Your search keyword '"Xu, Mingliang"' showing total 21 results

1. Natural variations of maize ZmLecRK1 determine its interaction with ZmBAK1 and resistance patterns to multiple pathogens.

Author

Li Z, Chen J, Liu C, He S, Wang M, Wang L, Bhadauria V, Wang S, Cheng W, Liu H, Yang X, Xu M, Peng YL, and Zhu W

Subjects

Gene Expression Regulation, Plant, Pythium pathogenicity, Genetic Variation, Zea mays genetics, Zea mays microbiology, Zea mays metabolism, Disease Resistance genetics, Plant Diseases microbiology, Plant Proteins genetics, Plant Proteins metabolism

Abstract

Maize (Zea mays) is one of the most important crops in the world, but its yield and quality are seriously affected by diverse diseases. Identifying broad-spectrum resistance genes is crucial for developing effective strategies to control the disease in maize. In a genome-wide study in maize, we identified a G-type lectin receptor kinase ZmLecRK1, as a new resistance protein against Pythium aphanidermatum, one of the causal pathogens of stalk rot in maize. Genetic analysis showed that the specific ZmLecRK1 allele can confer resistance to multiple pathogens in maize. The cell death and disease resistance phenotype mediated by the resistant variant of ZmLecRK1 requires the co-receptor ZmBAK1. A naturally occurring A404S variant in the extracellular domain of ZmLecRK1 determines the ZmLecRK1-ZmBAK1 interaction and the formation of ZmLecRK1-related protein complexes. Interestingly, the ZmLecRK1 susceptible variant was found to possess the amino acid S404 that is present in the ancestral variants of ZmLecRK1 and conserved among the majority of grass species, while the resistance variant of ZmLecRK1 with A404 is only present in a few maize inbred lines. Substitution of S by A at position 404 in ZmLecRK1-like proteins of sorghum and rice greatly enhances their ability to induce cell death. Further transcriptomic analysis reveals that ZmLecRK1 likely regulates gene expression related to the pathways in cell wall organization or biogenesis in response to pathogen infection. Taken together, these results suggest that the ZmLecRK1 resistance variant enhances its binding affinity to the co-receptor ZmBAK1, thereby enhancing the formation of active complexes for defense in maize. Our work highlights the biotechnological potential for generating disease-resistant crops by precisely modulating the activity of ZmLecRK1 and its homologs through targeted base editing., (Copyright © 2024 The Author. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Quantitative disease resistance: Multifaceted players in plant defense.

Author

Gou M, Balint-Kurti P, Xu M, and Yang Q

Subjects

Plant Breeding, Crops, Agricultural genetics, Genes, Plant, Plant Diseases genetics, Disease Resistance genetics, Epigenesis, Genetic

Abstract

In contrast to large-effect qualitative disease resistance, quantitative disease resistance (QDR) exhibits partial and generally durable resistance and has been extensively utilized in crop breeding. The molecular mechanisms underlying QDR remain largely unknown but considerable progress has been made in this area in recent years. In this review, we summarize the genes that have been associated with plant QDR and their biological functions. Many QDR genes belong to the canonical resistance gene categories with predicted functions in pathogen perception, signal transduction, phytohormone homeostasis, metabolite transport and biosynthesis, and epigenetic regulation. However, other "atypical" QDR genes are predicted to be involved in processes that are not commonly associated with disease resistance, such as vesicle trafficking, molecular chaperones, and others. This diversity of function for QDR genes contrasts with qualitative resistance, which is often based on the actions of nucleotide-binding leucine-rich repeat (NLR) resistance proteins. An understanding of the diversity of QDR mechanisms and of which mechanisms are effective against which classes of pathogens will enable the more effective deployment of QDR to produce more durably resistant, resilient crops., (© 2022 The Authors. Journal of Integrative Plant Biology published by John Wiley & Sons Australia, Ltd on behalf of Institute of Botany, Chinese Academy of Sciences.)

Published

2023

3. qMrdd2, a novel quantitative resistance locus for maize rough dwarf disease.

