Your search keyword '"Liu, Zhaohui"' showing total 30 results

1. Association mapping of tan spot and septoria nodorum blotch resistance in cultivated emmer wheat.

Author

Lhamo D, Sun Q, Friesen TL, Karmacharya A, Li X, Fiedler JD, Faris JD, Xia G, Luo M, Gu YQ, Liu Z, and Xu SS

Subjects

Phenotype, Genotype, Quantitative Trait Loci, Genetic Markers, Genetic Association Studies, Triticum microbiology, Triticum genetics, Triticum growth & development, Plant Diseases microbiology, Plant Diseases genetics, Disease Resistance genetics, Ascomycota pathogenicity, Ascomycota physiology, Polymorphism, Single Nucleotide, Chromosome Mapping

Abstract

Key Message: A total of 65 SNPs associated with resistance to tan spot and septoria nodorum blotch were identified in a panel of 180 cultivated emmer accessions through association mapping Tan spot and septoria nodorum blotch (SNB) are foliar diseases caused by the respective fungal pathogens Pyrenophora tritici-repentis and Parastagonospora nodorum that affect global wheat production. To find new sources of resistance, we evaluated a panel of 180 cultivated emmer wheat (Triticum turgidum ssp. dicoccum) accessions for reactions to four P. tritici-repentis isolates Pti2, 86-124, 331-9 and DW5, two P. nodorum isolate, Sn4 and Sn2000, and four necrotrophic effectors (NEs) produced by the pathogens. About 8-36% of the accessions exhibited resistance to the four P. tritici-repentis isolates, with five accessions demonstrating resistance to all isolates. For SNB, 64% accessions showed resistance to Sn4, 43% to Sn2000 and 36% to both isolates, with Spain (11% accessions) as the most common origin of resistance. To understand the genetic basis of resistance, association mapping was performed using SNP (single nucleotide polymorphism) markers generated by genotype-by-sequencing and the 9 K SNP Infinium array. A total of 46 SNPs were significantly associated with tan spot and 19 SNPs with SNB resistance or susceptibility. Six trait loci on chromosome arms 1BL, 3BL, 4AL (2), 6BL and 7AL conferred resistance to two or more isolates. Known NE sensitivity genes for disease development were undetected except Snn5 for Sn2000, suggesting novel genetic factors are controlling host-pathogen interaction in cultivated emmer. The emmer accessions with the highest levels of resistance to the six pathogen isolates (e.g., CItr 14133-1, PI 94634-1 and PI 377672) could serve as donors for tan spot and SNB resistance in wheat breeding programs., (© 2024. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2024

2. Increase of Bacterial Leaf Streak in Hard Red Spring Wheat in North Dakota and Yield Loss Considerations.

Author

Friskop A, Green A, Ransom J, Liu Z, Knodel J, Hansen B, Halvorson J, and Lux L

Subjects

North Dakota, Plant Breeding, Triticum microbiology, Plant Diseases microbiology

Abstract

Bacterial leaf streak (BLS), caused by Xanthomonas translucens pv. undulosa , has increased in both prevalence and severity in the major hard red spring wheat (HRSW)-producing state North Dakota. The disease is readily observed after flag leaf emergence and can quickly lead to defoliation and severe yield loss. The objectives of this research were to document the prevalence and incidence of BLS in North Dakota and provide estimations of yield and economic losses. Trained field scouts determined the incidence and prevalence of BLS in ND on HRSW plants between Feekes growth stage (FGS) 8 and FGS 11.2 from 2015 to 2021, and data were used to determine BLS-affected hectares. Yield data in combination with BLS ratings were obtained from HRSW performance trials to estimate the impact of BLS on yield. The combination of variety identity, hectarage data, BLS-affected hectarage estimates, and yield loss estimates was used to estimate economic losses from BLS in 2019 and 2020. Our data suggest that BLS-affected hectares ranged from 747 to 141,680 between 2015 and 2021. Yield loss was observed at multiple HRSW performance trial locations, with estimated yield losses as high as 60% on susceptible varieties. The amount of BLS-affected hectares was the highest in 2019 and 2020, and direct economic losses for North Dakota HRSW producers were estimated to be as high as $4.7 and $8.0 million, respectively. These data highlight the importance of BLS in HRSW and the need to procure resources for breeding efforts and grower education on management of BLS., Competing Interests: The author(s) declare no conflict of interest.

Published

2023

3. Targeting Disease Susceptibility Genes in Wheat Through wide Hybridization with Maize Expressing Cas9 and Guide RNA.

Author

Karmacharya A, Li D, Leng Y, Shi G, Liu Z, Yang S, Du Y, Dai W, and Zhong S

Subjects

Zea mays genetics, Disease Susceptibility, RNA, CRISPR-Cas Systems genetics, Triticum genetics

Abstract

Two genes ( TaHRC and Tsn1 ) conferring susceptibility to Fusarium head blight and tan spot, Septoria nodorum blotch, and spot blotch in wheat were targeted through wide hybridization with maize expressing Cas9 and guide RNA (gRNA). For each gene, two target sites were selected and corresponding gRNA expression cassettes were synthesized and cloned into a binary vector carrying the CRISPR/Cas9-mediated genome editing machinery. The constructed binary vectors were used to transform the hybrid maize Hi-II through an Agrobacterium -mediated approach to generate T0 and T1 plants, which were used to cross with wheat variety Dayn for targeting Tsn1 or the susceptible allele ( TaHRC-S ) of TaHRC as well as with the near-isogenic line (Day- Fhb1 ) of Dayn for targeting the resistant allele ( TaHRC-R ) of TaHRC . Haploid embryos were rescued in vitro from the wide crosses to generate haploid plants. PCR amplification and sequencing indicated that 15 to 33% of the haploid plants contained the target gene with mutations at the target sites. This wheat × maize hybridization combined with genome editing approach provides a useful alternative tool, not only for targeting susceptibility genes to improve disease resistance without regulatory issues, but also for understanding gene function in wheat. [Formula: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license., Competing Interests: The author(s) declare no conflict of interest.

Published

2023

4. A global pangenome for the wheat fungal pathogen Pyrenophora tritici-repentis and prediction of effector protein structural homology.

Author

Moolhuijzen PM, See PT, Shi G, Powell HR, Cockram J, Jørgensen LN, Benslimane H, Strelkov SE, Turner J, Liu Z, and Moffat CS

Subjects

Ascomycota, Host-Pathogen Interactions genetics, Plant Diseases microbiology, Structural Homology, Protein, Mycotoxins genetics, Mycotoxins metabolism, Triticum genetics, Triticum metabolism, Triticum microbiology

Abstract

The adaptive potential of plant fungal pathogens is largely governed by the gene content of a species, consisting of core and accessory genes across the pathogen isolate repertoire. To approximate the complete gene repertoire of a globally significant crop fungal pathogen, a pan genomic analysis was undertaken for Pyrenophora tritici-repentis (Ptr), the causal agent of tan (or yellow) spot disease in wheat. In this study, 15 new Ptr genomes were sequenced, assembled and annotated, including isolates from three races not previously sequenced. Together with 11 previously published Ptr genomes, a pangenome for 26 Ptr isolates from Australia, Europe, North Africa and America, representing nearly all known races, revealed a conserved core-gene content of 57 % and presents a new Ptr resource for searching natural homologues (orthologues not acquired by horizontal transfer from another species) using remote protein structural homology. Here, we identify for the first time a non-synonymous mutation in the Ptr necrotrophic effector gene ToxB , multiple copies of the inactive toxb within an isolate, a distant natural Pyrenophora homologue of a known Parastagonopora nodorum necrotrophic effector (SnTox3), and clear genomic break points for the ToxA effector horizontal transfer region. This comprehensive genomic analysis of Ptr races includes nine isolates sequenced via long read technologies. Accordingly, these resources provide a more complete representation of the species, and serve as a resource to monitor variations potentially involved in pathogenicity.

