Your search keyword '"Baobao Wang"' showing total 13 results

1. Identification of a Fusarium ear rot resistance gene in maize by QTL mapping and RNA sequencing

Author

Yusheng Xia, Baobao Wang, Lihong Zhu, Wenqi Wu, Suli Sun, Zhendong Zhu, Xinhai Li, Jianfeng Weng, and Canxing Duan

Subjects

maize, ear rot, Fusarium verticillioides, resistance gene, QTL mapping, RNA sequencing, Plant culture, SB1-1110

Abstract

Fusarium ear rot (FER) caused by Fusarium verticillioides is a prevalent maize disease. To comprehensively characterize the genetic basis of the natural variation in FER resistance, a recombinant inbred line (RIL) population was used to map quantitative trait loci (QTL) for FER resistance. A total of 17 QTL were identified by linkage mapping in eight environments. These QTL were located on six chromosomes and explained 3.88–15.62% of the total phenotypic variation. Moreover, qFER1.03 had the strongest effect and accounted for 4.98–15.62% of the phenotypic variation according to analyses of multiple environments involving best linear unbiased predictions. The chromosome segment substitution lines (CSSLs) derived from a cross between Qi319 (donor parent) and Ye478 (recurrent parent) were used to verify the contribution of qFER1.03 to FER resistance. The line CL171, which harbored an introgressed qFER1.03, was significantly resistant to FER. Further fine mapping of qFER1.03 revealed that the resistance QTL was linked to insertion/deletion markers InDel 8 and InDel 2, with physical distances of 43.55 Mb and 43.76 Mb, respectively. Additionally, qFER1.03 differed from the previous resistance QTL on chromosome 1. There were three annotated genes in this region. On the basis of the RNA-seq data, which revealed the genes differentially expressed between the FER-resistant Qi319 and susceptible Ye478, GRMZM2G017792 (MPK3) was preliminarily identified as a candidate gene in the qFER1.03 region. The Pr-CMV-VIGS system was used to decrease the GRMZM2G017792 expression level in CL171 by 34–57%, which led to a significant decrease in FER resistance. Using RIL and CSSL populations combined with RNA-seq and Pr-CMV-VIGS, the candidate gene can be dissected effectively, which provided important gene resource for breeding FER-resistant varieties.

Published

2022

2. QTL Analysis Reveals Conserved and Differential Genetic Regulation of Maize Lateral Angles above the Ear

Author

Yanbin Zhu, Bo Song, Yanling Guo, Baobao Wang, Changcheng Xu, Hongyu Zhu, Lizhu E, Jinsheng Lai, Weibin Song, and Haiming Zhao

Subjects

maize, leaf angle (LA), tassel branch angle (TBA), quantitative trait locus (QTL), Botany, QK1-989

Abstract

Improving the density tolerance and planting density has great importance for increasing maize production. The key to promoting high density planting is breeding maize with a compact canopy architecture, which is mainly influenced by the angles of the leaves and tassel branches above the ear. It is still unclear whether the leaf angles of different stem nodes and tassel branches are controlled by similar genetic regulatory mechanisms, which limits the ability to breed for density-tolerant maize. Here, we developed a population with 571 double haploid lines derived from inbred lines, PHBA6 and Chang7-2, showing significant differences in canopy architecture. Phenotypic and QTL analyses revealed that the genetic regulation mechanism was largely similar for closely adjacent leaves above the ears. In contrast, the regulation mechanisms specifying the angles of distant leaves and the angles of leaves vs. tassel branches are largely different. The liguless1 gene was identified as a candidate gene for QTLs co-regulating the angles of different leaves and the tassel branch, consistent with its known roles in regulating plant architecture. Our findings can be used to develop strategies for the improvement of leaf and tassel architecture through the introduction of trait-specific or pleiotropic genes, thus benefiting the breeding of maize with increased density tolerance in the future.

