Your search keyword '"Friesen, Timothy L"' showing total 433 results

51. The Barley HvWRKY6 Transcription Factor Is Required for Resistance Against Pyrenophora teres f. teres.

Author

Tamang, Prabin, Richards, Jonathan K., Solanki, Shyam, Ameen, Gazala, Sharma Poudel, Roshan, Deka, Priyanka, Effertz, Karl, Clare, Shaun J., Hegstad, Justin, Bezbaruah, Achintya, Li, Xuehui, Horsley, Richard D., Friesen, Timothy L., and Brueggeman, Robert S.

Subjects

TRANSCRIPTION factors, BARLEY, PYRENOPHORA, WHEAT diseases & pests, CLIMATE change, DISTILLING industries, HERBICIDE resistance

Abstract

Barley is an important cereal crop worldwide because of its use in the brewing and distilling industry. However, adequate supplies of quality malting barley are threatened by global climate change due to drought in some regions and excess precipitation in others, which facilitates epidemics caused by fungal pathogens. The disease net form net blotch caused by the necrotrophic fungal pathogen Pyrenophora teres f. teres (Ptt) has emerged as a global threat to barley production and diverse populations of Ptt have shown a capacity to overcome deployed genetic resistances. The barley line CI5791 exhibits remarkably effective resistance to diverse Ptt isolates from around the world that maps to two major QTL on chromosomes 3H and 6H. To identify genes involved in this effective resistance, CI5791 seed were γ-irradiated and two mutants, designated CI5791-γ3 and CI5791-γ8, with compromised Ptt resistance were identified from an M2 population. Phenotyping of CI5791-γ3 and -γ8 × Heartland F2 populations showed three resistant to one susceptible segregation ratios and CI5791-γ3 × -γ8 F1 individuals were susceptible, thus these independent mutants are in a single allelic gene. Thirty-four homozygous mutant (susceptible) CI5791-γ3 × Heartland F2 individuals, representing 68 recombinant gametes, were genotyped via PCR genotype by sequencing. The data were used for single marker regression mapping placing the mutation on chromosome 3H within an approximate 75 cM interval encompassing the 3H CI5791 resistance QTL. Sequencing of the mutants and wild-type (WT) CI5791 genomic DNA following exome capture identified independent mutations of the HvWRKY6 transcription factor located on chromosome 3H at ∼50.7 cM, within the genetically delimited region. Post transcriptional gene silencing of HvWRKY6 in barley line CI5791 resulted in Ptt susceptibility, confirming that it functions in NFNB resistance, validating it as the gene underlying the mutant phenotypes. Allele analysis and transcript regulation of HvWRKY6 from resistant and susceptible lines revealed sequence identity and upregulation upon pathogen challenge in all genotypes analyzed, suggesting a conserved transcription factor is involved in the defense against the necrotrophic pathogen. We hypothesize that HvWRKY6 functions as a conserved signaling component of defense mechanisms that restricts Ptt growth in barley. [ABSTRACT FROM AUTHOR]

Published

2021

52. Plant genes hijacked by necrotrophic fungal pathogens.

Author

Faris, Justin D and Friesen, Timothy L

Subjects

*PLANT genes, *APOPTOSIS, *PHYTOPATHOGENIC microorganisms, *DOMINANCE (Genetics), *PATHOGENIC microorganisms

Abstract

Plant fungal pathogens can be classified according to their lifestyles. Biotrophs feed on living tissue and constitute an economically significant group of pathogens historically. Necrotrophs, which feed on dead tissue, have become economically significant over recent decades, especially those of the Dothideomycetes , which produce necrotrophic effectors (NEs) to modulate the host response. Some of these pathogens interact with their hosts in an inverse gene-for-gene manner, where NEs are recognized by specific dominant genes in the host leading to host-mediated programmed cell death allowing the pathogen to cause disease. Whereas the NE genes tend to be unique, several of the plant 'susceptibility' genes belong to the nucleotide-binding leucine-rich repeat class of disease 'resistance' genes, and one is a wall-associated kinase. These susceptible interactions exhibit hallmarks of defense responses to biotrophic pathogens. Therefore, there is now accumulating evidence that many necrotrophic specialists hijack the resistance mechanisms that are effective against biotrophic pathogens. [ABSTRACT FROM AUTHOR]

Published

2020

53. Research advances in the Pyrenophora teres–barley interaction.

Author

Clare, Shaun J., Wyatt, Nathan A., Brueggeman, Robert S., and Friesen, Timothy L.

Subjects

BARLEY breeding, COMMUNITY life

Abstract

Summary: Pyrenophora teres f. teres and P. teres f. maculata are significant pathogens that cause net blotch of barley. An increased number of loci involved in P. teres resistance or susceptibility responses of barley as well as interacting P. teres virulence effector loci have recently been identified through biparental and association mapping studies of both the pathogen and host. Characterization of the resistance/susceptibility loci in the host and the interacting effector loci in the pathogen will provide a path for targeted gene validation for better‐informed release of resistant barley cultivars. This review assembles concise consensus maps for all loci published for both the host and pathogen, providing a useful resource for the community to be used in pathogen characterization and barley breeding for resistance to both forms of P. teres. [ABSTRACT FROM AUTHOR]

Published

2020

54. Combating the Sigatoka Disease Complex on Banana

Author

Friesen, Timothy L.

Subjects

Leaves, Crops, Bananas, Mycology, Plant Science, Pathology and Laboratory Medicine, Microbiology, Fruits, Ascomycota, Medicine and Health Sciences, Genetics, Fungal Genetics, Microbial Pathogens, Fungal Genomics, Fungicides, Plant Diseases, Fungal Pathogens, Plant Anatomy, Organisms, Fungal Diseases, Biology and Life Sciences, Computational Biology, Agriculture, Musa, Genomics, Plants, Genome Analysis, Infectious Diseases, Medical Microbiology, Perspective, Host-Pathogen Interactions, Pathogens, Agrochemicals, Crop Science

Published

2016

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

Author

Richards, Jonathan K., Stukenbrock, Eva H., Carpenter, Jessica, Liu, Zhaohui, Cowger, Christina, Faris, Justin D., and Friesen, Timothy L.