Published

2022

5. A triple threat: the Parastagonospora nodorum SnTox267 effector exploits three distinct host genetic factors to cause disease in wheat.

Author

Richards JK, Kariyawasam GK, Seneviratne S, Wyatt NA, Xu SS, Liu Z, Faris JD, and Friesen TL

Subjects

Host-Pathogen Interactions genetics, Plant Diseases genetics, Virulence genetics, Ascomycota genetics, Triticum genetics

Abstract

Parastagonospora nodorum is a fungal pathogen of wheat. As a necrotrophic specialist, it deploys effector proteins that target dominant host susceptibility genes to elicit programmed cell death (PCD). Here we identify and functionally validate the effector targeting the host susceptibility genes Snn2, Snn6 and Snn7. We utilized whole-genome sequencing, association mapping, gene-disrupted mutants, gain-of-function transformants, virulence assays, bioinformatics and quantitative PCR to characterize these interactions. A single proteinaceous effector, SnTox267, targeted Snn2, Snn6 and Snn7 to trigger PCD. Snn2 and Snn6 functioned cooperatively to trigger PCD in a light-dependent pathway, whereas Snn7-mediated PCD functioned in a light-independent pathway. Isolates harboring 20 SnTox267 protein isoforms quantitatively varied in virulence. The diversity and distribution of isoforms varied between populations, indicating adaptation to local selection pressures. SnTox267 deletion resulted in the upregulation of effector genes SnToxA, SnTox1 and SnTox3. We validated a novel effector operating in an inverse-gene-for-gene manner to target three genetically distinct host susceptibility genes and elicit PCD. The discovery of the complementary gene action of Snn2 and Snn6 indicates their potential function in a guard or decoy model. Additionally, differences in light dependency in the elicited pathways and upregulation of unlinked effectors sheds new light onto a complex fungal necrotroph-host interaction., (© No claim to US Government works New Phytologist © 2021 New Phytologist Foundation.)

Published

2022

6. The Parastagonospora nodorum necrotrophic effector SnTox5 targets the wheat gene Snn5 and facilitates entry into the leaf mesophyll.

Author

Kariyawasam GK, Richards JK, Wyatt NA, Running KLD, Xu SS, Liu Z, Borowicz P, Faris JD, and Friesen TL

Subjects

Ascomycota, Plant Diseases genetics, Plant Leaves, Genome-Wide Association Study, Triticum genetics

Abstract

Parastagonospora nodorum is an economically important necrotrophic fungal pathogen of wheat. Parastagonospora nodorum secretes necrotrophic effectors that target wheat susceptibility genes to induce programmed cell death (PCD). In this study, we cloned and functionally validated SnTox5 and characterized its role in pathogenesis. We used whole genome sequencing, genome-wide association study (GWAS) mapping, CRISPR-Cas9-based gene disruption, gain-of-function transformation, quantitative trait locus (QTL) analysis, haplotype and isoform analysis, protein modeling, quantitative PCR, and laser confocal microscopy to validate SnTox5 and functionally characterize SnTox5. SnTox5 is a mature 16.26 kDa protein with high structural similarity to SnTox3. Wild-type and mutant P. nodorum strains and wheat genotypes of SnTox5 and Snn5, respectively, were used to show that SnTox5 not only targets Snn5 to induce PCD but also facilitates the colonization of the mesophyll layer even in the absence of Snn5. Here we show that SnTox5 facilitates the efficient colonization of the mesophyll tissue and elicits PCD specific to host lines carrying Snn5. The homology to SnTox3 and the ability of SnTox5 to facilitate the colonizing of the mesophyll also suggest a role in the suppression of host defense before PCD induction., (© No claim to US Government works New Phytologist © 2021 New Phytologist Foundation.)

Published

2022

7. Pyrenophora tritici-repentis Race 4 Isolates Cause Disease on Tetraploid Wheat.

Author

Guo J, Shi G, Kalil A, Friskop A, Elias E, Xu SS, Faris JD, and Liu Z

Subjects

Humans, North Dakota, Plant Diseases, Tetraploidy, Ascomycota genetics, Triticum genetics

Abstract

The ascomycete fungus Pyrenophora tritici-repentis is the causal agent of tan spot of wheat. The disease can occur on both common wheat ( Triticum aestivum ) and durum wheat ( T . turgidum ssp. durum ) and has potential to cause significant yield and quality losses. The fungal pathogen is known to produce necrotrophic effectors (NEs) that act as important virulence factors. Based on the NE production and virulence on a set of four differentials, P. tritici-repentis isolates have been classified into eight races. Race 4 produces no known NEs and is avirulent on the differentials. From a fungal collection in North Dakota, we identified several isolates that were classified as race 4. These isolates caused no or little disease on all common wheat lines including the differentials; however, they were virulent on some durum cultivars and tetraploid wheat accessions. Using two segregating tetraploid wheat populations and quantitative trait locus mapping, we identified several genomic regions significantly associated with disease caused by two of these isolates, some of which have not been previously reported. This is the first report that race 4 is virulent on tetraploid wheat, likely utilizing unidentified NEs. Our findings further highlight the insufficiency of the current race classification system for P. tritici-repentis .

Published

2020

8. Meta-QTL analysis of tan spot resistance in wheat.

Author

Liu Y, Salsman E, Wang R, Galagedara N, Zhang Q, Fiedler JD, Liu Z, Xu S, Faris JD, and Li X

Subjects

Ascomycota isolation & purification, Genes, Plant, Genetic Linkage, Phenotype, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Triticum metabolism, Triticum microbiology, Chromosome Mapping methods, Disease Resistance genetics, Host-Pathogen Interactions genetics, Plant Diseases genetics, Triticum genetics

Abstract

Key Message: A total of 19 meta-QTL conferring resistance to tan spot were identified from 104 initial QTL detected in 15 previous QTL mapping studies. Tan spot, caused by the fungal pathogen Pyrenophora tritici-repentis (Ptr), is a major foliar disease worldwide in both bread wheat and durum wheat and can reduce grain yield due to reduction in photosynthetic area of leaves. Developing and growing resistant cultivars is a cost-effective and environmentally friendly approach to mitigate negative effects of the disease. Understanding the genetic basis of tan spot resistance can enhance the development of resistant cultivars. With that goal, over 100 QTL associated with resistance to tan spot induced by a variety of Ptr races and isolates have been identified from previous QTL mapping studies. Meta-QTL analysis can identify redundant QTL among various studies and reveal major QTL for targeting in marker-assisted selection applications. In this study, we performed a meta-QTL analysis of tan spot resistance using the reported QTL from 15 previous QTL mapping studies. An integrated linkage map with a total length of 4080.5 cM containing 47,309 markers was assembled from 21 individual linkage maps and three previously published consensus maps. Nineteen meta-QTL were clustered from 104 initial QTL projected on the integrated map. Three of the 19 meta-QTL located on chromosomes 2A, 3B, and 5A show large genetic effects and confer resistance to multiple races in multiple bread wheat and durum wheat mapping populations. The integration of those race-nonspecific QTL is a promising strategy to provide high and stable resistance to tan spot in wheat.