Published

2023

3. Identification and Fine-Mapping of a Major Maize Leaf Width QTL in a Re-sequenced Large Recombinant Inbred Lines Population

Author

Baobao Wang, Yanbin Zhu, Jinjie Zhu, Zhipeng Liu, Han Liu, Xiaomei Dong, Jinjie Guo, Wei Li, Jing Chen, Chi Gao, Xinmei Zheng, Lizhu E, Jinsheng Lai, Haiming Zhao, and Weibin Song

Subjects

fine-mapping, maize, leaf width, QTL, qLW4, large RIL population, Plant culture, SB1-1110

Abstract

Leaf width (LW) influences canopy architecture of population-cultured maize and can thus contribute to density breeding. In previous studies, almost all maize LW-related mutants have extreme effect on leaf development or accompanied unfavorable phenotypes. In addition, the identification of quantitative trait loci (QTLs) has been resolution-limited, with cloning and fine-mapping rarely performed. Here, we constructed a bin map for 670 recombinant inbred lines (RILs) using ∼1.2 billion 100-bp re-sequencing reads. QTL analysis of the LW trait directly narrowed the major effect QTL, qLW4, to a ∼270-kb interval. A fine-mapping population and near-isogenic lines (NILs) were quickly constructed using a key RIL harboring heterozygous genotypes across the qLW4 region. A recombinant-derived progeny testing strategy was subsequently used to further fine-map qLW4 to a 55-kb interval. Examination of NILs revealed that qLW4 has a completely dominant effect on LW, with no additional effect on leaf length. Candidate gene analysis suggested that this locus may be a novel LW controlling allele in maize. Our findings demonstrate the advantage of large-population high-density bin mapping, and suggest a strategy for efficiently fine-mapping or even cloning of QTLs. These results should also be helpful for further dissection of the genetic mechanism of LW variation, and benefit maize density breeding.

Published

2018

4. CRISPR/Cas9-mediated knockout and overexpression studies reveal a role of maize phytochrome C in regulating flowering time and plant height

Author

Guangxia Wu, Haiyang Wang, Dexin Kong, Zhao Binbin, Yongping Zhao, Hongbin Wei, Cuixia Chen, Quanquan Li, and Baobao Wang

Subjects

0106 biological sciences, 0301 basic medicine, Mutant, Circadian clock, Arabidopsis, Plant Science, maize, phytochrome C, 01 natural sciences, Zea mays, 03 medical and health sciences, Gene Expression Regulation, Plant, Phytochrome B, shade‐avoidance syndrome, CRISPR, Research Articles, biology, Phytochrome, Cas9, Arabidopsis Proteins, fungi, food and beverages, flowering time, high‐density planting, biology.organism_classification, Phenotype, Cell biology, 030104 developmental biology, Heterologous expression, CRISPR-Cas Systems, Agronomy and Crop Science, 010606 plant biology & botany, Biotechnology, Research Article

Abstract

Summary Maize is a major staple crop widely used for food, feedstocks and industrial products. Shade‐avoidance syndrome (SAS), which is triggered when plants sense competition of light from neighbouring vegetation, is detrimental for maize yield production under high‐density planting conditions. Previous studies have shown that the red and far‐red photoreceptor phytochromes are responsible for perceiving the shading signals and triggering SAS in Arabidopsis; however, their roles in maize are less clear. In this study, we examined the expression patterns of ZmPHYC1 and ZmPHYC2 and found that ZmPHYC1, but not ZmPHYC2, is highly expressed in leaves and is regulated by the circadian clock. Both ZmPHYC1 and ZmPHYC2 proteins are localized to both the nucleus and cytoplasm under light conditions and both of them can interact with themselves or with ZmPHYBs. Heterologous expression of ZmPHYCs can complement the Arabidopsis phyC‐2 mutant under constant red light conditions and confer an attenuated SAS in Arabidopsis in response to shading. Double knockout mutants of ZmPHYC1 and ZmPHYC2 created using the CRISPR/Cas9 technology display a moderate early‐flowering phenotype under long‐day conditions, whereas ZmPHYC2 overexpression plants exhibit a moderately reduced plant height and ear height. Together, these results provided new insight into the function of ZmPHYCs and guidance for breeding high‐density tolerant maize cultivars.

