in RIL-ZD and RIL-ZZ in the two environments, respectively (Tables 2 and 3). Among the MRDD-resistance QTLs identified in the two connected RILs, qZD-MRDD4-1 and qZZ-MRDD4 were located in a similar region on chromosome 4, suggesting that these QTLs might be controlled by the same gene(s). However, several other QTLs for MRDD resistance were detected between the different RIL populations. Five QTLs (qZD-MRDD2, qZD-MRDD6, qZD-MRDD7, qZD-MRDD8-1 and qZD-MRDD8-2) were detected in RIL-ZD, while only three minor QTLs (qZZ-MRDD2, qZZ-MRDD6 and qZZ-MRDD10) were identified in RIL-ZZ. These results suggest that resistance to MRDD in maize might be controlled by population-specific QTLs, and qZD-MRDD8-1 should contain an important resistance gene based on its effect on MRDD disease. ICIM is a widely used method for mapping QTLs in biparental populations [39], and GCIM was reported to have improved QTLs detection power, especially small QTLs [40]. In this study, we compared the outputs of IciMapping and gCIMapping, and found 7 common QTLs for MRDD resistance trait. Among them, QTL qZD-MRDD8-1 was mapped in the marker interval of M105-M108 by both ICIM and GCIM approaches. It should be noted that three small QTLs (qZD-MRDD6, qZZ-MRDD6, qZZ-MRDD10) for MRDD resistance were detected only by gCIMapping. Based on the results of this study and previous investigations [26, 27, 41], we speculate that MRDD resistance is a complex genetic trait that is regulated by multiple resistance genes.

Plant growth and development are controlled by genetic composition and environment, as well the interaction between them [42]. In maize, in spite of that QTL×environment interaction for some traits have been described [43, 44], QTL×environment interaction for MRDD resistance has not been reported so far. In this study, five QEIs for MRDD resistance were detected for multi-environment phenotypic values using IciMapping, indicating that the genetic and molecular mechanisms of resistance to MRDD were partly influenced by the environment. However, since these QEIs effects for MRDD resistance were relatively small, it is assumed that this trait was more significantly affected by genotype than by environment.

Comparison of QTLs detected in previous studies

To date, several labs have identified numerous QTLs conferring resistance to MRDD. A major resistance QTL has been consistently mapped in the region of bin 8.03 on chromosome 8 in different mapping populations [16, 17]. Additionally, a major QTL for MRCV resistance at the same position on chromosome 8 was identified by Di Renzo et al. [14], Bonamico et al. [23] and Rossi et al. [25]. In our study, qZD-MRDD8-1 in RIL-ZD was located in a similar region on chromosome 8 across two years. These results suggest that resistance to different MRDD viruses might have a common mechanism in maize and this region on chromosome 8 might have a core gene homolog conferring resistance to MRDD. We strongly believe that this QTL could serve as a major QTL for gene cloning or marker-assisted selection.

A QTL (qZD-MRDD4-1 and qZZ-MRDD4) on chromosome 4 was common to both RIL populations. In a previous study, Hao et al. [27] detected a locus significantly associated with MRDD DSI on chromosome 4.09 by GWAS. Bonamico et al. [23] also identified a QTL for MRCV resistance on chromosome 4.05. The genomic locations of these QTLs suggest that they are distinct from qZD-MRDD4-1/qZZ-MRDD4. Therefore, we suppose that qZD-MRDD4-1/qZZ-MRDD4 is a novel and stable QTL conferring resistance to MRDD.

In recent QTL experiments, Luan et al. [16] detected a QTL for MRDD resistance on bin 2.02 through QTL mapping. Li et al. [20] detected a single dominant locus significantly associated with MRDD on bin 6.01 by SLAF-seq. Rossi et al. [23] identified a QTL for MRCV resistance on bin 10.03. In our study, qZD-MRDD2 in RIL-ZD and qZZ-MRDD6/qZZ-MRDD10 in RIL-ZZ were located in a similar region on chromosomes 2, 6 and 10 across one or two years.