Published

2020

9. Genome-wide association mapping of tan spot resistance in a worldwide collection of durum wheat.

Author

Galagedara N, Liu Y, Fiedler J, Shi G, Chiao S, Xu SS, Faris JD, Li X, and Liu Z

Subjects

Ascomycota pathogenicity, Chromosome Mapping, Chromosomes, Plant, Genes, Plant, Genetic Association Studies, Genetic Linkage, Genetic Markers, Genotype, Phenotype, Plant Diseases microbiology, Quantitative Trait Loci, Disease Resistance genetics, Plant Diseases genetics, Polymorphism, Single Nucleotide, Triticum genetics

Abstract

Key Message: Resistance to tan spot in durum wheat involves race-nonspecific QTL and necrotrophic insensitivity gene. Tan spot, caused by the necrotrophic fungus Pyrenophoratritici-repentis, is a major foliar disease on all cultivated wheat crops worldwide. Compared to common wheat, much less work has been done to investigate the genetic basis of tan spot resistance in durum. Here, we conducted disease evaluations, necrotrophic effector (NE) sensitivity assays and a genome-wide association study using a collection of durum accessions. The durum panel segregated for the reaction to disease inoculations and NE infiltrations with eighteen accessions being highly resistant to all races and most of them insensitive to both PtrToxA and PtrToxB. Over 65,000SNP markers were developed from genotyping-by-sequencing for the association mapping. As expected, sensitivity to PtrToxA and PtrToxB was mapped to the chromosome arms 5BL and 2BS, respectively. For the fungal inoculations, a quantitative trait locus (QTL) on chromosome 3B was associated with resistance to all races and likely corresponds to the race-nonspecific resistance QTL previously identified in common wheat. The Tsn1locus was not significantly associated with tan spot caused by the PtrToxA-producing isolates Pti2 and 86-124, but the Tsc2 locus was significantly associated with tan spot caused by the PtrToxB-producing isolate DW5. Another QTL on chromosome arm 1AS was associated with tan spot caused by the PtrToxC-producing isolate Pti2 and likely corresponds to the Tsc1 locus. Additional QTL for specific races was identified on chromosome 1B and 3B. Our work highlights the complexity of genetic resistance to tan spot and further confirms that the Ptr ToxA-Tsn1 interaction plays no significant role in disease development in tetraploid wheat.

Published

2020

10. Identification of a major dominant gene for race-nonspecific tan spot resistance in wild emmer wheat.

Author

Faris JD, Overlander ME, Kariyawasam GK, Carter A, Xu SS, and Liu Z

Subjects

Alleles, Chromosome Mapping, Electrophoresis, Polyacrylamide Gel, Genes, Dominant, Genes, Plant, Genetic Linkage, Genetic Markers, Plant Diseases microbiology, Polymorphism, Single Nucleotide, Polyploidy, Quantitative Trait Loci, Ascomycota, Disease Resistance genetics, Host-Pathogen Interactions genetics, Plant Diseases genetics, Triticum genetics

Abstract

Key Message: A single dominant gene found in tetraploid and hexaploid wheat controls broad-spectrum race-nonspecific resistance to the foliar disease tan spot caused by Pyrenophora tritici-repentis. Tan spot is an important foliar disease of durum and common wheat caused by the necrotrophic fungal pathogen Pyrenophora tritici-repentis. Genetic studies in common wheat have shown that pathogen-produced necrotrophic effectors interact with host genes in an inverse gene-for-gene manner to cause disease, but quantitative trait loci (QTLs) with broad race-nonspecific resistance also exist. Less work has been done to understand the genetics of tan spot interactions in durum wheat. Here, we evaluated a set of Langdon durum-wild emmer (Triticum turgidum ssp. dicoccoides) disomic chromosome substitution lines for reaction to four P. tritici-repentis isolates representing races 1, 2, 3, and 5 to identify wild emmer chromosomes potentially containing tan spot resistance genes. Chromosome 3B from the wild emmer accession IsraelA rendered the tan spot-susceptible durum cultivar Langdon resistant to all four fungal isolates. Genetic analysis indicated that a single dominant gene, designated Tsr7, governed resistance. Detailed mapping experiments showed that the Tsr7 locus is likely the same as the race-nonspecific QTL previously identified in the hexaploid wheat cultivars BR34 and Penawawa. Four user-friendly SNP-based semi-thermal asymmetric reverse PCR (STARP) markers cosegregated with Tsr7 and should be useful for marker-assisted selection of resistance. In addition to 3B, other wild emmer chromosomes contributed moderate levels of tan spot resistance, and, as has been shown previously for tetraploid wheat, the Tsn1-Ptr ToxA interaction was not associated with susceptibility. This is the first report of a major dominant gene governing resistance to tan spot in tetraploid wheat.

Published

2020

11. QTL mapping of resistance to tan spot induced by race 2 of Pyrenophora tritici-repentis in tetraploid wheat.

Author

Liu Y, Zhang Q, Salsman E, Fiedler JD, Hegstad JB, Liu Z, Faris JD, Xu SS, and Li X

Subjects

Ascomycota genetics, Ascomycota pathogenicity, Chromosome Mapping, Disease Resistance physiology, Gene Knockout Techniques, Genes, Plant, Genetic Linkage, Genotype, Mycotoxins, Phenotype, Plant Breeding, Plant Diseases microbiology, Plants, Genetically Modified, Tetraploidy, Triticum metabolism, Disease Resistance genetics, Host-Pathogen Interactions genetics, Plant Diseases genetics, Quantitative Trait Loci, Triticum genetics

Abstract

Key Message: A total of 12 QTL conferring resistance to tan spot induced by a race 2 isolate, 86-124, were identified in three tetraploid wheat mapping populations. Durum is a tetraploid species of wheat and an important food crop. Tan spot, caused by the necrotrophic fungal pathogen Pyrenophora tritici-repentis (Ptr), is a major foliar disease of both tetraploid durum wheat and hexaploid bread wheat. Understanding the Ptr-wheat interaction and identifying major QTL can facilitate the development of resistant cultivars and effectively mitigate the negative effect of this disease. Over 100 QTL have already been discovered in hexaploid bread wheat, whereas few mapping studies have been conducted in durum wheat. Utilizing resistant resources and identifying novel resistant loci in tetraploid wheat will be beneficial for the development of tan spot-resistant durum varieties. In this study, we evaluated four interconnected tetraploid wheat populations for their reactions to the race 2 isolate 86-124, which produces Ptr ToxA. Tsn1, the wheat gene that confers sensitivity to Ptr ToxA, was not associated with tan spot severity in any of the four populations. We found a total of 12 tan spot-resistant QTL among the three mapping populations. The QTL located on chromosomes 3A and 5A were detected in multiple populations and co-localized with race-nonspecific QTL identified in other mapping studies. Together, these QTL can confer high levels of resistance and can be used for the improvement in tan spot resistance in both hexaploid bread and durum wheat breeding. Two QTL on chromosomes 1B and 7A, respectively, were found in one population when inoculated with a ToxA knockout strain 86-124ΔToxA only, indicating that their association with tan spot was induced by other unidentified necrotrophic effectors, but under the absence of Ptr ToxA. In addition to removal of the known dominant susceptibility genes, integrating major race-nonspecific resistance loci like the QTL identified on chromosome 3A and 5A in this study could confer high and stable tan spot resistance in durum wheat.

Published

2020

12. Local adaptation drives the diversification of effectors in the fungal wheat pathogen Parastagonospora nodorum in the United States.

Author

Richards JK, Stukenbrock EH, Carpenter J, Liu Z, Cowger C, Faris JD, and Friesen TL

Subjects

Acclimatization genetics, Ascomycota pathogenicity, Evolution, Molecular, Fungal Proteins genetics, Fungi pathogenicity, Genetics, Population, Genomics, Host-Pathogen Interactions genetics, Plant Diseases microbiology, Polymorphism, Single Nucleotide genetics, Quantitative Trait Loci genetics, Triticum genetics, Triticum growth & development, Virulence Factors genetics, Ascomycota genetics, Fungi genetics, Plant Diseases genetics, Selection, Genetic genetics, Triticum microbiology