Published

2020

5. Identification and Fine-Mapping of a Major Maize Leaf Width QTL in a Re-sequenced Large Recombinant Inbred Lines Population

Author

Xinmei Zheng, Xiaomei Dong, Yanbin Zhu, Baobao Wang, Weibin Song, Jinjie Zhu, Han Liu, Jing Chen, Wei Li, Jinsheng Lai, Haiming Zhao, Lizhu E, Chi Gao, Jinjie Guo, and Zhipeng Liu

Subjects

0106 biological sciences, 0301 basic medicine, Progeny testing, QTL, Population, qLW4, Locus (genetics), Plant Science, lcsh:Plant culture, Quantitative trait locus, Biology, maize, 01 natural sciences, leaf width, 03 medical and health sciences, Inbred strain, Genotype, lcsh:SB1-1110, Allele, education, Original Research, Genetics, education.field_of_study, food and beverages, genotyping-by-sequencing (GBS), 030104 developmental biology, fine-mapping, Candidate Gene Analysis, large RIL population, 010606 plant biology & botany

Abstract

Leaf width (LW) influences canopy architecture of population-cultured maize and can thus contribute to density breeding. In previous studies, almost all maize LW-related mutants have extreme effect on leaf development or accompanied unfavorable phenotypes. In addition, the identification of quantitative trait loci (QTLs) has been resolution-limited, with cloning and fine-mapping rarely performed. Here, we constructed a bin map for 670 recombinant inbred lines (RILs) using ∼1.2 billion 100-bp re-sequencing reads. QTL analysis of the LW trait directly narrowed the major effect QTL, qLW4, to a ∼270-kb interval. A fine-mapping population and near-isogenic lines (NILs) were quickly constructed using a key RIL harboring heterozygous genotypes across the qLW4 region. A recombinant-derived progeny testing strategy was subsequently used to further fine-map qLW4 to a 55-kb interval. Examination of NILs revealed that qLW4 has a completely dominant effect on LW, with no additional effect on leaf length. Candidate gene analysis suggested that this locus may be a novel LW controlling allele in maize. Our findings demonstrate the advantage of large-population high-density bin mapping, and suggest a strategy for efficiently fine-mapping or even cloning of QTLs. These results should also be helpful for further dissection of the genetic mechanism of LW variation, and benefit maize density breeding.

Published

2018

6. Genetic dissection of maize seedling root system architecture traits using an ultra-high density bin-map and a recombinant inbred line population

Author

Weibin, Song, Baobao, Wang, Andrew L, Hauck, Xiaomei, Dong, Jieping, Li, and Jinsheng, Lai

Subjects

Genetic Markers, Recombination, Genetic, root system architecture, QTL, bin map, Quantitative Trait Loci, genotyping by sequencing (GBS), Plant Roots, Polymorphism, Single Nucleotide, Zea mays, Maize, Plant Breeding, Phenotype, Quantitative Trait, Heritable, Hydroponics, Seedlings, Inbreeding, Research Articles, Research Article

Abstract

Maize (Zea mays) root system architecture (RSA) mediates the key functions of plant anchorage and acquisition of nutrients and water. In this study, a set of 204 recombinant inbred lines (RILs) was derived from the widely adapted Chinese hybrid ZD958(Zheng58 × Chang7‐2), genotyped by sequencing (GBS) and evaluated as seedlings for 24 RSA related traits divided into primary, seminal and total root classes. Significant differences between the means of the parental phenotypes were detected for 18 traits, and extensive transgressive segregation in the RIL population was observed for all traits. Moderate to strong relationships among the traits were discovered. A total of 62 quantitative trait loci (QTL) were identified that individually explained from 1.6% to 11.6% (total root dry weight/total seedling shoot dry weight) of the phenotypic variation. Eighteen, 24 and 20 QTL were identified for primary, seminal and total root classes of traits, respectively. We found hotspots of 5, 3, 4 and 12 QTL in maize chromosome bins 2.06, 3.02‐03, 9.02‐04, and 9.05‐06, respectively, implicating the presence of root gene clusters or pleiotropic effects. These results characterized the phenotypic variation and genetic architecture of seedling RSA in a population derived from a successful maize hybrid.