Author

Zhang W, Deng S, Zhao Y, Xu W, Liu Q, Zhang Y, Ren C, Cheng Z, Xu M, and Liu B

Subjects

Analysis of Variance, Genetic Linkage, Inbreeding, Models, Genetic, Phenotype, Physical Chromosome Mapping, Disease Resistance genetics, Plant Diseases genetics, Plant Diseases virology, Quantitative Trait Loci genetics, Zea mays genetics, Zea mays virology

Abstract

Background: Maize rough dwarf disease (MRDD), a widespread disease caused by four pathogenic viruses, severely reduces maize yield and grain quality. Resistance against MRDD is a complex trait that controlled by many quantitative trait loci (QTL) and easily influenced by environmental conditions. So far, many studies have reported numbers of resistant QTL, however, only one QTL have been cloned, so it is especially important to map and clone more genes that confer resistance to MRDD., Results: In the study, a major quantitative trait locus (QTL) qMrdd2, which confers resistance to MRDD, was identified and fine mapped. qMrdd2, located on chromosome 2, was consistently identified in a 15-Mb interval between the simple sequence repeat (SSR) markers D184 and D1600 by using a recombinant inbred line (RIL) population derived from a cross between resistant ("80007") and susceptible ("80044") inbred lines. Using a recombinant-derived progeny test strategy, qMrdd2 was delineated to an interval of 577 kb flanked by markers N31 and N42. We further demonstrated that qMrdd2 is an incompletely dominant resistance locus for MRDD that reduced the disease severity index by 20.4%., Conclusions: A major resistance QTL (qMrdd2) have been identified and successfully refined into 577 kb region. This locus will be valuable for improving maize variety resistance to MRDD via marker-assisted selection (MAS).

Published

2021

4. A helitron-induced RabGDIα variant causes quantitative recessive resistance to maize rough dwarf disease.

Author

Liu Q, Deng S, Liu B, Tao Y, Ai H, Liu J, Zhang Y, Zhao Y, and Xu M

Subjects

Alleles, Gene Expression Regulation, Plant, Genes, Plant, Guanine Nucleotide Dissociation Inhibitors genetics, Models, Biological, Physical Chromosome Mapping, Plant Diseases genetics, Plant Proteins genetics, Plants, Genetically Modified, Protein Binding, Quantitative Trait Loci genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Reproducibility of Results, Viral Proteins metabolism, Zea mays genetics, Zea mays ultrastructure, Disease Resistance genetics, Guanine Nucleotide Dissociation Inhibitors metabolism, Plant Diseases virology, Plant Proteins metabolism, Plant Viruses physiology, Zea mays virology

Abstract

Maize rough dwarf disease (MRDD), caused by various species of the genus Fijivirus, threatens maize production worldwide. We previously identified a quantitative locus qMrdd1 conferring recessive resistance to one causal species, rice black-streaked dwarf virus (RBSDV). Here, we show that Rab GDP dissociation inhibitor alpha (RabGDIα) is the host susceptibility factor for RBSDV. The viral P7-1 protein binds tightly to the exon-10 and C-terminal regions of RabGDIα to recruit it for viral infection. Insertion of a helitron transposon into RabGDIα intron 10 creates alternative splicing to replace the wild-type exon 10 with a helitron-derived exon 10. The resultant splicing variant RabGDIα-hel has difficulty being recruited by P7-1, thus leading to quantitative recessive resistance to MRDD. All naturally occurring resistance alleles may have arisen from a recent single helitron insertion event. These resistance alleles are valuable to improve maize resistance to MRDD and potentially to engineer RBSDV resistance in other crops.

Published

2020

5. The Auxin-Regulated Protein ZmAuxRP1 Coordinates the Balance between Root Growth and Stalk Rot Disease Resistance in Maize.

Author

Ye J, Zhong T, Zhang D, Ma C, Wang L, Yao L, Zhang Q, Zhu M, and Xu M

Subjects

Fusarium physiology, Gibberella physiology, Plant Diseases genetics, Plant Diseases microbiology, Plant Growth Regulators immunology, Plant Proteins genetics, Plant Roots immunology, Plant Stems genetics, Plant Stems immunology, Zea mays genetics, Zea mays microbiology, Disease Resistance, Indoleacetic Acids immunology, Plant Diseases immunology, Plant Proteins immunology, Plant Roots growth & development, Plant Stems microbiology, Zea mays immunology