Subjects

APOPTOSIS, DURUM wheat, AGRICULTURAL diversification, WINTER wheat, WHEAT, DISEASE resistance of plants, GENOMICS

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. Parastagonospora nodorum is an economically important pathogen of wheat, employing proteinaceous effectors to cause disease. Recognition of effectors by host susceptibility genes often leads to the elicitation of programmed cell death. However, little is known on the correlation between effector diversity and the spatial distribution of host resistance/susceptibility or the genomic mechanisms of diversification. This research presents the genome resequencing of 197 P. nodorum isolates collected from spring, winter, and durum wheat production regions of the United States, enabling the investigation of genome dynamics and evolution. Results illustrate local adaptation to host resistance or susceptibility, as evidenced by population-specific evolution of predicted effector genes and positively selected selective sweeps. Predicted effector genes, genes exhibiting presence/absence variation, and genes residing on an accessory chromosome, were found to be diversifying more rapidly. Additionally, transposable elements were predicted to play a role in the maintenance or elimination of genes. A GWAS approach identified the previously reported SnToxA and SnTox3 as well as novel virulence candidates as major elicitors of disease. These results highlight the flexibility of the P. nodorum genome in response to population-specific selection pressures and illustrate the utility of whole genome resequencing for the identification of putative virulence mechanisms. [ABSTRACT FROM AUTHOR]

Published

2019

56. Genetics of Variable Disease Expression Conferred by Inverse Gene-For-Gene Interactions in the Wheat-Parastagonospora nodorum Pathosystem.

Author

Haugrud, Amanda R. Peters, Zengcui Zhang, Richards, Jonathan K., Friesen, Timothy L., and Faris, Justin D.

Published

2019

57. Genetic Diversity and Resistance to Fusarium Head Blight in Synthetic Hexaploid Wheat Derived From Aegilops tauschii and Diverse Triticum turgidum Subspecies.

Author

Szabo-Hever, Agnes, Zhang, Qijun, Friesen, Timothy L., Zhong, Shaobin, Elias, Elias M., Cai, Xiwen, Jin, Yue, Faris, Justin D., Chao, Shiaoman, and Xu, Steven S.

Subjects

EMMER wheat, WHEAT genetics, SINGLE nucleotide polymorphisms

Abstract

Synthetic hexaploid wheat (SHW) can serve as a bridge for the transfer of useful genes from Aegilops tauschii and tetraploid wheat (Triticum turgidum) into common wheat (T. aestivum). The objective of this study was to evaluate 149 SHW lines and their 74 tetraploid parents for their genetic diversity, breeding values and inter-genomic interactions for resistance to Fusarium head blight (FHB). The genetic diversity analysis was performed based on the population structure established using 4,674 and 3,330 polymorphic SNP markers among the SHW lines and tetraploid parents, respectively. The results showed that all T. carthlicum and most T. dicoccum accessions formed different clusters and subpopulations, respectively, whereas all the T. durum , T. polonicum , T. turgidum , and T. turanicum accessions were clustered together, suggesting that T. durum was more closely related to T. polonicum , T. turgidum , and T. turanicum than to T. dicoccum. The genetic diversity of the SHW lines mainly reflected that of the tetraploid parents. The SHW lines and their tetraploid parents were evaluated for reactions to FHB in two greenhouse seasons and at two field nurseries for 2 years. As expected, most of the SHW lines were more resistant than their tetraploid parents in all environments. The FHB severities of the SHW lines varied greatly depending on the Ae. tauschii and tetraploid genotypes involved. Most of the SHW lines with a high level of FHB resistance were generally derived from the tetraploid accessions with a high level of FHB resistance. Among the 149 SHW lines, 140 were developed by using three Ae. tauschii accessions CIae 26, PI 268210, and RL 5286. These SHW lines showed FHB severities reduced by 21.7%, 17.3%, and 11.5%, respectively, with an average reduction of 18.3%, as compared to the tetraploid parents, suggesting that the D genome may play a major role in reducing disease severity in the SHW lines. Thirteen SHW lines consistently showed a high level of FHB resistance compared to the resistant check, Sumai 3, in each environment. These SHW lines will be useful for the development of FHB-resistant wheat germplasm and populations for discovery of novel FHB resistance genes. [ABSTRACT FROM AUTHOR]

Published

2018

58. Necrotrophic effector‐triggered susceptibility (NETS) underlies the barley–Pyrenophora teres f. teres interaction specific to chromosome 6H

Author

Liu, Zhaohui, Holmes, Danielle J., Faris, Justin D., Chao, Shiaoman, Brueggeman, Robert S., Edwards, Michael C., and Friesen, Timothy L.

Subjects

Ascomycota, Quantitative Trait Loci, food and beverages, Hordeum, Original Articles, Reactive Oxygen Species, Plant Diseases

Abstract

Barley net form net blotch (NFNB), caused by the necrotrophic fungus Pyrenophora teres f. teres, is a destructive foliar disease in barley-growing regions worldwide. Little is known about the genetic and molecular basis of this pathosystem. Here, we identified a small secreted proteinaceous necrotrophic effector (NE), designated PttNE1, from intercellular wash fluids of the susceptible barley line Hector after inoculation with P. teres f. teres isolate 0-1. Using a barley recombinant inbred line (RIL) population developed from a cross between the sensitive/susceptible line Hector and the insensitive/resistant line NDB 112 (HN population), sensitivity to PttNE1, which we have named SPN1, mapped to a common resistance/susceptibility region on barley chromosome 6H. PttNE1-SPN1 interaction accounted for 31% of the disease variation when the HN population was inoculated with the 0-1 isolate. Strong accumulation of hydrogen peroxide and increased levels of electrolyte leakage were associated with the susceptible reaction, but not the resistant reaction. In addition, the HN RIL population was evaluated for its reactions to 10 geographically diverse P. teres f. teres isolates. Quantitative trait locus (QTL) mapping led to the identification of at least 10 genomic regions associated with disease, with chromosomes 3H and 6H harbouring major QTLs for resistance/susceptibility. SPN1 was associated with all the 6H QTLs, except one. Collectively, this information indicates that the barley-P. teres f. teres pathosystem follows, at least partially, an NE-triggered susceptibility (NETS) model that has been described in other necrotrophic fungal disease systems, especially in the Dothideomycete class of fungi.

Published

2014

59. A dimeric PR‐1‐type pathogenesis‐related protein interacts with ToxA and potentially mediates ToxA‐induced necrosis in sensitive wheat

Author

Lu, Shunwen, Faris, Justin D., Sherwood, Robert, Friesen, Timothy L., and Edwards, Michael C.