Published

2015

7. An ultra-high density bin-map for rapid QTL mapping for tassel and ear architecture in a large F₂ maize population

Author

Zongliang, Chen, Baobao, Wang, Xiaomei, Dong, Han, Liu, Longhui, Ren, Jian, Chen, Andrew, Hauck, Weibin, Song, and Jinsheng, Lai

Subjects

Quantitative trait loci, DNA, Plant, Chromosome Mapping, Next generation sequencer, Sequence Analysis, DNA, Breeding, Zea mays, Chromosomes, Plant, Maize, Phenotype, Quantitative Trait, Heritable, Genotyping by sequencing, Inflorescence, Research Article

Abstract

Background Understanding genetic control of tassel and ear architecture in maize (Zea mays L. ssp. mays) is important due to their relationship with grain yield. High resolution QTL mapping is critical for understanding the underlying molecular basis of phenotypic variation. Advanced populations, such as recombinant inbred lines, have been broadly adopted for QTL mapping; however, construction of large advanced generation crop populations is time-consuming and costly. The rapidly declining cost of genotyping due to recent advances in next-generation sequencing technologies has generated new possibilities for QTL mapping using large early generation populations. Results A set of 708 F2 progeny derived from inbreds Chang7-2 and 787 were generated and genotyped by whole genome low-coverage genotyping-by-sequencing method (average 0.04×). A genetic map containing 6,533 bin-markers was constructed based on the parental SNPs and a sliding-window method, spanning a total genetic distance of 1,396 cM. The high quality and accuracy of this map was validated by the identification of two well-studied genes, r1, a qualitative trait locus for color of silk (chromosome 10) and ba1 for tassel branch number (chromosome 3). Three traits of tassel and ear architecture were evaluated in this population, a total of 10 QTL were detected using a permutation-based-significance threshold, seven of which overlapped with reported QTL. Three genes (GRMZM2G316366, GRMZM2G492156 and GRMZM5G805008) encoding MADS-box domain proteins and a BTB/POZ domain protein were located in the small intervals of qTBN5 and qTBN7 (~800 Kb and 1.6 Mb in length, respectively) and may be involved in patterning of tassel architecture. The small physical intervals of most QTL indicate high-resolution mapping is obtainable with this method. Conclusions We constructed an ultra-high-dentisy linkage map for the large early generation population in maize. Our study provides an efficient approach for fast detection of quantitative loci responsible for complex trait variation with high accuracy, thus helping to dissect the underlying molecular basis of phenotypic variation and accelerate improvement of crop breeding in a cost-effective fashion. Electronic supplementary material The online version of this article (doi:10.1186/1471-2164-15-433) contains supplementary material, which is available to authorized users.

Published

2014

8. Combined linkage and association mapping reveals candidates for Scmv1, a major locus involved in resistance to sugarcane mosaic virus (SCMV) in maize

Author

Yan Zhang, Ursula K. Frei, Jinsheng Lai, Qingqing Liu, Thomas Lübberstedt, Rui Zhang, Baobao Wang, Yongfu Tao, Mingliang Xu, Christina Roenn Ingvardsen, and Lu Jiang

Subjects

Genetic Markers, Candidate gene, QTL, Genetic Linkage, Population, Locus (genetics), Plant Science, Plant disease resistance, Biology, Quantitative trait locus, Genes, Plant, Zea mays, Linkage Disequilibrium, Genetic linkage, Mosaic Viruses, Inbreeding, Association mapping, education, Crosses, Genetic, Genetic Association Studies, Disease Resistance, Plant Diseases, Genetics, education.field_of_study, Fine-mapping, Chromosome Mapping, Reproducibility of Results, biology.organism_classification, Physical Chromosome Mapping, Maize, Saccharum, Genetics, Population, Sugarcane mosaic virus, Genetic Loci, SCMV, Research Article, Microsatellite Repeats