Abstract

To optimize fitness, plants must efficiently allocate their resources between growth and defense. Although phytohormone crosstalk has emerged as a major player in balancing growth and defense, the genetic basis by which plants manage this balance remains elusive. We previously identified a quantitative disease-resistance locus, qRfg2, in maize (Zea mays) that protects against the fungal disease Gibberella stalk rot. Here, through map-based cloning, we demonstrate that the causal gene at qRfg2 is ZmAuxRP1, which encodes a plastid stroma-localized auxin-regulated protein. ZmAuxRP1 responded quickly to pathogen challenge with a rapid yet transient reduction in expression that led to arrested root growth but enhanced resistance to Gibberella stalk rot and Fusarium ear rot. ZmAuxRP1 was shown to promote the biosynthesis of indole-3-acetic acid (IAA), while suppressing the formation of benzoxazinoid defense compounds. ZmAuxRP1 presumably acts as a resource regulator modulating indole-3-glycerol phosphate and/or indole flux at the branch point between the IAA and benzoxazinoid biosynthetic pathways. The concerted interplay between IAA and benzoxazinoids can regulate the growth-defense balance in a timely and efficient manner to optimize plant fitness., (Copyright © 2018 The Author. Published by Elsevier Inc. All rights reserved.)

Published

2019

6. Auxin Binding Protein 1 Reinforces Resistance to Sugarcane Mosaic Virus in Maize.

Author

Leng P, Ji Q, Asp T, Frei UK, Ingvardsen CR, Xing Y, Studer B, Redinbaugh M, Jones M, Gajjar P, Liu S, Li F, Pan G, Xu M, and Lübberstedt T

Subjects

Gene Deletion, Genetic Complementation Test, Plant Proteins genetics, Plants, Genetically Modified, Receptors, Cell Surface genetics, Ribulose-Bisphosphate Carboxylase metabolism, Two-Hybrid System Techniques, Zea mays genetics, Zea mays physiology, Disease Resistance genetics, Plant Proteins metabolism, Potyvirus physiology, Receptors, Cell Surface metabolism, Zea mays virology

Published

2017

7. A transposon-directed epigenetic change in ZmCCT underlies quantitative resistance to Gibberella stalk rot in maize.

Author

Wang C, Yang Q, Wang W, Li Y, Guo Y, Zhang D, Ma X, Song W, Zhao J, and Xu M

Subjects

Alleles, DNA Methylation genetics, Gene Expression Regulation, Plant, Histones metabolism, Photoperiod, Physical Chromosome Mapping, Plant Proteins metabolism, Plants, Genetically Modified, Promoter Regions, Genetic genetics, Quantitative Trait Loci genetics, Seedlings genetics, DNA Transposable Elements genetics, Disease Resistance genetics, Epigenesis, Genetic, Gibberella physiology, Plant Diseases genetics, Plant Diseases microbiology, Plant Proteins genetics, Zea mays genetics, Zea mays microbiology

Abstract

A major resistance quantitative trait locus, qRfg1, significantly enhances maize resistance to Gibberella stalk rot, a devastating disease caused by Fusarium graminearum. However, the underlying molecular mechanism remains unknown. We adopted a map-based cloning approach to identify the resistance gene at qRfg1 and examined the dynamic epigenetic changes during qRfg1-mediated maize resistance to the disease. A CCT domain-containing gene, ZmCCT, is the causal gene at the qRfg1 locus and a polymorphic CACTA-like transposable element (TE1) c. 2.4 kb upstream of ZmCCT is the genetic determinant of allelic variation. The non-TE1 ZmCCT allele is in a poised state, with predictive bivalent chromatin enriched for both repressive (H3K27me3/H3K9me3) and active (H3K4me3) histone marks. Upon pathogen challenge, this non-TE1 ZmCCT allele was promptly induced by a rapid yet transient reduction in H3K27me3/H3K9me3 and a progressive decrease in H3K4me3, leading to disease resistance. However, TE1 insertion in ZmCCT caused selective depletion of H3K4me3 and enrichment of methylated GC to suppress the pathogen-induced ZmCCT expression, resulting in disease susceptibility. Moreover, ZmCCT-mediated resistance to Gibberella stalk rot is not affected by photoperiod sensitivity. This chromatin-based regulatory mechanism enables ZmCCT to be more precise and timely in defense against F. graminearum infection., (© 2017 The Authors. New Phytologist © 2017 New Phytologist Trust.)

Published

2017

8. qRfg3, a novel quantitative resistance locus against Gibberella stalk rot in maize.