Associations between QTLs and candidate genes for MRDD resistance in maize

The virus-resistance mechanism for MRDD in maize is very complex, and little is known about the molecular mechanism and candidate genes for MRDD resistance in maize [20, 41]. According to the BLAST results, several candidate genes were located in the physical intervals of the QTLs on chromosomes 4 and 8, such as GDSL-lipase on chromosome 4 and RPP13-like on chromosome 8. GDSL-lipase genes are well represented in the plant immune system, and have been shown to be induced by both biotic and abiotic stress. GDSL LIPASE1 is involved in pathogen responses in Arabidopsis thaliana [45]. RPP13 is thought to function independently of NDR1/EDS1 and SA responses to Peronospora parasitica in Arabidopsis [46]. These predicted genes could be possible candidates for resistance to MRDD. Further studies are necessary to construct near isogenic lines at bins 4.07 and 8.03 and perform positional cloning.

Supporting information

S1 Table [xlsx]
Information on newly developed primers used in linkage map construction and QTL analysis in this study.

S2 Table [xlsx]
Primer sets for real-time PCR analysis in this study.


Zdroje

1. Ali F, Yan J. Disease resistance in maize and the role of molecular breeding in defending against global threat. Journal of Integrative Plant Biology. 2012; 54(3): 134–151. doi: 10.1111/j.1744-7909.2012.01105.x 22333113

2. Lv P, Zhang J, Su K, Liu W, Liu P, Yang J, et al. Effects of rough dwarf disease on yield and plant characteristics of summer maize. Journal of Maize Sciences. 2010; 18(2): 113–116.

3. Fang S, Yu J, Feng J, Han C, Li D, Liu Y. Identification of rice black-streaked dwarf fijivirus in maize with rough dwarf disease in China. Archives of Virology. 2001; 146(1): 167–170. doi: 10.1007/s007050170200 11266211

4. Tao YF, Liu QC, Xu ML. The research progress on maize rough dwarf disease. Journal of Maize Sciences. 2013; 21(1): 149–152.

5. Milne RG, Lovisolo O. Maize rough dwarf and related viruses. Advances in Virus Research. 1977; 21: 267–341. doi: 10.1016/s0065-3527(08)60764-2 324252

6. Dovas C, Eythymiou K, Katis N. First report of Maize rough dwarf virus (MRDV) on maize crops in Greece. Plant Pathology. 2004; 53: 238.

7. Wang AL, Wang JJ, Chen CH. Study on maize rough dwarf virus incidence law and its integrated control technique. Journal of Maize Sciences. 2005; 13(4): 114–116.

8. Zhang H, Chen J, Lei J, Adams MJ. Sequence analysis shows that a dwarfing disease on rice, wheat and maize in China is caused by Rice Black-streaked Dwarf Virus. European Journal of Plant Pathology. 2001; 107(5): 563–567.

9. Yang XF, Wen GB, Yang Y. Resistance identification and analysis of different maize germplasms to maize rough dwarf virus. Journal of Maize Sciences. 2010; 18: 144–146.

10. Wang AL, Zhao DF, Chen ZH, Wang JJ, Shao XS, Wei GY. Studies on genetic basis and recurrent selection effect of inbred line maize resistance to MRDV. Journal of Maize Sciences. 2000; 8: 80–82.

11. Shang YF, Zhao J, Du S, Lu X, Wang S, Sun H, et al. Identification and investigation on resistance to virus diseases of both maize commercial varieties and germplasm at seedling stage. Shandong Agricultural Sciences. 2001; 4: 3–5.

12. Lu YG, Di DP, Miao HQ, Tian LZ. Identification and analysis on resistance of introduced foreign and domestic maize inbreds to MRDV. Journal of Hebei Agricultural Sciences. 2001; 5: 22–24.

13. Xue L, Zhang D, Xu L, Jin MM, Peng CJ, Xu CW. Mining and analyzing genetic diversity for maize rough dwarf disease resistant gerplasms and its application in maize breeding. Acta Agronomica Sinica. 2011; 37: 2123–2129.

14. Di Renzo MA, Bonamico NC, Díaz DG, Ibañez MA, Faricelli ME, Balzarini MG, et al. Microsatellite markers linked to QTL for resistance to Mal de Río Cuarto disease in Zea mays L. Journal of Agricultural Science. 2004; 142: 289–295.

15. Wang F, Zhang YS, Zhuang YL, Qin GZ, Zhang JR. Molecular mapping of three loci conferring resistance to Maize (Zea mays L.) rough dwarf disease. Molecular Plant Breeding. 2007; 5: 178–179.