Abstract

Background Sugarcane mosaic virus (SCMV) disease causes substantial losses of grain yield and forage biomass in susceptible maize cultivars. Maize resistance to SCMV is associated with two dominant genes, Scmv1 and Scmv2, which are located on the short arm of chromosome 6 and near the centromere region of chromosome 3, respectively. We combined both linkage and association mapping to identify positional candidate genes for Scmv1. Results Scmv1 was fine-mapped in a segregating population derived from near-isogenic lines and further validated and fine-mapped using two recombinant inbred line populations. The combined results assigned the Scmv1 locus to a 59.21-kb interval, and candidate genes within this region were predicted based on the publicly available B73 sequence. None of three predicted genes that are possibly involved in the disease resistance response are similar to receptor-like resistance genes. Candidate gene–based association mapping was conducted using a panel of 94 inbred lines with variable resistance to SCMV. A presence/absence variation (PAV) in the Scmv1 region and two polymorphic sites around the Zmtrx-h gene were significantly associated with SCMV resistance. Conclusion Combined linkage and association mapping pinpoints Zmtrx-h as the most likely positional candidate gene for Scmv1. These results pave the way towards cloning of Scmv1 and facilitate marker-assisted selection for potyvirus resistance in maize.

Published

2013

9. Regulatory modules controlling early shade avoidance response in maize seedlings.

Author

Hai Wang, Guangxia Wu, Binbin Zhao, Baobao Wang, Zhihong Lang, Chunyi Zhang, and Haiyang Wang

Subjects

CORN seeds, EFFECT of shade on plants, CROP yields & the environment, PLANT growth & the environment, PHYTOCHROMES

Abstract

Background: Optimization of shade avoidance response (SAR) is crucial for enhancing crop yield in high-density planting conditions in modern agriculture, but a comprehensive study of the regulatory network of SAR is still lacking in monocot crops. Results: In this study, the genome-wide early responses in maize seedlings to the simulated shade (low red/far-red ratio) and also to far-red light treatment were transcriptionally profiled. The two processes were predominantly mediated by phytochrome B and phytochrome A, respectively. Clustering of differentially transcribed genes (DTGs) along with functional enrichment analysis identified important biological processes regulated in response to both treatments. Co-expression network analysis identified two transcription factor modules as potentially pivotal regulators of SAR and de-etiolation, respectively. A comprehensive cross-species comparison of orthologous DTG pairs between maize and Arabidopsis in SAR was also conducted, with emphasis on regulatory circuits controlling accelerated flowering and elongated growth, two physiological hallmarks of SAR. Moreover, it was found that the genome-wide distribution of DTGs in SAR and de-etiolation both biased toward the maize1 subgenome, and this was associated with differential retention of various cis-elements between the two subgenomes. Conclusions: The results provide the first transcriptional picture for the early dynamics of maize phytochrome signaling. Candidate genes with regulatory functions involved in maize shade avoidance response have been identified, offering a starting point for further functional genomics investigation of maize adaptation to heavily shaded field conditions. [ABSTRACT FROM AUTHOR]

Published

2016

10. An ultra-high density bin-map for rapid QTL mapping for tassel and ear architecture in a large F2 maize population.

Author

Zongliang Chen, Baobao Wang, Xiaomei Dong, Han Liu, Longhui Ren, Jian Chen, Hauck, Andrew, Weibin Song, and Jinsheng Lai

Subjects

*PLANT gene mapping, *CORN breeding, *PHENOTYPES, *PLANT variation, *PLANT DNA, *NUCLEOTIDE sequencing

Abstract

Background Understanding genetic control of tassel and ear architecture in maize (Zea mays L. ssp. mays) is important due to their relationship with grain yield. High resolution QTL mapping is critical for understanding the underlying molecular basis of phenotypic variation. Advanced populations, such as recombinant inbred lines, have been broadly adopted for QTL mapping; however, construction of large advanced generation crop populations is time-consuming and costly. The rapidly declining cost of genotyping due to recent advances in next-generation sequencing technologies has generated new possibilities for QTL mapping using large early generation populations. Results A set of 708 F2 progeny derived from inbreds Chang7-2 and 787 were generated and genotyped by whole genome low-coverage genotyping-by-sequencing methods (average 0.04×). A genetic map containing 6,533 bin-markers was constructed based on the parental SNPs and a sliding-window method, spanning a total genetic distance of 1,396 cM. The high quality and accuracy of this map was validated by the identification of two well-studied genes, r1, a qualitative trait locus for color of silk (chromosome 10) and ba1 for tassel branch number (chromosome 3). Three traits of tassel and ear architecture were evaluated in this population, a total of 10 QTL were detected using a permutation-based-significance threshold, seven of which overlapped with reported QTL. Three genes (GRMZM2G316366, GRMZM2G492156 and GRMZM5G805008) encoding MADS-box domain proteins and a BTB/POZ domain protein were located in the small intervals of qTBN5 and qTBN7 (∼800 Kb and 1.6 Mb in length, respectively) and may be involved in patterning of tassel architecture. The small physical intervals of most QTL indicate high-resolution mapping is obtainable with this method. Conclusions We constructed an ultra-high-dentisy linkage map for the large early generation population in maize. Our study provides an efficient approach for fast detection of quantitative loci responsible for complex trait variation with high accuracy, thus helping to dissect the underlying molecular basis of phenotypic variation and accelerate improvement of crop breeding in a cost-effective fashion. [ABSTRACT FROM AUTHOR]