Abstract

Filamentous fungi rapidly evolve in response to environmental selection pressures in part due to their genomic plasticity. Parastagonospora nodorum, a fungal pathogen of wheat and causal agent of septoria nodorum blotch, responds to selection pressure exerted by its host, influencing the gain, loss, or functional diversification of virulence determinants, known as effector genes. Whole genome resequencing of 197 P. nodorum isolates collected from spring, durum, and winter wheat production regions of the United States enabled the examination of effector diversity and genomic regions under selection specific to geographically discrete populations. 1,026,859 SNPs/InDels were used to identify novel loci, as well as SnToxA and SnTox3 as factors in disease. Genes displaying presence/absence variation, predicted effector genes, and genes localized on an accessory chromosome had significantly higher pN/pS ratios, indicating a higher rate of sequence evolution. Population structure analyses indicated two P. nodorum populations corresponding to the Upper Midwest (Population 1) and Southern/Eastern United States (Population 2). Prevalence of SnToxA varied greatly between the two populations which correlated with presence of the host sensitivity gene Tsn1 in the most prevalent cultivars in the corresponding regions. Additionally, 12 and 5 candidate effector genes were observed to be under diversifying selection among isolates from Population 1 and 2, respectively, but under purifying selection or neutrally evolving in the opposite population. Selective sweep analysis revealed 10 and 19 regions that had recently undergone positive selection in Population 1 and 2, respectively, involving 92 genes in total. When comparing genes with and without presence/absence variation, those genes exhibiting this variation were significantly closer to transposable elements. Taken together, these results indicate that P. nodorum is rapidly adapting to distinct selection pressures unique to spring and winter wheat production regions by rapid adaptive evolution and various routes of genomic diversification, potentially facilitated through transposable element activity., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

13. Xanthomonas translucens commandeers the host rate-limiting step in ABA biosynthesis for disease susceptibility.

Author

Peng Z, Hu Y, Zhang J, Huguet-Tapia JC, Block AK, Park S, Sapkota S, Liu Z, Liu S, and White FF

Subjects

Dioxygenases genetics, Dioxygenases metabolism, Disease Susceptibility, Gene Expression Regulation, Plant, Host-Pathogen Interactions, Plant Diseases immunology, Plant Proteins genetics, Plant Proteins metabolism, Triticum genetics, Triticum immunology, Triticum metabolism, Virulence, Xanthomonas pathogenicity, Abscisic Acid metabolism, Plant Diseases microbiology, Plant Growth Regulators biosynthesis, Triticum microbiology, Xanthomonas physiology

Abstract

Plants are vulnerable to disease through pathogen manipulation of phytohormone levels, which otherwise regulate development, abiotic, and biotic responses. Here, we show that the wheat pathogen Xanthomonas translucens pv. undulosa elevates expression of the host gene encoding 9- cis -epoxycarotenoid dioxygenase ( TaNCED-5BS ), which catalyzes the rate-limiting step in the biosynthesis of the phytohormone abscisic acid and a component of a major abiotic stress-response pathway, to promote disease susceptibility. Gene induction is mediated by a type III transcription activator-like effector. The induction of TaNCED-5BS results in elevated abscisic acid levels, reduced host transpiration and water loss, enhanced spread of bacteria in infected leaves, and decreased expression of the central defense gene TaNPR1 The results represent an appropriation of host physiology by a bacterial virulence effector., Competing Interests: The authors declare no competing interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

14. Transposon-Mediated Horizontal Transfer of the Host-Specific Virulence Protein ToxA between Three Fungal Wheat Pathogens.

Author

McDonald MC, Taranto AP, Hill E, Schwessinger B, Liu Z, Simpfendorfer S, Milgate A, and Solomon PS

Subjects

Base Sequence, Evolution, Molecular, Host-Pathogen Interactions genetics, Sequence Alignment, Virulence genetics, Ascomycota genetics, DNA Transposable Elements genetics, Fungal Proteins genetics, Gene Transfer, Horizontal, Mycotoxins genetics, Plant Diseases microbiology, Triticum microbiology

Abstract

Most known examples of horizontal gene transfer (HGT) between eukaryotes are ancient. These events are identified primarily using phylogenetic methods on coding regions alone. Only rarely are there examples of HGT where noncoding DNA is also reported. The gene encoding the wheat virulence protein ToxA and the surrounding 14 kb is one of these rare examples. ToxA has been horizontally transferred between three fungal wheat pathogens ( Parastagonospora nodorum , Pyrenophora tritici- repentis , and Bipolaris sorokiniana ) as part of a conserved ∼14 kb element which contains coding and noncoding regions. Here we used long-read sequencing to define the extent of HGT between these three fungal species. Construction of near-chromosomal-level assemblies enabled identification of terminal inverted repeats on either end of the 14 kb region, typical of a type II DNA transposon. This is the first description of ToxA with complete transposon features, which we call ToxhAT. In all three species, ToxhAT resides in a large (140-to-250 kb) transposon-rich genomic island which is absent in isolates that do not carry the gene (annotated here as toxa - ). We demonstrate that the horizontal transfer of ToxhAT between P. tritici-repentis and P. nodorum occurred as part of a large (∼80 kb) HGT which is now undergoing extensive decay. In B. sorokiniana , in contrast, ToxhAT and its resident genomic island are mobile within the genome. Together, these data provide insight into the noncoding regions that facilitate HGT between eukaryotes and into the genomic processes which mask the extent of HGT between these species. IMPORTANCE This work dissects the tripartite horizontal transfer of ToxA , a gene that has a direct negative impact on global wheat yields. Defining the extent of horizontally transferred DNA is important because it can provide clues to the mechanisms that facilitate HGT. Our analysis of ToxA and its surrounding 14 kb suggests that this gene was horizontally transferred in two independent events, with one event likely facilitated by a type II DNA transposon. These horizontal transfer events are now in various processes of decay in each species due to the repeated insertion of new transposons and subsequent rounds of targeted mutation by a fungal genome defense mechanism known as repeat induced point mutation. This work highlights the role that HGT plays in the evolution of host adaptation in eukaryotic pathogens. It also increases the growing body of evidence indicating that transposons facilitate adaptive HGT events between fungi present in similar environments and hosts., (Copyright © 2019 McDonald et al.)

Published

2019

15. Chromosome engineering-mediated introgression and molecular mapping of novel Aegilops speltoides-derived resistance genes for tan spot and Septoria nodorum blotch diseases in wheat.

Author

Zhang W, Zhu X, Zhang M, Shi G, Liu Z, and Cai X

Subjects

Aegilops growth & development, Aegilops microbiology, Chromosome Mapping, Chromosomes, Plant genetics, Genetic Markers, Genotype, Homologous Recombination, Host-Pathogen Interactions, Phenotype, Plant Breeding, Plant Diseases microbiology, Triticum growth & development, Triticum microbiology, Aegilops genetics, Ascomycota physiology, Disease Resistance genetics, Plant Diseases genetics, Plant Proteins genetics, Polymorphism, Single Nucleotide, Triticum genetics

Abstract

Key Message: We identified, mapped and introduced novel Aegilops speltoides-derived resistance genes for tan spot and SNB diseases into wheat, enhancing understanding and utilization of host resistance to both diseases in wheat. Tan spot and Septoria nodorum blotch (SNB) are two important fungal diseases of wheat. Resistance to these diseases is often observed as the lack of sensitivity to the necrotrophic effectors (NE) produced by the fungal pathogens and thus exhibits a recessive inheritance pattern. In this study, we identified novel genes for resistance to tan spot and SNB on Aegilops speltoides (2n = 2x = 14, genome SS) chromosome 2S. These genes confer dominant resistance in the wheat background, indicating a distinct NE-independent mechanism of resistance. Ae. speltoides chromosome 2S was engineered for resistance gene introgression and molecular mapping by inducing meiotic homoeologous recombination with wheat chromosome 2B. Twenty representative 2B-2S recombinants were evaluated for reaction to tan spot and SNB and were delineated by genomic in situ hybridization and high-throughput wheat 90 K SNP assay. The resistance genes physically mapped to the sub-telomeric region (~ 8 Mb) on the short arm of chromosome 2S and designated TsrAes1 for tan spot resistance and SnbAes1 for SNB resistance. In addition, we developed SNP-derived PCR markers closely linked to TsrAes1/SnbAes1 for marker-assisted selection in wheat breeding. TsrAes1 and SnbAes1 are the first set of NE-independent tan spot, and SNB resistance genes are identified from Ae. speltoides. The 2SS-2BS·2BL recombinants with minimal amounts of Ae. speltoides chromatin containing TsrAes1/SnbAes1 were produced for germplasm development, making the wild species-derived resistance genes usable in wheat breeding. This will strengthen and diversify resistance of wheat to tan spot and SNB and facilitate understanding of resistance to these two diseases.