16. Luan J, Wang F, Li Y, Zhang B, Zhang J. Mapping quantitative trait loci conferring resistance to rice black-streaked virus in maize (Zea mays L.). Theoretical and Applied Genetics. 2012; 125(4):781–791. doi: 10.1007/s00122-012-1871-1 22562145

17. Shi L, Hao Z, Weng J, Xie C, Liu C, Zhang D, et al. Identification of a major quantitative trait locus for resistance to maize rough dwarf virus in a Chinese maize inbred line X178 using a linkage map based on 514 gene-derived single nucleotide polymorphisms. Molecular Breeding. 2012; 30(2): 615–625. https://doi.org/10.1007/s11032-011-9652-0

18. Tao Y, Liu Q, Wang H, Zhang Y, Huang X, Wang B, et al. Identification and fine-mapping of a QTL, qMrdd1, that confers recessive resistance to maize rough dwarf disease. BMC Plant Biology. 2013; 13: 145. doi: 10.1186/1471-2229-13-145 24079304

19. Chen G, Wang X, Hao J, Yan J, Ding J. Genome-Wide Association Implicates Candidate Genes Conferring Resistance to Maize Rough Dwarf Disease in Maize. PloS ONE. 2015; 10(11): e0142001. doi: 10.1371/journal.pone.0142001 26529245

20. Li R, Song W, Wang B, Wang J, Zhang D, Zhang Q, et al. Identification of a locus conferring dominant resistance to maize rough dwarf disease in maize. Scientific Reports. 2018; 8(1): 3248. doi: 10.1038/s41598-018-21677-3 29459698

21. Shang W, Zhang Y, Wei H, Kong X, Jiang F, Liu B. SSR Linkage Map Construction and QTL Identification for Resistance Gene of MRDV in Maize. Shandong Agricultural Sciences. 2011; 12: 1–6.

22. Bonamico NC, Di Renzo MA, Ibañez MA, Borghi M, Díaz DG, Salerno J, et al. (2012). QTL analysis of resistance to Mal de Río Cuarto disease in maize using recombinant inbred lines. Journal of Agricultural Science. 2012; 150(5): 619–629.

23. Bonamico NC, Di Renzo MA, Borghi M, Ibañez MA, Díaz DG, Balzarini MG. Mapping QTL for a multivariate measure of the reaction with the Mal de Río Cuarto virus. Journal of Basic and Applied Genetics. 2013; 24: 11–21.

24. Lan J, Gong Y, Song C. Preliminary QTL Analysis on Resistance of Maize Combination QR-001/QS-001 to Rough Dwarf Disease. Shandong Agricultural Sciences. 2015; 47(2): 90–95.

25. Rossi EA, Borghi ML, Di Renzo MA, Bonamico NC. Quantitative Trait loci (QTL) Identification for Resistance to Mal de Rio Cuarto Virus (MRCV) in Maize Based on Segregate Population. The Open Agriculture Journal. 2015; 9: 48–55.

26. Liu C, Weng J, Zhang D, Zhang X, Yang X, Shi L, et al. Genome-wide association study of resistance to rough dwarf disease in maize. European Journal of Plant Pathology. 2014; 139(1): 205–216. https://doi.org/10.1007/s10658-014-0383-z

27. Hao D, Cheng Y, Chen G, Lu H, Shi M, Zhang Z, et al. Identification of significant single nucleotide polymorphisms for resistance to maize rough dwarf disease in elite maize (Zea mays L.) inbred lines. Euphytica. 2015; 203: 109–120.

28. Di DP, Miao HQ, Lu YG, Tian LZ (2005) Study on the method of inoculation and identification for the resistance of maize to maize rough dwarf virus. Journal of Agricultural University of Hebei. 2005; 28: 76–78.

29. Miao HQ, Tian LZ, Lu YG, Di DP, Chen XP. One simple grading standard for maize rough dwarf virus, Plant Protection. 2005; 31(6): 87–89.

30. Grau CR, Radke VL, Gillespie FL. Resistance of soybean cultivars to Sclerotinia sclerotiorum. Plant Diseases. 1982; 66: 506–508. https://doi.org/10.1094/PD-66-506

31. Murray MG, Thompson WF. Rapid isolation of high molecular weight plant DNA. Nucleic Acids Research. 1980; 8(19): 4321–4325. doi: 10.1093/nar/8.19.4321 7433111

32. Lei M, Li HH, Zhang LY, Wang JK. QTL IciMapping: Integrated software for genetic linkage map construction and quantitative trait locus mapping in biparental populations. The Crop Journal. 2015; 3(3): 269–283.