Author

Ma C, Ma X, Yao L, Liu Y, Du F, Yang X, and Xu M

Subjects

Chromosome Mapping, Crosses, Genetic, Genetic Linkage, Genetic Markers, Genotype, Phenotype, Plant Diseases microbiology, Zea mays microbiology, Disease Resistance genetics, Gibberella, Plant Diseases genetics, Quantitative Trait Loci, Zea mays genetics

Abstract

Key Message: A quantitative trait locus  qRfg3 imparts recessive resistance to maize Gibberella stalk rot. qRfg3 has been mapped into a 350-kb interval and could reduce the disease severity index by ~26.6%. Gibberella stalk rot, caused by the fungal pathogen Fusarium graminearum, severely affects maize yield and grain quality worldwide. To identify more resistance quantitative trait loci (QTLs) against this disease, we analyzed a recombinant inbred line (RIL) population derived from a cross between resistant H127R and susceptible C7-2 inbred lines. Within this population, maize resistance to Gibberella stalk rot had high broad-sense heritability. A major QTL, qRfg3, on chromosome 3 was consistently detected across three field trials, accounting for 10.7-19.4% of the total phenotypic variation. Using a progeny-based sequential fine-mapping strategy, we narrowed qRfg3 down to an interval of ~350 kb. We further demonstrated that qRfg3 is a recessive resistance locus to Gibberella stalk rot that reduced the disease severity index by ~26.6%. Both the gene location and recessive genetic mode distinguish qRfg3 from other stalk rot resistance loci. Hence, qRfg3 is valuable as a complement to existing resistance QTLs to improve maize resistance to Gibberella stalk rot.

Published

2017

9. Cytological and Molecular Characterization of ZmWAK-Mediated Head-Smut Resistance in Maize.

Author

Zhang N, Zhang B, Zuo W, Xing Y, Konlasuk S, Tan G, Zhang Q, Ye J, and Xu M

Subjects

Apoptosis genetics, Autophagy genetics, Gene Expression Profiling methods, Gene Expression Regulation, Plant, Host-Pathogen Interactions, Hyphae physiology, Metabolomics methods, Microscopy, Electron, Plant Diseases microbiology, Plant Proteins metabolism, Protein Kinases metabolism, Ustilaginales physiology, Zea mays metabolism, Zea mays microbiology, Disease Resistance genetics, Plant Diseases genetics, Plant Proteins genetics, Protein Kinases genetics, Zea mays genetics

Abstract

Head smut, caused by the fungal pathogen Sporisorium reilianum, poses a threat to maize production worldwide. ZmWAK, a cell wall-associated receptor kinase, confers quantitative resistance to head smut disease. Here, two near-isogenic lines (NILs), susceptible line Huangzao4 and its ZmWAK-converted resistant line Huangzao4R, were used to decipher the role of ZmWAK in head smut resistance. Cytological and molecular characterization in response to S. reilianum infection was compared between two NILs. Upon S. reilianum infection, the growth of pathogen hyphae was severely arrested in the ZmWAK-converted resistant line Huangzao4R, relative to its susceptible parental line Huangzao4. Infected cells exhibited apoptosis-like features in Huangzao4R and hyphae were sequestered within dead cells, whereas pathogen invasion caused autophagy in Huangzao4, which failed to prevent hyphal spreading. Integrated transcriptomic and metabolomic analysis indicated that ZmWAK functions as a hub in the trade-off between growth and defense, whereby ZmWAK promotes cell growth in the absence of the pathogen and switches to a defense response upon S. reilianum attack. These findings shed light on an elegant regulatory mechanism governed by ZmWAK in the trade-off between growth and head smut defense.

Published

2017

10. Characterization of Sugarcane Mosaic Virus Scmv1 and Scmv2 Resistance Regions by Regional Association Analysis in Maize.