Published

2019

16. Comparative genomics of the wheat fungal pathogen Pyrenophora tritici-repentis reveals chromosomal variations and genome plasticity.

Author

Moolhuijzen P, See PT, Hane JK, Shi G, Liu Z, Oliver RP, and Moffat CS

Subjects

Gene Transfer, Horizontal, Genome, Mitochondrial genetics, Molecular Sequence Annotation, Phylogeny, Sequence Homology, Nucleic Acid, Ascomycota genetics, Ascomycota physiology, Chromosomes, Fungal genetics, Genetic Variation, Genome, Fungal genetics, Genomics, Triticum microbiology

Abstract

Background: Pyrenophora tritici-repentis (Ptr) is a necrotrophic fungal pathogen that causes the major wheat disease, tan spot. We set out to provide essential genomics-based resources in order to better understand the pathogenicity mechanisms of this important pathogen., Results: Here, we present eight new Ptr isolate genomes, assembled and annotated; representing races 1, 2 and 5, and a new race. We report a high quality Ptr reference genome, sequenced by PacBio technology with Illumina paired-end data support and optical mapping. An estimated 98% of the genome coverage was mapped to 10 chromosomal groups, using a two-enzyme hybrid approach. The final reference genome was 40.9 Mb and contained a total of 13,797 annotated genes, supported by transcriptomic and proteogenomics data sets., Conclusions: Whole genome comparative analysis revealed major chromosomal segmental rearrangements and fusions, highlighting intraspecific genome plasticity in this species. Furthermore, the Ptr race classification was not supported at the whole genome level, as phylogenetic analysis did not cluster the ToxA producing isolates. This expansion of available Ptr genomics resources will directly facilitate research aimed at controlling tan spot disease.

Published

2018

17. Inverse gene-for-gene interactions contribute additively to tan spot susceptibility in wheat.

Author

Liu Z, Zurn JD, Kariyawasam G, Faris JD, Shi G, Hansen J, Rasmussen JB, and Acevedo M

Subjects

Ascomycota, Chromosome Mapping, Genes, Plant, Genotype, Plant Diseases microbiology, Triticum microbiology, Disease Resistance genetics, Epistasis, Genetic, Plant Diseases genetics, Quantitative Trait Loci, Triticum genetics

Abstract

Key Message: Tan spot susceptibility is conferred by multiple interactions of necrotrophic effector and host sensitivity genes. Tan spot of wheat, caused by Pyrenophora tritici-repentis, is an important disease in almost all wheat-growing areas of the world. The disease system is known to involve at least three fungal-produced necrotrophic effectors (NEs) that interact with the corresponding host sensitivity (S) genes in an inverse gene-for-gene manner to induce disease. However, it is unknown if the effects of these NE-S gene interactions contribute additively to the development of tan spot. In this work, we conducted disease evaluations using different races and quantitative trait loci (QTL) analysis in a wheat recombinant inbred line (RIL) population derived from a cross between two susceptible genotypes, LMPG-6 and PI 626573. The two parental lines each harbored a single known NE sensitivity gene with LMPG-6 having the Ptr ToxC sensitivity gene Tsc1 and PI 626573 having the Ptr ToxA sensitivity gene Tsn1. Transgressive segregation was observed in the population for all races. QTL mapping revealed that both loci (Tsn1 and Tsc1) were significantly associated with susceptibility to race 1 isolates, which produce both Ptr ToxA and Ptr ToxC, and the two genes contributed additively to tan spot susceptibility. For isolates of races 2 and 3, which produce only Ptr ToxA and Ptr ToxC, only Tsn1 and Tsc1 were associated with tan spot susceptibility, respectively. This work clearly demonstrates that tan spot susceptibility in this population is due primarily to two NE-S interactions. Breeders should remove both sensitivity genes from wheat lines to obtain high levels of tan spot resistance.

Published

2017

18. New Insights into the Roles of Host Gene-Necrotrophic Effector Interactions in Governing Susceptibility of Durum Wheat to Tan Spot and Septoria nodorum Blotch.

Author

Virdi SK, Liu Z, Overlander ME, Zhang Z, Xu SS, Friesen TL, and Faris JD

Subjects

Chromosome Mapping, Disease Resistance genetics, Gene Expression Profiling, Gene Expression Regulation, Plant, Genetic Linkage, Genetic Markers, Microsatellite Repeats, Phenotype, Plant Diseases microbiology, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Triticum microbiology, Genetic Predisposition to Disease, Host-Pathogen Interactions genetics, Plant Diseases genetics, Triticum genetics

Abstract

Tan spot and Septoria nodorum blotch (SNB) are important diseases of wheat caused by the necrotrophic fungi Pyrenophora tritici-repentis and Parastagonospora nodorum, respectively. The P. tritici-repentis necrotrophic effector (NE) Ptr ToxB causes tan spot when recognized by the Tsc2 gene. The NE ToxA is produced by both pathogens and has been associated with the development of both tan spot and SNB when recognized by the wheat Tsn1 gene. Most work to study these interactions has been conducted in common wheat, but little has been done in durum wheat. Here, quantitative trait loci (QTL) analysis of a segregating biparental population indicated that the Tsc2-Ptr ToxB interaction plays a prominent role in the development of tan spot in durum. However, analysis of two biparental populations indicated that the Tsn1-ToxA interaction was not associated with the development of tan spot, but was strongly associated with the development of SNB. Pa. nodorum expressed ToxA at high levels in infected Tsn1 plants, whereas ToxA expression in P. tritici-repentis was barely detectable, suggesting that the differences in disease levels associated with the Tsn1-ToxA interaction were due to differences in pathogen expression of ToxA These and previous results together indicate that: (1) the effects of Tsn1-ToxA on tan spot in common wheat can range from nonsignificant to highly significant depending on the host genetic background; (2) Tsn1-ToxA is not a significant factor for tan spot development in durum wheat; and (3) Tsn1-ToxA plays a major role in SNB development in both common and durum wheat. Durum and common wheat breeders alike should strive to remove both Tsc2 and Tsn1 from their materials to achieve disease resistance., (Copyright © 2016 Virdi et al.)

Published

2016

19. The hijacking of a receptor kinase-driven pathway by a wheat fungal pathogen leads to disease.

Author

Shi G, Zhang Z, Friesen TL, Raats D, Fahima T, Brueggeman RS, Lu S, Trick HN, Liu Z, Chao W, Frenkel Z, Xu SS, Rasmussen JB, and Faris JD

Subjects

Ascomycota genetics, Ascomycota pathogenicity, Fungal Proteins genetics, Ascomycota metabolism, Fungal Proteins metabolism, G-Protein-Coupled Receptor Kinases metabolism, Plant Diseases microbiology, Plant Proteins metabolism, Signal Transduction, Triticum enzymology, Triticum microbiology

Abstract

Necrotrophic pathogens live and feed on dying tissue, but their interactions with plants are not well understood compared to biotrophic pathogens. The wheat Snn1 gene confers susceptibility to strains of the necrotrophic pathogen Parastagonospora nodorum that produce the SnTox1 protein. We report the positional cloning of Snn1 , a member of the wall-associated kinase class of receptors, which are known to drive pathways for biotrophic pathogen resistance. Recognition of SnTox1 by Snn1 activates programmed cell death, which allows this necrotroph to gain nutrients and sporulate. These results demonstrate that necrotrophic pathogens such as P. nodorum hijack host molecular pathways that are typically involved in resistance to biotrophic pathogens, revealing the complex nature of susceptibility and resistance in necrotrophic and biotrophic pathogen interactions with plants.