33. Wang SB, Wen YJ, Ren WL, Ni YL, Zhang J, Feng JY, et al. Mapping small-effect and linked quantitative trait loci for complex traits in backcross or DH populations via a multi-locus GWAS methodology. Scientific Reports. 2016, 6: 29951. doi: 10.1038/srep29951 27435756

34. Zhang YW, Wen YJ, Dunwell JM, Zhang YM. QTL.gCIMapping.GUI v2.0: An R software for detecting small-effect and linked QTLs for quantitative traits in bi-parental segregation populations. Computational and Structural Biotechnology Journal. in press.

35. Li H, Bradbury P, Ersoz E, Buckler ES, Wang J. Joint QTL linkage mapping for multiple-cross mating design sharing one common parent. PloS ONE. 2011; 6(3): e17573. doi: 10.1371/journal.pone.0017573 21423655

36. Li S, Wang J, Zhang L. Inclusive Composite Interval Mapping of QTL by Environment Interactions in Biparental Populations. PloS ONE. 2015; 10(7): e0132414. doi: 10.1371/journal.pone.0132414 26161656

37. Livak KJ, Schmittgen TD. Analysis of relative gene expressiondata using real-time quantitative PCR and the 2−ΔΔCTmethod. Methods. 2001; 25(4): 402–408. doi: 10.1006/meth.2001.1262 11846609

38. Wang X, Wang Y, Yang Q, Liu J, Wang X, Hao J. Screening and genetic diversity analysis of maize germplasm resources that resistant to maize rough dwarf virus. Molecular Plant Breeding. 2017; 15(12): 5172–5177.

39. Liu C, Hua J, Liu C, Zhang D, Hao Z, Yong H, et al. Fine mapping of a quantitative trait locus conferring resistance to maize rough dwarf disease. Theoretical and Applied Genetics. 2016; 129(12): 2333–2242. doi: 10.1007/s00122-016-2770-7 27544523

40. Wang SB, Feng JY, Ren WL, Huang B, Zhou L, Wen YJ, et al. Improving power and accuracy of genome-wide association studies via a multi-locus mixed linear model methodology. Scientific Reports. 2016; 6: 19444. doi: 10.1038/srep19444 26787347

41. Zhou Y, Xu Z, Duan C, Chen Y, Meng Q, Wu J, et al. Dual transcriptome analysis reveals insights into the response to Rice black-streaked dwarf virus in maize. Journal of Experimental Botany. 2016; 67(15): 4593–4609. doi: 10.1093/jxb/erw244 27493226

42. EI-Soda M, Malosetti M, Zwaan BJ, Koornneef M, Aarts MG. Genotype × environment interaction QTL mapping in plants: lessons from Arabidopsis. Trends in Plant Science. 2014; 19(6): 390–398. doi: 10.1016/j.tplants.2014.01.001 24491827

43. Messmer R, Fracheboud Y, Bänziger M, Vargas M, Stamp P, Ribaut JM. Drought stress and tropical maize: QTL-by-environment interactions and stability of QTLs across environments for yield components and secondary traits. Theoretical and Applied Genetics. 2009; 119(5): 913–930. doi: 10.1007/s00122-009-1099-x 19597726

44. Li P, Zhang Y, Yin S, Zhu P, Pan T, Xu Y, et al. QTL-By-Environment Interaction in the Response of Maize Root and Shoot Traits to Different Water Regimes. Frontiers in Plant Science. 2018; 9: 229. doi: 10.3389/fpls.2018.00229 29527220

45. Oh IS, Park AR, Bae MS, Kwon SJ, Kim YS, Lee JE, et al. Secretome analysis reveals an Arabidopsis lipase involved in defense against Alternaria brassicicola. The Plant Cell. 2005; 17(10): 2832–2847. doi: 10.1105/tpc.105.034819 16126835

46. Bittner-Eddy PD, Beynon JL. The Arabidopsis downy mildew resistance gene, RPP13-Nd, functions independently of NDR1 and EDS1 and does not require the accumulation of salicylic acid. Molecular Plant-Microbe Interactions. 2001; 14(3): 416–421. doi: 10.1094/MPMI.2001.14.3.416 11277440


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