Subjects

DNA, Complementary, Two-Hybrid System Techniques, Molecular Sequence Data, Electrophoresis, Polyacrylamide Gel, Original Articles, Asparagine, Dimerization, Triticum, Plant Proteins, Protein Binding

Abstract

A dimeric PR‐1‐type pathogenesis‐related protein (PR‐1‐5), recently identified in wheat, was found to interact with Stagonospora nodorum ToxA in both yeast two‐hybrid and co‐immunoprecipitation assays. Site‐specific mutational analyses revealed that the RGD motif of ToxA is not targeted by PR‐1‐5, whereas two surface‐exposed asparagine residues are essential for the interaction: the N102 residue of the turning loop between β2 and β3 in ToxA and the N141 residue of the turning loop between βC and βD in PR‐1‐5. Recombinant PR‐1‐5 and ToxA mutant proteins carrying alanine substitutions at the interacting sites were expressed in Pichia pastoris, together with the wild‐type proteins. Native polyacrylamide gel electrophoresis (PAGE) confirmed that the PR‐1‐5‐N141A mutant retains the ability to form dimers. Plant assays indicated that the ToxA‐N102A mutant fails to induce necrosis, whereas the PR‐1‐5‐N141A mutant is impaired in the ‘necrosis‐promoting’ activity shown by the wild‐type PR‐1‐5 when co‐infiltrated with ToxA in sensitive wheat. Reverse transcriptase‐polymerase chain reaction and Western blot analyses revealed that the native PR‐1‐5 protein is differentially expressed between ToxA‐sensitive and ToxA‐insensitive wheat lines in response to ToxA treatment. These results suggest that PR‐1‐5 is a potential target of ToxA and the site‐specific interaction between PR‐1‐5 and ToxA may mediate ToxA‐induced necrosis in sensitive wheat.

Published

2014

60. Transposable Element Genomic Fissuring in Pyrenophora teres Is Associated With Genome Expansion and Dynamics of Host--Pathogen Genetic Interactions.

Author

Syme, Robert A., Martin, Anke, Wyatt, Nathan A., Lawrence, Julie A., Muria-Gonzalez, Mariano J., Friesen, Timothy L., and Ellwood, Simon R.

Subjects

BARLEY net-spot blotch disease, PLANT DNA, HOST-parasite relationships

Abstract

Pyrenophora teres, P. teres f. teres (PTT) and P. teres f. maculata (PTM) cause significant diseases in barley, but little is known about the large-scale genomic differences that may distinguish the two forms. Comprehensive genome assemblies were constructed from long DNA reads, optical and genetic maps. As repeat masking in fungal genomes influences the final gene annotations, an accurate and reproducible pipeline was developed to ensure comparability between isolates. The genomes of the two forms are highly collinear, each composed of 12 chromosomes. Genome evolution in P. teres is characterized by genome fissuring through the insertion and expansion of transposable elements (TEs), a process that isolates blocks of genic sequence. The phenomenon is particularly pronounced in PTT, which has a larger, more repetitive genome than PTM and more recent transposon activity measured by the frequency and size of genome fissures. PTT has a longer cultivated host association and, notably, a greater range of host--pathogen genetic interactions compared to other Pyrenophora spp., a property which associates better with genome size than pathogen lifestyle. The two forms possess similar complements of TE families with Tc1/Mariner and LINE-like Tad-1 elements more abundant in PTT. Tad-1 was only detectable as vestigial fragments in PTM and, within the forms, differences in genome sizes and the presence and absence of several TE families indicated recent lineage invasions. Gene differences between P. teres forms are mainly associated with gene-sparse regions near or within TE-rich regions, with many genes possessing characteristics of fungal effectors. Instances of gene interruption by transposons resulting in pseudogenization were detected in PTT. In addition, both forms have a large complement of secondary metabolite gene clusters indicating significant capacity to produce an array of different molecules. This study provides genomic resources for functional genetics to help dissect factors underlying the host--pathogen interactions. [ABSTRACT FROM AUTHOR]

Published

2018

61. SnTox5–Snn5: a novel Stagonospora nodorum effector–wheat gene interaction and its relationship with the SnToxA–Tsn1 and SnTox3–Snn3–B1 interactions

Author

Friesen, Timothy l., Chu, Chenggen, Xu, Steven S., and Faris, Justin D.

Subjects

Genotype, Genes, Fungal, Quantitative Trait Loci, Chromosome Mapping, Original Articles, Haploidy, Genes, Plant, Fungal Proteins, Ascomycota, Host-Pathogen Interactions, Regression Analysis, Alleles, Crosses, Genetic, Triticum, Plant Diseases

Abstract

The Stagonospora nodorum-wheat interaction involves multiple pathogen-produced necrotrophic effectors that interact directly or indirectly with specific host gene products to induce the disease Stagonospora nodorum blotch (SNB). Here, we used a tetraploid wheat mapping population to identify and characterize a sixth effector-host gene interaction in the wheat-S. nodorum system. Initial characterization of the effector SnTox5 indicated that it is a proteinaceous necrotrophic effector that induces necrosis on host lines harbouring the Snn5 sensitivity gene, which was mapped to the long arm of wheat chromosome 4B. On the basis of ultrafiltration, SnTox5 is probably in the size range 10-30 kDa. Analysis of SNB development in the mapping population indicated that the SnTox5-Snn5 interaction explains 37%-63% of the variation, demonstrating that this interaction plays a significant role in disease development. When the SnTox5-Snn5 and SnToxA-Tsn1 interactions occurred together, the level of SNB was increased significantly. Similar to several other interactions in this system, the SnTox5-Snn5 interaction is light dependent, suggesting that multiple interactions may exploit the same pathways to cause disease.

Published

2012

62. Transcriptome analysis of Stagonospora nodorum: gene models, effectors, metabolism and pantothenate dispensability

Author

IPCHO, SIMON V. S., HANE, JAMES K., ANTONI, EVA A., AHREN, DAG, HENRISSAT, BERNARD, FRIESEN, TIMOTHY L., SOLOMON, PETER S., and OLIVER, RICHARD P.

Subjects

Fungal Proteins, Ascomycota, Gene Expression Profiling, Gene Expression Regulation, Fungal, food and beverages, Original Articles, Triticum, Plant Diseases

Abstract

The wheat pathogen Stagonospora nodorum, causal organism of the wheat disease Stagonospora nodorum blotch, has emerged as a model for the Dothideomycetes, a large fungal taxon that includes many important plant pathogens. The initial annotation of the genome assembly included 16,586 nuclear gene models. These gene models were used to design a microarray that has been interrogated with labelled transcripts from six cDNA samples: four from infected wheat plants at time points spanning early infection to sporulation, and two time points taken from growth in artificial media. Positive signals of expression were obtained for 12,281 genes. This represents strong corroborative evidence of the validity of these gene models. Significantly differential expression between the various time points was observed. When infected samples were compared with axenic cultures, 2882 genes were expressed at a higher level in planta and 3630 were expressed more highly in vitro. Similar numbers were differentially expressed between different developmental stages. The earliest time points in planta were particularly enriched in differentially expressed genes. A disproportionate number of the early expressed gene products were predicted to be secreted, but otherwise had no obvious sequence homology to functionally characterized genes. These genes are candidate necrotrophic effectors. We have focused attention on genes for carbohydrate metabolism and the specific biosynthetic pathways active during growth in planta. The analysis points to a very dynamic adjustment of metabolism during infection. Functional analysis of a gene in the coenzyme A biosynthetic pathway showed that the enzyme was dispensable for growth, indicating that a precursor is supplied by the plant.