Published

2016

20. Validation of Genome-Wide Association Studies as a Tool to Identify Virulence Factors in Parastagonospora nodorum.

Author

Gao Y, Liu Z, Faris JD, Richards J, Brueggeman RS, Li X, Oliver RP, McDonald BA, and Friesen TL

Subjects

Ascomycota pathogenicity, Fungal Proteins genetics, Genetic Markers genetics, Genotype, Genotyping Techniques, Phenotype, Polymorphism, Single Nucleotide genetics, Ascomycota genetics, Genome-Wide Association Study, Plant Diseases microbiology, Triticum microbiology, Virulence Factors genetics

Abstract

Parastagonospora nodorum is a necrotrophic fungal pathogen causing Septoria nodorum blotch on wheat. We have identified nine necrotrophic effector-host dominant sensitivity gene interactions, and we have cloned three of the necrotrophic effector genes, including SnToxA, SnTox1, and SnTox3. Because sexual populations of P. nodorum are difficult to develop under lab conditions, genome-wide association study (GWAS) is the best population genomic approach to identify genomic regions associated with traits using natural populations. In this article, we used a global collection of 191 P. nodorum isolates from which we identified 2,983 single-nucleotide polymorphism (SNP) markers and gene markers for SnToxA and SnTox3 to evaluate the power of GWAS on two popular wheat breeding lines that were sensitive to SnToxA and SnTox3. Strong marker trait associations (MTA) with P. nodorum virulence that mapped to SnTox3 and SnToxA were first identified using the marker set described above. A novel locus in the P. nodorum genome associated with virulence was also identified as a result of this analysis. To evaluate whether a sufficient level of marker saturation was available, we designed a set of primers every 1 kb in the genomic regions containing SnToxA and SnTox3. Polymerase chain reaction amplification was performed across the 191 isolates and the presence/absence polymorphism was scored and used as the genotype. The marker proximity necessary to identify MTA flanking SnToxA and SnTox3 ranged from 4 to 5 and 1 to 7 kb, respectively. Similar analysis was performed on the novel locus. Using a 45% missing data threshold, two more SNP were identified spanning a 4.6-kb genomic region at the novel locus. These results showed that the rate of linkage disequilibrium (LD) decay in P. nodorum and, likely, other fungi is high compared with plants and animals. The fast LD decay in P. nodorum is an advantage only if sufficient marker density is attained. Based on our results with the SnToxA and SnTox3 regions, markers are needed every 9 or 8 kb, respectively, or in every gene, to guarantee that genes associated with a quantitative trait such as virulence are not missed.

Published

2016

21. SnTox1, a Parastagonospora nodorum necrotrophic effector, is a dual-function protein that facilitates infection while protecting from wheat-produced chitinases.

Author

Liu Z, Gao Y, Kim YM, Faris JD, Shelver WL, de Wit PJ, Xu SS, and Friesen TL

Subjects

Ascomycota cytology, Ascomycota growth & development, Ascomycota pathogenicity, Chitin metabolism, Green Fluorescent Proteins metabolism, Mesophyll Cells microbiology, Mycelium metabolism, Plant Leaves microbiology, Virulence, Ascomycota metabolism, Chitinases metabolism, Fungal Proteins metabolism, Triticum enzymology, Triticum microbiology

Abstract

SnTox1 induces programmed cell death and the up-regulation of pathogenesis-related genes including chitinases. Additionally, SnTox1 has structural homology to several plant chitin-binding proteins. Therefore, we evaluated SnTox1 for chitin binding and localization. We transformed an avirulent strain of Parastagonospora nodorum as well as three nonpathogens of wheat (Triticum aestivum), including a necrotrophic pathogen of barley, a hemibiotrophic pathogen of sugar beet and a saprotroph, to evaluate the role of SnTox1 in infection and in protection from wheat chitinases. SnTox1 bound chitin and an SnTox1-green fluorescent fusion protein localized to the mycelial cell wall. Purified SnTox1 induced necrosis in the absence of the pathogen when sprayed on the leaf surface and appeared to remain on the leaf surface while inducing both epidermal and mesophyll cell death. SnTox1 protected the different fungi from chitinase degradation. SnTox1 was sufficient to change the host range of a necrotrophic pathogen but not a hemibiotroph or saprotroph. Collectively, this work shows that SnTox1 probably interacts with a receptor on the outside of the cell to induce cell death to acquire nutrients, but SnTox1 accomplishes a second role in that it protects against one aspect of the defense response, namely the effects of wheat chitinases., (No claim to original US government works New Phytologist © 2016 New Phytologist Trust.)

Published

2016

22. Genetic relationships between race-nonspecific and race-specific interactions in the wheat-Pyrenophora tritici-repentis pathosystem.

Author

Kariyawasam GK, Carter AH, Rasmussen JB, Faris J, Xu SS, Mergoum M, and Liu Z

Subjects

Chromosome Mapping, Crosses, Genetic, Epistasis, Genetic, Genetic Linkage, Inbreeding, Plant Diseases microbiology, Species Specificity, Ascomycota, Disease Resistance genetics, Host-Pathogen Interactions genetics, Plant Diseases genetics, Quantitative Trait Loci, Triticum genetics

Abstract

Key Message: We identified a major QTL conferring race-nonspecific resistance and revealed its relationships with race-specific interactions in the wheat- Pyrenophora tritici-repentis pathosystem. Tan spot, caused by the fungus Pyrenophora tritici-repentis (Ptr), is a destructive disease of wheat worldwide. The disease system is known to include inverse gene-for-gene, race-specific interactions involving the recognition of fungal-produced necrotrophic effectors (NEs) by corresponding host sensitivity genes. However, quantitative trait loci (QTLs) conferring race-nonspecific resistance have also been identified. In this work, we identified a major race-nonspecific resistance QTL and characterized its genetic relationships with the NE-host gene interactions Ptr ToxA-Tsn1 and Ptr ToxC-Tsc1 in a recombinant inbred wheat population derived from the cross between 'Louise' and 'Penawawa.' Both parental lines were sensitive to Ptr ToxA, but Penawawa and Louise were highly resistant and susceptible, respectively, to conidial inoculations of all races. Resistance was predominantly governed by a major race-nonspecific QTL on chromosome arm 3BL for resistance to all races. Another significant QTL was detected at the distal end of chromosome arm 1AS for resistance to the Ptr ToxC-producing isolates, which corresponded to the known location of the Tsc1 locus. The effects of the 3B and 1A QTLs were largely additive, and the 3B resistance QTL was epistatic to the Ptr ToxA-Tsn1 interaction. Resistance to race 2 in F1 plants was completely dominant; however, race 3-inoculated F1 plants were only moderately resistant because they developed chlorosis presumably due to the Ptr ToxC-Tsc1 interaction. This work provides further understanding of genetic resistance in the wheat-tan spot system as well as important guidance for tan spot resistance breeding.

Published

2016

23. FPLC and liquid-chromatography mass spectrometry identify candidate necrosis-inducing proteins from culture filtrates of the fungal wheat pathogen Zymoseptoria tritici.

Author

Ben M'Barek S, Cordewener JH, Tabib Ghaffary SM, van der Lee TA, Liu Z, Mirzadi Gohari A, Mehrabi R, America AH, Robert O, Friesen TL, Hamza S, Stergiopoulos I, de Wit PJ, and Kema GH

Subjects

Chromatography, Liquid, Electrophoresis, Polyacrylamide Gel, Fungal Proteins chemistry, Light, Mass Spectrometry, Protein Stability, Temperature, Virulence Factors chemistry, Ascomycota chemistry, Fungal Proteins analysis, Necrosis microbiology, Plant Diseases microbiology, Triticum microbiology, Virulence Factors analysis

Abstract

Culture filtrates (CFs) of the fungal wheat pathogen Zymoseptoria tritici were assayed for necrosis-inducing activity after infiltration in leaves of various wheat cultivars. Active fractions were partially purified and characterized. The necrosis-inducing factors in CFs are proteinaceous, heat stable and their necrosis-inducing activity is temperature and light dependent. The in planta activity of CFs was tested by a time series of proteinase K (PK) co-infiltrations, which was unable to affect activity 30min after CF infiltrations. This suggests that the necrosis inducing proteins (NIPs) are either absent from the apoplast and likely actively transported into mesophyll cells or protected from the protease by association with a receptor. Alternatively, plant cell death signaling pathways might be fully engaged during the first 30min and cannot be reversed even after PK treatment. Further fractionation of the CFs with the highest necrosis-inducing activity involved fast performance liquid chromatography, SDS-PAGE and mass spectrometry. This revealed that most of the proteins present in the fractions have not been described before. The two most prominent ZtNIP encoding candidates were heterologously expressed in Pichia pastoris and subsequent infiltration assays showed their differential activity in a range of wheat cultivars., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