Author

Leng P, Ji Q, Tao Y, Ibrahim R, Pan G, Xu M, and Lübberstedt T

Subjects

Chromosome Mapping, Disease Resistance immunology, Genes, Plant, Genetic Markers genetics, Plant Diseases virology, Polymorphism, Single Nucleotide genetics, Sequence Tagged Sites, Zea mays virology, Disease Resistance genetics, Plant Diseases immunology, Potyvirus immunology, Zea mays genetics, Zea mays immunology

Abstract

Sugarcane Mosaic Virus (SCMV) causes one of the most severe virus diseases in maize worldwide, resulting in reduced grain and forage yield in susceptible cultivars. In this study, two association panels consisting of 94 inbred lines each, from China and the U.S., were characterized for resistance to two isolates: SCMV-Seehausen and SCMV-BJ. The population structure of both association panels was analyzed using 3072 single nucleotide polymorphism (SNP) markers. The Chinese and the U.S. panel were both subdivided into two sub-populations, the latter comprised of Stiff Stalk Synthetic (SS) lines and Non Stiff Stalk Synthetic (NSS). The relative kinships were calculated using informative 2947 SNPs with minor allele frequency ≥ 5% and missing data ≤ 20% for the Chinese panel and 2841 SNPs with the same characteristics were used for the U.S. panel. The Scmv1 region was genotyped using 7 single sequence repeat (SSR) and sequence-tagged site (STS) markers, and 12 SSR markers were used for the Scmv2 region in the U.S. panel, while 5 of them were used for the Chinese panel. For all traits, a MLM (Mix Linear Model) controlling both population structure and relative kinship (Q + K) was used for association analysis. Three markers Trx-1, STS-11, and STS-12 located in the Scmv1 region were strongly associated (P = 0.001) with SCMV resistance, and explained more than 16.0%, 10.6%, and 19.7% of phenotypic variation, respectively. 207FG003 located in the Scmv2 region was significantly associated (P = 0.001) with SCMV resistance, and explained around 18.5% of phenotypic variation.

Published

2015

11. A maize wall-associated kinase confers quantitative resistance to head smut.

Author

Zuo W, Chao Q, Zhang N, Ye J, Tan G, Li B, Xing Y, Zhang B, Liu H, Fengler KA, Zhao J, Zhao X, Chen Y, Lai J, Yan J, and Xu M

Subjects

Base Sequence, Chromosome Mapping, Cloning, Molecular, Mesophyll Cells, Molecular Sequence Data, Organ Specificity, Osmotic Pressure, Phylogeny, Plant Diseases microbiology, Plant Proteins genetics, Plant Proteins physiology, Plants, Genetically Modified, Protein Kinases physiology, Sequence Analysis, DNA, Zea mays enzymology, Zea mays immunology, Zea mays microbiology, Basidiomycota physiology, Disease Resistance genetics, Plant Diseases immunology, Protein Kinases genetics, Quantitative Trait Loci genetics, Zea mays genetics

Abstract

Head smut is a systemic disease in maize caused by the soil-borne fungus Sporisorium reilianum that poses a grave threat to maize production worldwide. A major head smut quantitative resistance locus, qHSR1, has been detected on maize chromosome bin2.09. Here we report the map-based cloning of qHSR1 and the molecular mechanism of qHSR1-mediated resistance. Sequential fine mapping and transgenic complementation demonstrated that ZmWAK is the gene within qHSR1 conferring quantitative resistance to maize head smut. ZmWAK spans the plasma membrane, potentially serving as a receptor-like kinase to perceive and transduce extracellular signals. ZmWAK was highly expressed in the mesocotyl of seedlings where it arrested biotrophic growth of the endophytic S. reilianum. Impaired expression in the mesocotyl compromised ZmWAK-mediated resistance. Deletion of the ZmWAK locus appears to have occurred after domestication and spread among maize germplasm, and the ZmWAK kinase domain underwent functional constraints during maize evolution.

Published

2015

12. High-resolution mapping and characterization of qRgls2, a major quantitative trait locus involved in maize resistance to gray leaf spot.

Author

Xu L, Zhang Y, Shao S, Chen W, Tan J, Zhu M, Zhong T, Fan X, and Xu M

Subjects

Plant Diseases genetics, Plant Diseases microbiology, Ascomycota physiology, Disease Resistance genetics, Plant Leaves genetics, Plant Leaves microbiology, Quantitative Trait Loci genetics, Zea mays genetics, Zea mays microbiology