Published

2011

63. Pyrenophora teres: profile of an increasingly damaging barley pathogen

Author

LIU, ZHAOHUI, ELLWOOD, SIMON R., OLIVER, RICHARD P., and FRIESEN, TIMOTHY L.

Subjects

Ascomycota, Species Specificity, Virulence, Host-Pathogen Interactions, Quantitative Trait Loci, Pathogen Profile, Hordeum, Genomics, Mycotoxins, Genes, Plant, Plant Diseases

Abstract

Pyrenophora teres, causal agent of net blotch of barley, exists in two forms, designated P. teres f. teres and P. teres f. maculata, which induce net form net blotch (NFNB) and spot form net blotch (SFNB), respectively. Significantly more work has been performed on the net form than on the spot form although recent activity in spot form research has increased because of epidemics of SFNB in barley‐producing regions. Genetic studies have demonstrated that NFNB resistance in barley is present in both dominant and recessive forms, and that resistance/susceptibility to both forms can be conferred by major genes, although minor quantitative trait loci have also been identified. Early work on the virulence of the pathogen showed toxin effector production to be important in disease induction by both forms of pathogen. Since then, several laboratories have investigated effectors of virulence and avirulence, and both forms are complex in their interaction with the host. Here, we assemble recent information from the literature that describes both forms of this important pathogen and includes reports describing the host–pathogen interaction with barley. We also include preliminary findings from a genome sequence survey. Taxonomy: Pyrenophora teres Drechs. Kingdom Fungi; Phylum Ascomycota; Subphylum Pezizomycotina; Class Dothideomycete; Order Pleosporales; Family Pleosporaceae; Genus Pyrenophora, form teres and form maculata. Identification: To date, no clear morphological or life cycle differences between the two forms of P. teres have been identified, and therefore they are described collectively. Towards the end of the growing season, the fungus produces dark, globosely shaped pseudothecia, about 1–2 mm in diameter, on barley. Ascospores measuring 18–28 µm × 43–61 µm are light brown and ellipsoidal and often have three to four transverse septa and one or two longitudinal septa in the median cells. Conidiophores usually arise singly or in groups of two or three and are lightly swollen at the base. Conidia measuring 30–174 µm × 15–23 µm are smoothly cylindrical and straight, round at both ends, subhyaline to yellowish brown, often with four to six pseudosepta. Morphologically, P. teres f. teres and P. teres f. maculata are indistinguishable. Host range: Comprehensive work on the host range of P. teres f. teres has been performed; however, little information on the host range of P. teres f. maculata is available. Hordeum vulgare and H. vulgare ssp. spontaneum are considered to be the primary hosts for P. teres. However, natural infection by P. teres has been observed in other wild Hordeum species and related species from the genera Bromus, Avena and Triticum, including H. marinum, H. murinum, H. brachyantherum, H. distichon, H. hystrix, B. diandrus, A. fatua, A. sativa and T. aestivum (Shipton et al., 1973, Rev. Plant Pathol. 52:269–290). In artificial inoculation experiments under field conditions, P. teres f. teres has been shown to infect a wide range of gramineous species in the genera Agropyron, Brachypodium, Elymus, Cynodon, Deschampsia, Hordelymus and Stipa (Brown et al., 1993, Plant Dis. 77:942–947). Additionally, 43 gramineous species were used in a growth chamber study and at least one of the P. teres f. teres isolates used was able to infect 28 of the 43 species tested. However, of these 28 species, 14 exhibited weak type 1 or 2 reactions on the NFNB 1–10 scale (Tekauz, 1985). These reaction types are small pin‐point lesions and could possibly be interpreted as nonhost reactions. In addition, the P. teres f. teres host range was investigated under field conditions by artificially inoculating 95 gramineous species with naturally infected barley straw. Pyrenophora teres f. teres was re‐isolated from 65 of the species when infected leaves of adult plants were incubated on nutrient agar plates; however, other than Hordeum species, only two of the 65 host species exhibited moderately susceptible or susceptible field reaction types, with most species showing small dark necrotic lesions indicative of a highly resistant response to P. teres f. teres. Although these wild species have the potential to be alternative hosts, the high level of resistance identified for most of the species makes their role as a source of primary inoculum questionable. Disease symptoms: Two types of symptom are caused by P. teres. These are net‐type lesions caused by P. teres f. teres and spot‐type lesions caused by P. teres f. maculata. The net‐like symptom, for which the disease was originally named, has characteristic narrow, dark‐brown, longitudinal and transverse striations on infected leaves. The spot form symptom consists of dark‐brown, circular to elliptical lesions surrounded by a chlorotic or necrotic halo of varying width.

Published

2010

64. Hybrid inferiority and genetic incompatibilities drive divergence of fungal pathogens infecting the same host

Author

Yuzon, Jennifer D, Wyatt, Nathan A, Vasighzadeh, Asieh, Clare, Shaun, Navratil, Emma, Friesen, Timothy L, and Stukenbrock, Eva H

Abstract

Agro-ecosystems provide environments that are conducive for rapid evolution and dispersal of plant pathogens. Previous studies have demonstrated that hybridization of crop pathogens can give rise to new lineages with altered virulence profiles. Currently, little is known about either the genetics of fungal pathogen hybridization or the mechanisms that may prevent hybridization between related species. The fungus Pyrenophora teresis a global pathogen of barley. The pathogenic fungus P. teresexists as two distinct lineages P. teresf. teresand P. teresf. maculata(Pttand Ptm, respectively), which both infect barley but produce very distinct lesions and rarely interbreed. Interestingly, Pttand Ptmcan, by experimental mating, produce viable progenies. Here, we addressed the underlying genetics of reproductive barriers of P. teres. We hypothesize that Pttand Ptmdiverged in the past, possibly by adapting to distinct hosts, and only more recently colonized the same host in agricultural fields. Using experimental mating and in plantaphenotyping in barley cultivars susceptible to both P. teresforms, we demonstrate that hybrids produce mixed infection phenotypes but overall show inferior pathogenic fitness relative to the pure parents. Based on analyses of 104 hybrid genomes, we identify signatures of negative epistasis between parental alleles at distinct loci (Dobzhansky–Müller incompatibilities). Most DMI regions are not involved in virulence but certain genes are predicted or known to play a role in virulence. These results potentially suggest that divergent niche adaptation—albeit in the same host plant—contributes to speciation in P. teres.