24. Genetics of tan spot resistance in wheat.

Author

Faris JD, Liu Z, and Xu SS

Subjects

Ascomycota genetics, Databases, Genetic, Genes, Plant, Host-Pathogen Interactions, Mycotoxins isolation & purification, Plant Proteins genetics, Plant Proteins metabolism, Quantitative Trait Loci, Ascomycota pathogenicity, Plant Diseases genetics, Plant Diseases microbiology, Triticum genetics, Triticum microbiology

Abstract

Tan spot is a devastating foliar disease of wheat caused by the necrotrophic fungal pathogen Pyrenophora tritici-repentis. Much has been learned during the past two decades about the genetics of wheat-P. tritici-repentis interactions. Research has shown that the fungus produces at least three host-selective toxins (HSTs), known as Ptr ToxA, Ptr ToxB, and Ptr ToxC, that interact directly or indirectly with the products of the dominant host genes Tsn1, Tsc2, and Tsc1, respectively. The recent cloning and characterization of Tsn1 provided strong evidence that the pathogen utilizes HSTs to subvert host resistance mechanisms to cause disease. However, in addition to host-HST interactions, broad-spectrum, race non-specific resistance QTLs and recessively inherited qualitative 'resistance' genes have been identified. Molecular markers suitable for marker-assisted selection against HST sensitivity genes and for race non-specific resistance QTLs have been developed and used to generate adapted germplasm with good levels of tan spot resistance. Future research is needed to identify novel HSTs and corresponding host sensitivity genes, determine if the recessively inherited resistance genes are HST insensitivities, extend the current race classification system to account for new HSTs, and determine the molecular basis of race non-specific resistance QTLs and their relationships with host-HST interactions at the molecular level. Necrotrophic pathogens such as P. tritici-repentis are likely to become increasingly significant under a changing global climate making it imperative to further characterize the wheat-P. tritici-repentis pathosystem and develop tan spot resistant wheat varieties.

Published

2013

25. The cysteine rich necrotrophic effector SnTox1 produced by Stagonospora nodorum triggers susceptibility of wheat lines harboring Snn1.

Author

Liu Z, Zhang Z, Faris JD, Oliver RP, Syme R, McDonald MC, McDonald BA, Solomon PS, Lu S, Shelver WL, Xu S, and Friesen TL

Subjects

Disease Resistance physiology, Fungal Proteins genetics, Host-Pathogen Interactions, Plant Proteins genetics, Protein Sorting Signals physiology, Respiratory Burst genetics, Triticum genetics, Ascomycota physiology, Fungal Proteins metabolism, Gene Expression Regulation, Plant, Plant Diseases, Plant Proteins biosynthesis, Triticum metabolism

Abstract

The wheat pathogen Stagonospora nodorum produces multiple necrotrophic effectors (also called host-selective toxins) that promote disease by interacting with corresponding host sensitivity gene products. SnTox1 was the first necrotrophic effector identified in S. nodorum, and was shown to induce necrosis on wheat lines carrying Snn1. Here, we report the molecular cloning and validation of SnTox1 as well as the preliminary characterization of the mechanism underlying the SnTox1-Snn1 interaction which leads to susceptibility. SnTox1 was identified using bioinformatics tools and verified by heterologous expression in Pichia pastoris. SnTox1 encodes a 117 amino acid protein with the first 17 amino acids predicted as a signal peptide, and strikingly, the mature protein contains 16 cysteine residues, a common feature for some avirulence effectors. The transformation of SnTox1 into an avirulent S. nodorum isolate was sufficient to make the strain pathogenic. Additionally, the deletion of SnTox1 in virulent isolates rendered the SnTox1 mutated strains avirulent on the Snn1 differential wheat line. SnTox1 was present in 85% of a global collection of S. nodorum isolates. We identified a total of 11 protein isoforms and found evidence for strong diversifying selection operating on SnTox1. The SnTox1-Snn1 interaction results in an oxidative burst, DNA laddering, and pathogenesis related (PR) gene expression, all hallmarks of a defense response. In the absence of light, the development of SnTox1-induced necrosis and disease symptoms were completely blocked. By comparing the infection processes of a GFP-tagged avirulent isolate and the same isolate transformed with SnTox1, we conclude that SnTox1 may play a critical role during fungal penetration. This research further demonstrates that necrotrophic fungal pathogens utilize small effector proteins to exploit plant resistance pathways for their colonization, which provides important insights into the molecular basis of the wheat-S. nodorum interaction, an emerging model for necrotrophic pathosystems.

Published

2012

26. Two putatively homoeologous wheat genes mediate recognition of SnTox3 to confer effector-triggered susceptibility to Stagonospora nodorum.

Author

Zhang Z, Friesen TL, Xu SS, Shi G, Liu Z, Rasmussen JB, and Faris JD

Subjects

Brachypodium genetics, Gene Frequency, Genetic Linkage, Oryza genetics, Plant Diseases genetics, Plant Proteins genetics, Triticum genetics, Ascomycota physiology, Plant Diseases microbiology, Plant Proteins metabolism, Triticum metabolism, Triticum microbiology

Abstract

The pathogen Stagonospora nodorum produces multiple effectors, also known as host-selective toxins (HSTs), that interact with corresponding host sensitivity genes in an inverse gene-for-gene manner to cause the disease Stagonospora nodorum blotch (SNB) in wheat. In this study, a sensitivity gene was identified in Aegilops tauschii, the diploid D-genome donor of common wheat. The gene was mapped to the short arm of chromosome 5D and mediated recognition of the effector SnTox3, which was previously shown to be recognized by the wheat gene Snn3 on chromosome arm 5BS. Comparative mapping suggested that Snn3 and the gene on 5DS are probably homoeologous and derived from a common ancestor. Therefore, we propose to designate these genes as Snn3-B1 and Snn3-D1, respectively. Compatible Snn3-D1-SnTox3 interactions resulted in more severe necrosis in both effector infiltration and spore inoculation experiments than compatible Snn3-B1-SnTox3 interactions, indicating that Snn3-B1 and Snn3-D1 may have different affinities in SnTox3 recognition or signal transduction. Wheat bin-mapped expressed sequence tags and good levels of collinearity among the wheat Snn3 regions, rice (Oryza sativa), and Brachypodium distachyon were exploited for saturation and fine mapping of the Snn3-D1 locus. Markers delineating the Snn3-D1 locus to a 1.4 cM interval will be useful for initiating positional cloning. Further characterization of how these homoeologous genes mediate recognition of the same pathogen effector should enhance understanding of host manipulation by necrotrophic pathogens in causing disease., (The Plant Journal © 2010 Blackwell Publishing Ltd. No claim to original US goverment works.)