Abstract

Background: Gray leaf spot (GLS) caused by Cercospora zeae-maydis (Czm) or Cercospora zeina (Cz) is a devastating maize disease and results in substantial yield reductions worldwide. GLS resistance is a quantitatively inherited trait. The development and cultivation of GLS-resistant maize hybrids are the most cost-effective and efficient ways to control this disease., Results: We previously detected a major GLS resistance QTL, qRgls2, in bin 5.03-04, which spans the whole centromere of chromosome 5 encompassing a physical distance of ~110-Mb. With advanced backcross populations derived from the cross between the resistant Y32 and susceptible Q11 inbred lines, a sequential recombinant-derived progeny testing strategy was adapted to fine map qRgls2. We narrowed the region of qRgls2 from an initial ~110-Mb to an interval of ~1-Mb, flanked by the markers G346 and DD11. qRgls2 showed predominantly additive genetic effects and significantly increased the resistance percentage by 20.6 to 24.6% across multiple generations. A total of 15 genes were predicted in the mapped region according to the 5b.60 annotation of the maize B73 genome v2. Two pieces of the mapped qRgls2 region shared collinearity with two distant segments on maize chromosome 4., Conclusions: qRgls2, a major QTL involved in GLS resistance, was mapped to a ~1-Mb region close to the centromere of chromosome 5. There are 15 predicted genes in the mapped region. It is assumed that qRgls2 could be widely used to improve maize resistance to GLS.

Published

2014

13. Cytological and molecular characterization of quantitative trait locus qRfg1, which confers resistance to gibberella stalk rot in maize.

Author

Ye J, Guo Y, Zhang D, Zhang N, Wang C, and Xu M

Subjects

Alleles, Biomass, Chromosome Mapping, Chromosomes, Plant genetics, Cluster Analysis, Colony Count, Microbial, Fusarium genetics, Fusarium growth & development, Fusarium ultrastructure, Genes, Reporter, Hydroxybenzoates, Hyphae, Lignin metabolism, Mitochondria ultrastructure, Phenotype, Plant Diseases microbiology, Plant Roots genetics, Plant Roots immunology, Plant Roots microbiology, Plant Roots ultrastructure, Sequence Analysis, RNA, Transcriptome, Zea mays immunology, Zea mays microbiology, Disease Resistance, Fusarium pathogenicity, Plant Diseases immunology, Quantitative Trait Loci, Zea mays genetics, Zea mays ultrastructure

Abstract

Tremendous progress has been made recently in understanding plant response to Fusarium graminearum infection. Here, the cytological aspect and molecular mechanism of maize defense to F. graminearum infection were characterized using a pair of near-isogenic lines (NIL), the resistant and the susceptible NIL. F. graminearum primarily penetrated the maize root tip and no penetration structure was found. The fungal biomass within the root correlated well with root-disease severity. Following inoculation, R-NIL and S-NIL plants significantly differed in percentage of diseased primary roots. In R-NIL roots, a fraction of exodermal cells collapsed to form cavities, and hyphae were confined to the outer exodermal cells. However, most exodermal cells shrank and turned brown, and fungi colonized the entire S-NIL root. In the R-NIL roots, the exodermal cells exhibited plasmolysis and atropous hyphal growth whereas, in the exodermal cells of the S-NIL roots, severe cellular degradation and membrane-coated, lushly grown hyphae were found. Transcriptome sequencing revealed comprehensive transcription reprogramming, reinforcement of a complex defense network, to enhance the systemic and basal resistance. This study reports a detailed microscopic analysis of F. graminearum infection on maize root, and provides insights into the molecular mechanisms underlying maize resistance to the pathogen.

Published

2013

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

Author

Tao Y, Jiang L, Liu Q, Zhang Y, Zhang R, Ingvardsen CR, Frei UK, Wang B, Lai J, Lübberstedt T, and Xu M

Subjects

Crosses, Genetic, Genes, Plant genetics, Genetic Linkage, Genetic Markers, Genetics, Population, Inbreeding, Linkage Disequilibrium genetics, Microsatellite Repeats genetics, Physical Chromosome Mapping, Plant Diseases genetics, Plant Diseases virology, Reproducibility of Results, Saccharum virology, Chromosome Mapping methods, Disease Resistance genetics, Genetic Association Studies, Genetic Loci genetics, Mosaic Viruses physiology, Zea mays genetics, Zea mays virology

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

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

Author

Tao Y, Liu Q, Wang H, Zhang Y, Huang X, Wang B, Lai J, Ye J, Liu B, and Xu M

Subjects

Plant Diseases genetics, Plant Diseases virology, Plant Proteins genetics, Plant Proteins metabolism, Disease Resistance genetics, Quantitative Trait Loci genetics, Zea mays genetics, Zea mays virology

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.