Published

2023

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

Author

Liu, Zhaohui, Zhang, Zengcui, Faris, Justin D., Oliver, Richard P., Syme, Robert, McDonald, Megan C., McDonald, Bruce A., Solomon, Peter S., Lu, Shunwen, Shelver, Weilin L., Xu, Steven, Friesen, Timothy L., Liu, Zhaohui, Zhang, Zengcui, Faris, Justin D., Oliver, Richard P., Syme, Robert, McDonald, Megan C., McDonald, Bruce A., Solomon, Peter S., Lu, Shunwen, Shelver, Weilin L., Xu, Steven, and Friesen, Timothy L.

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

Published

2012

66. SnTox3 Acts in Effector Triggered Susceptibility to Induce Disease on Wheat Carrying the Snn3 Gene

Author

Liu, Zhaohui, Faris, Justin D., Oliver, Richard P., Tan, Kar-Chun, Solomon, Peter S., McDonald, Megan C., McDonald, Bruce A., Nunez, Alberto, Lu, Shunwen, Rasmussen, Jack B., Friesen, Timothy L., Liu, Zhaohui, Faris, Justin D., Oliver, Richard P., Tan, Kar-Chun, Solomon, Peter S., McDonald, Megan C., McDonald, Bruce A., Nunez, Alberto, Lu, Shunwen, Rasmussen, Jack B., and Friesen, Timothy L.

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

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

Author

Liu, Zhaohui, Gao, Yuanyuan, Kim, Yong Min, Faris, Justin D., Shelver, Weilin L., Wit, Pierre J. G. M., Xu, Steven S., and Friesen, Timothy L.

Subjects

CHITIN, TOXINS, APOPTOSIS, WHEAT, CHITINASE

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. [ABSTRACT FROM AUTHOR]

Published

2016

68. Genotype-by-sequencing of the plant-pathogenic fungi Pyrenophora teres and Sphaerulina musiva utilizing Ion Torrent sequence technology.

Author

Leboldus, Jared M., Kinzer, Kasia, Richards, Jonathan, Ya, Zhu, Yan, Changhui, Friesen, Timothy L., and Brueggeman, Robert

Subjects

PYRENOPHORA teres, SEPTORIA musiva, PLANT genetics, HOST-parasite relationships, DISEASE resistance of plants, MICROBIAL virulence

Abstract

Genetic and genomics tools to characterize host-pathogen interactions are disproportionately directed to the host because of the focus on resistance. However, understanding the genetics of pathogen virulence is equally important and has been limited by the high cost of de novo genotyping of species with limited marker data. Non-resource-prohibitive methods that overcome the limitation of genotyping are now available through genotype-by-sequencing ( GBS). The use of a two-enzyme restriction-associated DNA ( RAD)- GBS method adapted for Ion Torrent sequencing technology provided robust and reproducible high-density genotyping of several fungal species. A total of 5783 and 2373 unique loci, 'sequence tags', containing 16 441 and 9992 single nucleotide polymorphisms ( SNPs) were identified and characterized from natural populations of Pyrenophora teres f. maculata and Sphaerulina musiva, respectively. The data generated from the P. teres f. maculata natural population were used in association mapping analysis to map the mating-type gene to high resolution. To further validate the methodology, a biparental population of P. teres f. teres, previously used to develop a genetic map utilizing simple sequence repeat ( SSR) and amplified fragment length polymorphism ( AFLP) markers, was re-analysed using the SNP markers generated from this protocol. A robust genetic map containing 1393 SNPs on 997 sequence tags spread across 15 linkage groups with anchored reference markers was generated from the P. teres f. teres biparental population. The robust high-density markers generated using this protocol will allow positional cloning in biparental fungal populations, association mapping of natural fungal populations and population genetics studies. [ABSTRACT FROM AUTHOR]

Published

2015

69. Necrotrophic effector-triggered susceptibility ( NETS) underlies the barley- Pyrenophora teres f. teres interaction specific to chromosome 6H.

Author

Liu, Zhaohui, Holmes, Danielle J., Faris, Justin D., Chao, Shiaoman, Brueggeman, Robert S., Edwards, Michael C., and Friesen, Timothy L.

Subjects

BARLEY net-spot blotch disease, PYRENOPHORA teres, PLANT chromosomes, PLANT populations, HYDROGEN peroxide, DOTHIDEOMYCETES

Abstract

Barley net form net blotch ( NFNB), caused by the necrotrophic fungus Pyrenophora teres f. teres, is a destructive foliar disease in barley-growing regions worldwide. Little is known about the genetic and molecular basis of this pathosystem. Here, we identified a small secreted proteinaceous necrotrophic effector ( NE), designated PttNE1, from intercellular wash fluids of the susceptible barley line Hector after inoculation with P. teres f. teres isolate 0-1. Using a barley recombinant inbred line (RIL) population developed from a cross between the sensitive/susceptible line Hector and the insensitive/resistant line NDB 112 ( HN population), sensitivity to PttNE1, which we have named SPN1, mapped to a common resistance/susceptibility region on barley chromosome 6H. PttNE1- SPN1 interaction accounted for 31% of the disease variation when the HN population was inoculated with the 0-1 isolate. Strong accumulation of hydrogen peroxide and increased levels of electrolyte leakage were associated with the susceptible reaction, but not the resistant reaction. In addition, the HN RIL population was evaluated for its reactions to 10 geographically diverse P. teres f. teres isolates. Quantitative trait locus ( QTL) mapping led to the identification of at least 10 genomic regions associated with disease, with chromosomes 3H and 6H harbouring major QTLs for resistance/susceptibility. SPN1 was associated with all the 6H QTLs, except one. Collectively, this information indicates that the barley- P. teres f. teres pathosystem follows, at least partially, an NE-triggered susceptibility ( NETS) model that has been described in other necrotrophic fungal disease systems, especially in the Dothideomycete class of fungi. [ABSTRACT FROM AUTHOR]

Published

2015

70. Characterization of Thinopyrum Species for Wheat Stem Rust Resistance and Ploidy Level.

Author

Qi Zheng, Klindworth, Daryl L., Friesen, Timothy L., Ai-Feng Liu, Zhen-Sheng Li, Shaobin Zhong, Yue Jin, and Xu, Steven S.