Published

2011

27. SnTox3 acts in effector triggered susceptibility to induce disease on wheat carrying the Snn3 gene.

Author

Liu Z, Faris JD, Oliver RP, Tan KC, Solomon PS, McDonald MC, McDonald BA, Nunez A, Lu S, Rasmussen JB, and Friesen TL

Subjects

Amino Acid Sequence, Ascomycota metabolism, Base Sequence, Blotting, Southern, Dithiothreitol, Fungal Proteins chemistry, Fungal Proteins genetics, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Genetic Variation, Host-Pathogen Interactions genetics, Molecular Sequence Data, Mycotoxins chemistry, Mycotoxins genetics, Mycotoxins metabolism, Pichia genetics, Pichia metabolism, Plant Diseases genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Triticum microbiology, Virulence, Ascomycota genetics, Fungal Proteins physiology, Mycotoxins physiology, Plant Diseases microbiology, Triticum genetics

Abstract

The necrotrophic fungus Stagonospora nodorum produces multiple proteinaceous host-selective toxins (HSTs) which act in effector triggered susceptibility. Here, we report the molecular cloning and functional characterization of the SnTox3-encoding gene, designated SnTox3, as well as the initial characterization of the SnTox3 protein. SnTox3 is a 693 bp intron-free gene with little obvious homology to other known genes. The predicted immature SnTox3 protein is 25.8 kDa in size. A 20 amino acid signal sequence as well as a possible pro sequence are predicted. Six cysteine residues are predicted to form disulfide bonds and are shown to be important for SnTox3 activity. Using heterologous expression in Pichia pastoris and transformation into an avirulent S. nodorum isolate, we show that SnTox3 encodes the SnTox3 protein and that SnTox3 interacts with the wheat susceptibility gene Snn3. In addition, the avirulent S. nodorum isolate transformed with SnTox3 was virulent on host lines expressing the Snn3 gene. SnTox3-disrupted mutants were deficient in the production of SnTox3 and avirulent on the Snn3 differential wheat line BG220. An analysis of genetic diversity revealed that SnTox3 is present in 60.1% of a worldwide collection of 923 isolates and occurs as eleven nucleotide haplotypes resulting in four amino acid haplotypes. The cloning of SnTox3 provides a fundamental tool for the investigation of the S. nodorum-wheat interaction, as well as vital information for the general characterization of necrotroph-plant interactions.

Published

2009

28. The Tsn1-ToxA interaction in the wheat-Stagonospora nodorum pathosystem parallels that of the wheat-tan spot system.

Author

Liu Z, Friesen TL, Ling H, Meinhardt SW, Oliver RP, Rasmussen JB, and Faris JD

Subjects

Alleles, Chromosome Mapping, Mycotoxins metabolism, Phenotype, Triticum microbiology, Ascomycota genetics, Ascomycota metabolism, Genes, Plant, Mycotoxins pharmacology, Plant Diseases genetics, Quantitative Trait Loci, Triticum drug effects, Triticum genetics

Abstract

The wheat tan spot fungus (Pyrenophora tritici-repentis) produces a well-characterized host-selective toxin (HST) known as Ptr ToxA, which induces necrosis in genotypes that harbor the Tsn1 gene on chromosome 5B. In previous work, we showed that the Stagonospora nodorum isolate Sn2000 produces at least 2 HSTs (SnTox1 and SnToxA). Sensitivity to SnTox1 is governed by the Snn1 gene on chromosome 1B in wheat. SnToxA is encoded by a gene with a high degree of similarity to the Ptr ToxA gene. Here, we evaluate toxin sensitivity and resistance to S. nodorum blotch (SNB) caused by Sn2000 in a recombinant inbred population that does not segregate for Snn1. Sensitivity to the Sn2000 toxin preparation cosegregated with sensitivity to Ptr ToxA at the Tsn1 locus. Tsn1-disrupted mutants were insensitive to both Ptr ToxA and SnToxA, suggesting that the 2 toxins are functionally similar, because they recognize the same locus in the host to induce necrosis. The locus harboring the tsn1 allele underlies a major quantitative trait locus (QTL) for resistance to SNB caused by Sn2000, and explains 62% of the phenotypic variation, indicating that the toxin is an important virulence factor for this fungus. The Tsn1 locus and several minor QTLs together explained 77% of the phenotypic variation. Therefore, the Tsn1-ToxA interaction in the wheat-S. nodorum pathosystem parallels that of the wheat-tan spot system, and the wheat Tsn1 gene serves as a major determinant for susceptibility to both SNB and tan spot.

Published

2006

29. Genomic constitution and variation in five partial amphiploids of wheat--Thinopyrum intermedium as revealed by GISH, multicolor GISH and seed storage protein analysis.

Author

Han F, Liu B, Fedak G, and Liu Z

Subjects

Breeding methods, Fluorescence, Gene Transfer Techniques, Gliadin genetics, Gliadin metabolism, Glutens genetics, Glutens metabolism, In Situ Hybridization methods, Ploidies, Triticum metabolism, Chromosomes, Plant genetics, Genetic Variation, Genome, Plant, Glutens analogs & derivatives, Hybridization, Genetic, Seeds metabolism, Triticum genetics

Abstract

Genomic in situ hybridization (GISH) and multicolor GISH (mcGISH) methodology were used to establish the cytogenetic constitution of five partial amphiploid lines obtained from wheat x Thinopyrum intermedium hybridizations. Line Zhong 1, 2 n=52, contained 14 chromosomes from each of the wheat genomes plus ten Th. intermedium chromosomes, with one pair of A-genome chromosomes having a Th. intermedium chromosomal segment translocated to the short arm. Line Zhong 2, 2 n=54, had intact ABD wheat genome chromosomes plus 12 Th. intermedium chromosomes. The multicolor GISH results, using different fluorochrome labeled Th. intermedium and the various diploid wheat genomic DNAs as probes, indicated that both Zhong 1 and Zhong 2 contained one pair of Th. intermedium chromosomes with a significant homology to the wheat D genome. High-molecular-weight (HMW) glutenin and gliadin analysis revealed that Zhong 1 and Zhong 2 had identical banding patterns that contained all of the wheat bands and a specific HMW band from Th. intermedium. Zhong 1 and Zhong 2 had good HMW subunits for wheat breeding. Zhong 3 and Zhong 5, both 2 n=56, possessed no gross chromosomal aberrations or translocations that were detectable at the GISH level. Zhong 4 also had a chromosome number of 2 n=56 and contained the complete wheat ABD-genome chromosomes plus 14 Th. intermedium chromosomes, with one pair of Th. intermedium chromosomes being markedly smaller. Multicolor GISH results indicated that Zhong 4 also contained two pairs of reciprocally translocated chromosomes involving the A and D genomes. Zhong 3, Zhong 4 and Zhong 5 contained a specific gliadin band from Th. intermedium. Based on the above data, it was concluded that inter-genomic transfer of chromosomal segments and/or sequence introgression had occurred in these newly synthesized partial amphiploids despite their diploid-like meiotic behavior and disomic inheritance.

Published

2004

30. Genomic Analysis and Delineation of the Tan Spot Susceptibility Locus Tsc1 in Wheat.

Author

Running, Katherine L. D., Momotaz, Aliya, Kariyawasam, Gayan K., Zurn, Jason D., Acevedo, Maricelis, Carter, Arron H., Liu, Zhaohui, and Faris, Justin D.

Subjects

GENOMICS, MOLECULAR cloning, GENE mapping, GENETIC markers, LOCUS (Genetics)

Abstract

The necrotrophic fungal pathogen Pyrenophora tritici-repentis (Ptr) causes the foliar disease tan spot in both bread wheat and durum wheat. Wheat lines carrying the tan spot susceptibility gene Tsc1 are sensitive to the Ptr -produced necrotrophic effector (NE) Ptr ToxC. A compatible interaction results in leaf chlorosis, reducing yield by decreasing the photosynthetic area of leaves. Developing genetically resistant cultivars will effectively reduce disease incidence. Toward that goal, the production of chlorosis in response to inoculation with Ptr ToxC-producing isolates was mapped in two low-resolution biparental populations derived from LMPG-6 × PI 626573 (LP) and Louise × Penawawa (LouPen). In total, 58 genetic markers were developed and mapped, delineating the Tsc1 candidate gene region to a 1.4 centiMorgan (cM) genetic interval spanning 184 kb on the short arm of chromosome 1A. A total of nine candidate genes were identified in the Chinese Spring reference genome, seven with protein domains characteristic of resistance genes. Mapping of the chlorotic phenotype, development of genetic markers, both for genetic mapping and marker-assisted selection (MAS), and the identification of Tsc1 candidate genes provide a foundation for map-based cloning of Tsc1. [ABSTRACT FROM AUTHOR]

Published

2022