Published

2013

16. The genetic and molecular basis of plant resistance to pathogens.

Author

Zhang Y, Lubberstedt T, and Xu M

Subjects

Immunity, Innate genetics, Disease Resistance genetics, Disease Resistance immunology, Host-Pathogen Interactions genetics, Plant Diseases genetics, Plant Diseases immunology, Plants genetics, Plants immunology

Abstract

Plant pathogens have evolved numerous strategies to obtain nutritive materials from their host, and plants in turn have evolved the preformed physical and chemical barriers as well as sophisticated two-tiered immune system to combat pathogen attacks. Genetically, plant resistance to pathogens can be divided into qualitative and quantitative disease resistance, conditioned by major gene(s) and multiple genes with minor effects, respectively. Qualitative disease resistance has been mostly detected in plant defense against biotrophic pathogens, whereas quantitative disease resistance is involved in defense response to all plant pathogens, from biotrophs, hemibiotrophs to necrotrophs. Plant resistance is achieved through interception of pathogen-derived effectors and elicitation of defense response. In recent years, great progress has been made related to the molecular basis underlying host-pathogen interactions. In this review, we would like to provide an update on genetic and molecular aspects of plant resistance to pathogens., (Copyright © 2013. Published by Elsevier Ltd.)

Published

2013

17. QTL mapping of resistance to gray leaf spot in maize.

Author

Zhang Y, Xu L, Fan X, Tan J, Chen W, and Xu M

Subjects

Analysis of Variance, Chromosomes, Plant genetics, Crosses, Genetic, Genetic Linkage, Genetic Markers, Inheritance Patterns genetics, Phenotype, Physical Chromosome Mapping, Plant Diseases genetics, Plant Diseases microbiology, Plant Leaves genetics, Plant Leaves immunology, Plant Leaves microbiology, Recombination, Genetic genetics, Reproducibility of Results, Zea mays immunology, Ascomycota physiology, Chromosome Mapping methods, Disease Resistance genetics, Plant Diseases immunology, Quantitative Trait Loci genetics, Zea mays genetics, Zea mays microbiology

Abstract

Gray leaf spot (GLS), caused by the causal fungal pathogen Cercospora zeae-maydis, is one of the most serious foliar diseases of maize worldwide. In the current study, a highly resistant inbred line Y32 and a susceptible line Q11 were used to produce segregating populations for both genetic analysis and QTL mapping. The broad-sense heritability (H (2)) for GLS resistance was estimated to be as high as 0.85, indicating that genetic factors played key roles in phenotypic variation. In initial QTL analysis, four QTL, located on chromosomes 1, 2, 5, and 8, were detected to confer GLS resistance. Each QTL could explain 2.53-23.90 % of the total phenotypic variation, predominantly due to additive genetic effects. Two major QTL, qRgls1 and qRgls2 on chromosomes 8 and 5, were consistently detected across different locations and replicates. Compared to the previous results, qRgls2 is located in a 'hotspot' for GLS resistance; while, qRgls1 does not overlap with any other known resistance QTL. Furthermore, the major QTL-qRgls1 was fine-mapped into an interval of 1.4 Mb, flanked by the markers GZ204 and IDP5. The QTL-qRgls1 could enhance the resistance percentages by 19.70-61.28 %, suggesting its usefulness to improve maize resistance to GLS.

Published

2012

18. Fine-mapping of qRfg2, a QTL for resistance to Gibberella stalk rot in maize.

Author

Zhang D, Liu Y, Guo Y, Yang Q, Ye J, Chen S, and Xu M

Subjects

Chromosome Mapping, DNA Primers genetics, Genetic Markers genetics, Genotype, Zea mays microbiology, Breeding methods, Disease Resistance genetics, Gibberella, Phenotype, Plant Diseases microbiology, Quantitative Trait Loci genetics, Zea mays genetics

Abstract

Stalk rot is one of the most devastating diseases in maize worldwide. In our previous study, two QTLs, a major qRfg1 and a minor qRfg2, were identified in the resistant inbred line '1145' to confer resistance to Gibberella stalk rot. In the present study, we report on fine-mapping of the minor qRfg2 that is located on chromosome 1 and account for ~8.9% of the total phenotypic variation. A total of 22 markers were developed in the qRfg2 region to resolve recombinants. The progeny-test mapping strategy was developed to accurately determine the phenotypes of all recombinants for fine-mapping of the qRfg2 locus. This fine-mapping process was performed from BC(4)F(1) to BC(8)F(1) generations to narrow down the qRfg2 locus into ~300 kb, flanked by the markers SSRZ319 and CAPSZ459. A predicted gene in the mapped region, coding for an auxin-regulated protein, is believed to be a candidate for qRfg2. The qRfg2 locus could steadily increase the resistance percentage by ~12% across different backcross generations, suggesting its usefulness in enhancing maize resistance against Gibberella stalk rot.