Subjects

WHEATGRASS (Wheat), PUCCINIA graminis, WHEAT stem rusts, DISEASE resistance of plants, WHEAT genetics

Abstract

In the tribe Triticeae, several Thinopyrum species have been used as sources of resistance to stem rust (caused by Puccinia graminis Pers.:Pers. f. sp. tritici Eriks. & E. Henn., abbreviated as Pgt) and other wheat (Triticum aestivum L.) diseases. To identify novel sources of resistance to Pgt race TTKSK (Ug99), we evaluated and characterized the stem rust resistance of 242 accessions belonging to five Thinopyrum species, including beach wheatgrass [Th. bessarabicum (Savul. & Rayss) A. Löve], diploid tall wheatgrass [Th. elongatum (Host) D.R. Dewey], intermediate wheatgrass [Th. intermedium (Host) Barkworth & D. R. Dewey], sand cough or sea wheatgrass [Th. junceum (L.) A. Löve], and decaploid tall wheatgrass [Th. ponticum (Podp.) Barkworth & D.R. Dewey]. These accessions were evaluated for seedling reactions to nine Pgt races (TTKSK, TTTTF, TRTTF, RTQQC, QFCSC, TCMJC, TPMKC, TMLKC, and TPP KC), genotyped with molecular markers linked to four stem rust resistance genes (Sr24, Sr25, Sr26, and Sr43) derived from Thinopyrum species, and examined for ploidy levels. All accessions but one (Th. elongatum PI 531718) were resistant to all or most races. Most of the Th. elongatum and Th. ponticum accessions showed near-immunity to all of the races while the accessions of the other three species (Th. bessarabicum, Th. intermedium, and Th. junceum) had varied levels of resistance ranging from near immunity to moderate resistance. Molecular marker analysis showed that most of the markers appeared to be species- or genusspecific rather than linked to a gene of interest, and thus genotyping analysis was of limited value. Comparisons of infection types of accessions based on ploidy level suggested that higher ploidy level was associated with higher levels of stem rust resistance. The results from this study substantiate that the Thinopyrum species are a rich source of stem rust resistance. [ABSTRACT FROM AUTHOR]

Published

2014

71. Polyethylene Glycol (PEG)-Mediated Transformation in Filamentous Fungal Pathogens.

Author

Liu, Zhaohui and Friesen, Timothy L.

Published

2012

72. Characterization of Plant-Fungal Interactions Involving Necrotrophic Effector-Producing Plant Pathogens.

Author

Friesen, Timothy L. and Faris, Justin D.

Published

2012

73. ‘Elgin‐ND’ Spring Wheat: A Newly Adapted Cultivar to the North‐Central Plains of the United States with High Agronomic and Quality Performance

Author

Mergoum, Mohamed, Simsek, Senay, Zhong, Shaobin, Acevedo, Maricelis, Friesen, Timothy L., Alamri, Mohammed S., Xu, Steven, and Liu, Zhaohui

Abstract

The spring wheat (Triticum aestivumL.) industry and growers usually value adapted wheat cultivars with high quality attributes, an essential criteria for maintaining wheat as a competitive commodity at the national and international levels. Therefore, the goal of the breeding program is to develop wheat cultivars that meet the above criteria using appropriate breeding tools. ‘Elgin‐ND’ (CV‐1116, PI 668099), a hard red spring wheat (HRSW) developed at North Dakota State University was released by the North Dakota Agricultural Experiment Station in 2013. Elgin‐ND, tested as experimental line ND818, was released because it is adapted to the US spring wheat growing conditions. It combines high yield potential with high protein and end‐use quality and has a good disease resistance package. This includes resistance to Fusarium head blight [caused by Fusarium graminearumSchwabe; teleomorph Gibberella zeae(Schwein.) Petch)]; leaf diseases including stem rust (caused by Puccinia graminisPers.:Pers. f. sp. triticiEriks. & E. Henn) and leaf rust (caused by Puccinia triticinaEriks.); tan spot [caused by Pyrenophora tritici‐repentis(Died.) Drechs]; and bacterial leaf blight (caused by Xanthomonas translucenspv. undulosa). However, Elgin‐ND relies heavily on the major Lr21gene that confers resistance to leaf rust. Thus, it is susceptible to the new race that overcomes the Lr21gene. The name Elgin‐ND was chosen for ND818 after a small town in western North Dakota, where the cultivar is expected to be widely planted.

Published

2016

74. Nicotiana benthamiana as a nonhost of Zymoseptoria tritici.

Author

Friesen, Timothy L.

Subjects

*DISEASE resistance of plants, *WHEAT disease & pest resistance, *WHEAT diseases & pests, *NICOTIANA benthamiana, *NICOTIANA

Abstract

This article is a Commentary on Kettles et al., 213: 338–350. [ABSTRACT FROM AUTHOR]

Published

2017

75. Characterization of ThinopyrumSpecies for Wheat Stem Rust Resistance and Ploidy Level

Author

Zheng, Qi, Klindworth, Daryl L., Friesen, Timothy L., Liu, Ai‐Feng, Li, Zhen‐Sheng, Zhong, Shaobin, Jin, Yue, and Xu, Steven S.

Abstract

In the tribe Triticeae, several Thinopyrumspecies have been used as sources of resistance to stem rust (caused by Puccinia graminisPers.:Pers. f. sp. triticiEriks. & E. Henn., abbreviated as Pgt) and other wheat (Triticum aestivumL.) diseases. To identify novel sources of resistance to Pgtrace TTKSK (Ug99), we evaluated and characterized the stem rust resistance of 242 accessions belonging to five Thinopyrumspecies, including beach wheatgrass [Th. bessarabicum(Savul. & Rayss) A. Löve], diploid tall wheatgrass [Th. elongatum(Host) D.R. Dewey], intermediate wheatgrass [Th. intermedium(Host) Barkworth & D. R. Dewey], sand cough or sea wheatgrass [Th. junceum(L.) A. Löve], and decaploid tall wheatgrass [Th. ponticum(Podp.) Barkworth & D.R. Dewey]. These accessions were evaluated for seedling reactions to nine Pgtraces (TTKSK, TTTTF, TRTTF, RTQQC, QFCSC, TCMJC, TPMKC, TMLKC, and TPPKC), genotyped with molecular markers linked to four stem rust resistance genes (Sr24, Sr25, Sr26, and Sr43) derived from Thinopyrumspecies, and examined for ploidy levels. All accessions but one (Th. elongatumPI 531718) were resistant to all or most races. Most of the Th. elongatumand Th. ponticumaccessions showed near‐immunity to all of the races while the accessions of the other three species (Th. bessarabicum, Th. intermedium, and Th. junceum) had varied levels of resistance ranging from near immunity to moderate resistance. Molecular marker analysis showed that most of the markers appeared to be species‐ or genus‐specific rather than linked to a gene of interest, and thus genotyping analysis was of limited value. Comparisons of infection types of accessions based on ploidy level suggested that higher ploidy level was associated with higher levels of stem rust resistance. The results from this study substantiate that the Thinopyrumspecies are a rich source of stem rust resistance.

Published

2014

76. Global diversity and distribution of three necrotrophic effectors in Phaeosphaeria nodorum and related species.

Author

McDonald, Megan C., Oliver, Richard P., Friesen, Timothy L., Brunner, Patrick C., and McDonald, Bruce A.