Published

2014

11. Identification and fine-mapping of a QTL, qMrdd1, that confers recessive resistance to maize rough dwarf disease.

Author

Yongfu Tao, Qingcai Liu, Honghong Wang, Yanjun Zhang, Xinyi Huang, Baobao Wang, Jinsheng Lai, Jianrong Ye, Baoshen Liu, and Mingliang Xu

Subjects

GENETIC polymorphisms, LOCUS (Genetics), CELL nuclei, PLANT diseases, PATHOGENIC microorganisms

Abstract

Background: Maize rough dwarf disease (MRDD) is a devastating viral disease that results in considerable yield losses worldwide. Three major strains of virus cause MRDD, including maize rough dwarf virus in Europe, Mal de Río Cuarto virus in South America, and rice black-streaked dwarf virus in East Asia. These viral pathogens belong to the genus fijivirus in the family Reoviridae. Resistance against MRDD is a complex trait that involves a number of quantitative trait loci (QTL). The primary approach used to minimize yield losses from these viruses is to breed and deploy resistant maize hybrids. Results: Of the 50 heterogeneous inbred families (HIFs), 24 showed consistent responses to MRDD across different years and locations, in which 9 were resistant and 15 were susceptible. We performed trait-marker association analysis on the 24 HIFs and found six chromosomal regions which were putatively associated with MRDD resistance. We then conducted QTL analysis and detected a major resistance QTL, qMrdd1, on chromosome 8. By applying recombinant-derived progeny testing to self-pollinated backcrossed families, we fine-mapped the qMrdd1 locus into a 1.2-Mb region flanked by markers M103-4 and M105-3. The qMrdd1 locus acted in a recessive manner to reduce the disease-severity index (DSI) by 24.2-39.3%. The genetic effect of qMrdd1 was validated using another F6 recombinant inbred line (RIL) population in which MRDD resistance was segregating and two genotypes at the qMrdd1 locus differed significantly in DSI values. Conclusions: The qMrdd1 locus is a major resistance QTL, acting in a recessive manner to increase maize resistance to MRDD. We mapped qMrdd1 to a 1.2-Mb region, which will enable the introgression of qMrdd1-based resistance into elite maize hybrids and reduce MRDD-related crop losses. [ABSTRACT FROM AUTHOR]

Published

2013

12. Regulatory modules controlling early shade avoidance response in maize seedlings

Author

Chunyi Zhang, Hai Wang, Baobao Wang, Zhao Binbin, Haiyang Wang, Guangxia Wu, and Zhihong Lang

Subjects

0106 biological sciences, 0301 basic medicine, Light, Arabidopsis, Regulatory Sequences, Nucleic Acid, Biology, Zea mays, 01 natural sciences, 03 medical and health sciences, Phytochrome A, Shade avoidance, Gene Expression Regulation, Plant, Phytochrome B, Shade, Botany, Genetics, Cluster Analysis, Gene Regulatory Networks, Gene, Transcription factor, Phytochrome, Sequence Analysis, RNA, fungi, biology.organism_classification, Adaptation, Physiological, Maize, 030104 developmental biology, RNA, Plant, Seedlings, Adaptation, Transcriptome, Functional genomics, Genome, Plant, Transcription Factors, Research Article, Regulatory module, 010606 plant biology & botany, Biotechnology