Published

2012

19. Genetic dissection of maize disease resistance and its applications in molecular breeding

Author

Zhu, Mang, Tong, Lixiu, Xu, Mingliang, and Zhong, Tao

Published

2021

20. ZmWAK, a quantitative resistance gene to head smut in maize, improves yield performance by reducing the endophytic pathogen Sporisorium reiliana

Author

Konlasuk, Suvimon, Xing, Yuexian, Zhang, Nan, Zuo, Weiliang, Zhang, Boqi, Tan, Guoqing, and Xu, Mingliang

Published

2015

21. Transcriptome analysis of maize resistance to Fusarium graminearum

Author

Liu, Yongjie, Guo, Yanling, Ma, Chuanyu, Zhang, Dongfeng, Wang, Chao, Yang, Qin, and Xu, Mingliang

Subjects

0106 biological sciences, 0301 basic medicine, Auxin signaling pathway, Plant disease resistance, Quantitative trait locus, Genes, Plant, 01 natural sciences, Zea mays, Transcriptome, 03 medical and health sciences, Fusarium, Botany, Gene expression, Genetics, Gibberella stalk rot, Gene, Disease Resistance, Plant Diseases, Polar auxin transport, biology, Sequence Analysis, RNA, Gene Expression Profiling, Constitutive resistance, Tryptophan, food and beverages, biology.organism_classification, RNAseq, Phenotype, 030104 developmental biology, Stalk, Gibberella, Erratum, 010606 plant biology & botany, Research Article, Biotechnology

Abstract

Background Gibberella stalk rot caused by Fusarium graminearum is one of the most destructive soil-borne diseases of maize (Zea mays L.). Chemical means of controlling Gibberella stalk rot are not very effective; development of highly resistant hybrids is the best choice for disease control. Hence, understanding of the molecular basis underlying maize resistance against Gibberella stalk rot would undoubtedly facilitate the resistance breeding for stalk rot. Results Two quantitative trait loci (QTL), qRfg1 and qRfg2, conferring resistance to Gibberella stalk rot were detected in our previous study. Three near-isogenic lines (NILs) of maize with either qRfg1 (NIL1) or qRfg2 (NIL2), or neither (NIL3) were generated and subjected to RNA sequencing to study the transcriptional changes after F. graminearum inoculation at 0 (control), 6, and 18 h post-inoculation (hpi). In total, 536,184,652 clean reads were generated, and gene expression levels were calculated using FPKM (fragments per kilobase of exon model per million mapped reads). A total of 7252 differentially expressed genes (DEGs) were found in the three NILs after F. graminearum inoculation. As many as 2499 DEGs were detected between NIL1 and NIL3 at 0 hpi, of which 884 DEGs were more abundant in NIL1 and enriched in defense responses. After F. graminearum inoculation, 1070 and 751 genes were exclusively up- and downregulated, respectively, in NIL1 as compared to NIL3. The 1070 upregulated DEGs were enriched in growth/development, photosynthesis/biogenesis, and defense-related responses. Genes encoding putative auxin-induced proteins and GH3 family proteins in auxin signaling pathway were highly induced and lasted longer in NIL3. Genes involved in polar auxin transport (PAT) were more abundant in NIL3 as compared with NIL2. Conclusions The qRfg1 confers its resistance to Gibberella stalk rot through both constitutive and induced high expression of defense-related genes; while qRfg2 enhances maize resistance to the disease via relatively lower induction of auxin signaling and repression of PAT. The defense-related transcriptional changes underlying each QTL will undoubtedly facilitate our understanding of the resistance mechanism and resistance breeding for maize stalk rot. Electronic supplementary material The online version of this article (doi:10.1186/s12864-016-2780-5) contains supplementary material, which is available to authorized users.