Subjects

WHEAT diseases & pests, PHYTOPATHOGENIC microorganisms, LOCUS (Genetics), POPULATION genetics, POLYMERASE chain reaction, FISHER exact test, GENETICS

Abstract

Population genetic and phylogenetic studies have shown that Phaeosphaeria nodorum is a member of a species complex that probably shares its center of origin with wheat ( Triticum aestivum and Triticum durum). We examined the evolutionary histories of three known necrotrophic effectors ( NEs) produced by P. nodorum and compared them with neutral loci., We screened over 1000 individuals for the presence/absence of each effector and assigned each individual to a multi-effector genotype. Diversity at each NE locus was assessed by sequencing c. 200 individuals for each locus., We found significant differences in effector frequency among populations. We propose that these differences reflect the presence/absence of the corresponding susceptibility gene in wheat cultivars. The population harboring the highest sequence diversity was different for each effector locus and never coincided with populations harboring the highest diversity at neutral loci. Coalescent and phylogenetic analyses showed a discontinuous presence of all three NEs among nine closely related Phaeosphaeria species. Only two of the nine species were found to harbor NEs., We present evidence that the three described NEs of P. nodorum were transmitted to its sister species, Phaeosphaeria avenaria tritici 1, via interspecific hybridization. [ABSTRACT FROM AUTHOR]

Published

2013

77. Stagonospora nodorum: From Pathology to Genomics and Host Resistance.

Author

Oliver, Richard P., Friesen, Timothy L., Faris, Justin D., and Solomon, Peter S.

Subjects

*STAGONOSPORA nodorum, *PLANT genomes, *DISEASE resistance of plants, *HOST-parasite relationships, *PLANT diseases, *FUNCTIONAL genomics, *PLEOSPORALES

Abstract

Stagonospora nodorum is a major necrotrophic pathogen of wheat that causes the diseases S. nodorum leaf and glume blotch. A series of tools and resources, including functional genomics, a genome sequence, proteomics and metabolomics, host-mapping populations, and a worldwide collection of isolates, have enabled the dissection of pathogenicity mechanisms. Metabolic and signaling genes required for pathogenicity have been defined. Interaction with the host is dominated by interplay of fungal effectors that induce necrosis on wheat lines carrying specific sensitivity loci. As such, the pathogen has emerged as a model for the Pleosporales group of pathogens. [ABSTRACT FROM AUTHOR]

Published

2012

78. Transcriptome analysis of Stagonospora nodorum: gene models, effectors, metabolism and pantothenate dispensability.

Author

IPCHO, SIMON V. S., HANE, JAMES K., ANTONI, EVA A., AHREN, DAG, HENRISSAT, BERNARD, FRIESEN, TIMOTHY L., SOLOMON, PETER S., and OLIVER, RICHARD P.

Subjects

STAGONOSPORA nodorum, PHYTOPATHOGENIC microorganisms, WHEAT diseases & pests, BLOTCH diseases, GENETIC models, ANTISENSE DNA, CARBOHYDRATE metabolism

Abstract

SUMMARY The wheat pathogen Stagonospora nodorum, causal organism of the wheat disease Stagonospora nodorum blotch, has emerged as a model for the Dothideomycetes, a large fungal taxon that includes many important plant pathogens. The initial annotation of the genome assembly included 16 586 nuclear gene models. These gene models were used to design a microarray that has been interrogated with labelled transcripts from six cDNA samples: four from infected wheat plants at time points spanning early infection to sporulation, and two time points taken from growth in artificial media. Positive signals of expression were obtained for 12 281 genes. This represents strong corroborative evidence of the validity of these gene models. Significantly differential expression between the various time points was observed. When infected samples were compared with axenic cultures, 2882 genes were expressed at a higher level in planta and 3630 were expressed more highly in vitro. Similar numbers were differentially expressed between different developmental stages. The earliest time points in planta were particularly enriched in differentially expressed genes. A disproportionate number of the early expressed gene products were predicted to be secreted, but otherwise had no obvious sequence homology to functionally characterized genes. These genes are candidate necrotrophic effectors. We have focused attention on genes for carbohydrate metabolism and the specific biosynthetic pathways active during growth in planta. The analysis points to a very dynamic adjustment of metabolism during infection. Functional analysis of a gene in the coenzyme A biosynthetic pathway showed that the enzyme was dispensable for growth, indicating that a precursor is supplied by the plant. [ABSTRACT FROM AUTHOR]

Published

2012

79. A functional genomics approach to dissect the mode of action of the Stagonospora nodorum effector protein SnToxA in wheat.

Author

VINCENT, DELPHINE, DU FALL, LAUREN A., LIVK, ANDREJA, MATHESIUS, ULRIKE, LIPSCOMBE, RICHARD J., OLIVER, RICHARD P., FRIESEN, TIMOTHY L., and SOLOMON, PETER S.

Subjects

FUNCTIONAL genomics, STAGONOSPORA nodorum, WHEAT, PHOTOSYNTHESIS, REACTIVE oxygen species, MALATE dehydrogenase, PHYTOPATHOGENIC microorganisms -- Molecular aspects

Abstract

SUMMARY In this study, proteomics and metabolomics were used to study the wheat response to exposure to the SnToxA effector protein secreted by the fungal pathogen Stagonospora nodorum during infection. Ninety-one different acidic and basic proteins and 101 metabolites were differentially abundant when comparing SnToxA- and control-treated wheat leaves during a 72-h time course. Proteins involved in photosynthesis were observed to increase marginally initially after exposure, before decreasing rapidly and significantly. Proteins and metabolites associated with the detoxification of reactive oxygen species in the chloroplast were also differentially abundant during SnToxA exposure, implying that the disruption of photosynthesis causes the rapid accumulation of chloroplastic reactive oxygen species. Metabolite profiling revealed major metabolic perturbations in central carbon metabolism, evidenced by significant increases in tricarboxylic acid (TCA) cycle intermediates, suggestive of an attempt by the plant to generate ATP and reducing equivalents in response to the collapse of photosynthesis caused by SnToxA. This was supported by the observation that the TCA cycle enzyme malate dehydrogenase was up-regulated in response to SnToxA. The infiltration of SnToxA also resulted in a significant increase in abundance of many pathogenicity-related proteins, even in the absence of the pathogen or other pathogen-associated molecular patterns. This approach highlights the complementary nature of proteomics and metabolomics in studying effector-host interactions, and provides further support for the hypothesis that necrotrophic pathogens, such as S. nodorum, appear to exploit existing host cell death mechanisms to promote pathogen growth and cause disease. [ABSTRACT FROM AUTHOR]

Published

2012

80. The Cysteine Rich Necrotrophic Effector SnTox1 Produced by Stagonospora nodorum Triggers Susceptibility of Wheat Lines Harboring Snn1.