Abstract

Background Optimization of shade avoidance response (SAR) is crucial for enhancing crop yield in high-density planting conditions in modern agriculture, but a comprehensive study of the regulatory network of SAR is still lacking in monocot crops. Results In this study, the genome-wide early responses in maize seedlings to the simulated shade (low red/far-red ratio) and also to far-red light treatment were transcriptionally profiled. The two processes were predominantly mediated by phytochrome B and phytochrome A, respectively. Clustering of differentially transcribed genes (DTGs) along with functional enrichment analysis identified important biological processes regulated in response to both treatments. Co-expression network analysis identified two transcription factor modules as potentially pivotal regulators of SAR and de-etiolation, respectively. A comprehensive cross-species comparison of orthologous DTG pairs between maize and Arabidopsis in SAR was also conducted, with emphasis on regulatory circuits controlling accelerated flowering and elongated growth, two physiological hallmarks of SAR. Moreover, it was found that the genome-wide distribution of DTGs in SAR and de-etiolation both biased toward the maize1 subgenome, and this was associated with differential retention of various cis-elements between the two subgenomes. Conclusions The results provide the first transcriptional picture for the early dynamics of maize phytochrome signaling. Candidate genes with regulatory functions involved in maize shade avoidance response have been identified, offering a starting point for further functional genomics investigation of maize adaptation to heavily shaded field conditions. Electronic supplementary material The online version of this article (doi:10.1186/s12864-016-2593-6) contains supplementary material, which is available to authorized users.

13. Identification and fine-mapping of a QTL, qMrdd1, that confers recessive resistance to maize rough dwarf disease

Author

Zhang Yanjun, Baoshen Liu, Baobao Wang, Mingliang Xu, Xinyi Huang, Jinsheng Lai, Jianrong Ye, Qingcai Liu, Yongfu Tao, and Honghong Wang

Subjects

Progeny testing, Maize rough dwarf virus, QTL, Quantitative Trait Loci, Population, Introgression, Locus (genetics), Plant Science, Biology, Plant disease resistance, Quantitative trait locus, Zea mays, MRDD, education, Disease Resistance, Plant Diseases, Plant Proteins, Hybrid, Genetics, education.field_of_study, Fine-mapping, Recombinant-derived progeny test, biology.organism_classification, Maize, Agronomy, Research Article

Abstract

Background Maize rough dwarf disease (MRDD) is a devastating viral disease that results in considerable yield losses worldwide. Three major strains of virus cause MRDD, including maize rough dwarf virus in Europe, Mal de Río Cuarto virus in South America, and rice black-streaked dwarf virus in East Asia. These viral pathogens belong to the genus fijivirus in the family Reoviridae. Resistance against MRDD is a complex trait that involves a number of quantitative trait loci (QTL). The primary approach used to minimize yield losses from these viruses is to breed and deploy resistant maize hybrids. Results Of the 50 heterogeneous inbred families (HIFs), 24 showed consistent responses to MRDD across different years and locations, in which 9 were resistant and 15 were susceptible. We performed trait-marker association analysis on the 24 HIFs and found six chromosomal regions which were putatively associated with MRDD resistance. We then conducted QTL analysis and detected a major resistance QTL, qMrdd1, on chromosome 8. By applying recombinant-derived progeny testing to self-pollinated backcrossed families, we fine-mapped the qMrdd1 locus into a 1.2-Mb region flanked by markers M103-4 and M105-3. The qMrdd1 locus acted in a recessive manner to reduce the disease-severity index (DSI) by 24.2–39.3%. The genetic effect of qMrdd1 was validated using another F6 recombinant inbred line (RIL) population in which MRDD resistance was segregating and two genotypes at the qMrdd1 locus differed significantly in DSI values. Conclusions The qMrdd1 locus is a major resistance QTL, acting in a recessive manner to increase maize resistance to MRDD. We mapped qMrdd1 to a 1.2-Mb region, which will enable the introgression of qMrdd1-based resistance into elite maize hybrids and reduce MRDD-related crop losses.