Author

Zhaohui Liu, Zengcui Zhang, Faris, Justin D., Oliver, Richard P., Syme, Robert, McDonald, Megan C., McDonald, Bruce A., Solomon, Peter S., Shunwen Lu, Shelver, Weilin L., Xu, Steven, and Friesen, Timothy L.

Subjects

CYSTEINE, STAGONOSPORA, SPHAEROPSIDACEAE, PROTEINS, GENES

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. [ABSTRACT FROM AUTHOR]

Published

2012

81. RNA-mediated gene silencing in the cereal fungal pathogen Cochliobolus sativus.

Author

LENG, YUEQIANG, WU, CHENGXIANG, LIU, ZHAOHUI, FRIESEN, TIMOTHY L., RASMUSSEN, JACK B., and ZHONG, SHAOBIN

Subjects

PLANT gene silencing, GRAIN diseases & pests, COCHLIOBOLUS, PHYTOPATHOGENIC fungi in host plants, RNA, SMALL interfering RNA, TRANSGENE expression, FUNCTIONAL genomics

Abstract

A high-throughput RNA-mediated gene silencing system was developed for Cochliobolus sativus (anamorph: Bipolaris sorokiniana), the causal agent of spot blotch, common root rot and black point in barley and wheat. The green fluorescent protein gene ( GFP) and the proteinaceous host-selective toxin gene ( ToxA) were first introduced into C. sativus via the polyethylene glycol (PEG)-mediated transformation method. Transformants with a high level of expression of GFP or ToxA were generated. A silencing vector (pSGate1) based on the Gateway cloning system was developed and used to construct RNA interference (RNAi) vectors. Silencing of GFP and ToxA in the transformants was demonstrated by transformation with the RNAi construct expressing hairpin RNA (hpRNA) of the target gene. The polyketide synthase gene ( CsPKS1), involved in melanin biosynthesis pathways in C. sativus, was also targeted by transformation with the RNAi vector (pSGate1- CsPKS1) encoding hpRNA of the CsPKS1 gene. The transformants with pSGate1- CsPKS1 exhibited an albino phenotype or reduced melanization, suggesting effective silencing of the endogenous CsPKS1 in C. sativus. Sectors exhibiting the wild-type phenotype of the fungus appeared in some of the CsPKS1-silenced transformants after subcultures as a result of inactivation or deletions of the RNAi transgene. The gene silencing system established provides a useful tool for functional genomics studies in C. sativus and other filamentous fungi. [ABSTRACT FROM AUTHOR]

Published

2011

82. Pyrenophora teres: profile of an increasingly damaging barley pathogen.

Author

LIU, ZHAOHUI, ELLWOOD, SIMON R., OLIVER, RICHARD P., and FRIESEN, TIMOTHY L.

Subjects

PYRENOPHORA teres, BARLEY diseases & pests, PHYTOPATHOGENIC microorganisms, HOST-parasite relationships, FUNGI classification, FUNGAL genetics, PHYTOPATHOGENIC fungi, ASCOSPORES

Abstract

Pyrenophora teres, causal agent of net blotch of barley, exists in two forms, designated P. teres f. teres and P. teres f. maculata, which induce net form net blotch (NFNB) and spot form net blotch (SFNB), respectively. Significantly more work has been performed on the net form than on the spot form although recent activity in spot form research has increased because of epidemics of SFNB in barley-producing regions. Genetic studies have demonstrated that NFNB resistance in barley is present in both dominant and recessive forms, and that resistance/susceptibility to both forms can be conferred by major genes, although minor quantitative trait loci have also been identified. Early work on the virulence of the pathogen showed toxin effector production to be important in disease induction by both forms of pathogen. Since then, several laboratories have investigated effectors of virulence and avirulence, and both forms are complex in their interaction with the host. Here, we assemble recent information from the literature that describes both forms of this important pathogen and includes reports describing the host-pathogen interaction with barley. We also include preliminary findings from a genome sequence survey. Pyrenophora teres Drechs. Kingdom Fungi; Phylum Ascomycota; Subphylum Pezizomycotina; Class Dothideomycete; Order Pleosporales; Family Pleosporaceae; Genus Pyrenophora, form teres and form maculata. To date, no clear morphological or life cycle differences between the two forms of P. teres have been identified, and therefore they are described collectively. Towards the end of the growing season, the fungus produces dark, globosely shaped pseudothecia, about 1-2 mm in diameter, on barley. Ascospores measuring 18-28 µm × 43-61 µm are light brown and ellipsoidal and often have three to four transverse septa and one or two longitudinal septa in the median cells. Conidiophores usually arise singly or in groups of two or three and are lightly swollen at the base. Conidia measuring 30-174 µm × 15-23 µm are smoothly cylindrical and straight, round at both ends, subhyaline to yellowish brown, often with four to six pseudosepta. Morphologically, P. teres f. teres and P. teres f. maculata are indistinguishable. Comprehensive work on the host range of P. teres f. teres has been performed; however, little information on the host range of P. teres f. maculata is available. Hordeum vulgare and H. vulgare ssp. spontaneum are considered to be the primary hosts for P. teres. However, natural infection by P. teres has been observed in other wild Hordeum species and related species from the genera Bromus, Avena and Triticum, including H. marinum, H. murinum, H. brachyantherum, H. distichon, H. hystrix, B. diandrus, A. fatua, A. sativa and T. aestivum (, Rev. Plant Pathol. 52:269-290). In artificial inoculation experiments under field conditions, P. teres f. teres has been shown to infect a wide range of gramineous species in the genera Agropyron, Brachypodium, Elymus, Cynodon, Deschampsia, Hordelymus and Stipa (Brown et al., 1993, Plant Dis. 77:942-947). Additionally, 43 gramineous species were used in a growth chamber study and at least one of the P. teres f. teres isolates used was able to infect 28 of the 43 species tested. However, of these 28 species, 14 exhibited weak type 1 or 2 reactions on the NFNB 1-10 scale (). These reaction types are small pin-point lesions and could possibly be interpreted as nonhost reactions. In addition, the P. teres f. teres host range was investigated under field conditions by artificially inoculating 95 gramineous species with naturally infected barley straw. Pyrenophora teres f. teres was re-isolated from 65 of the species when infected leaves of adult plants were incubated on nutrient agar plates; however, other than Hordeum species, only two of the 65 host species exhibited moderately susceptible or susceptible field reaction types, with most species showing small dark necrotic lesions indicative of a highly resistant response to P. teres f. teres. Although these wild species have the potential to be alternative hosts, the high level of resistance identified for most of the species makes their role as a source of primary inoculum questionable. Two types of symptom are caused by P. teres. These are net-type lesions caused by P. teres f. teres and spot-type lesions caused by P. teres f. maculata. The net-like symptom, for which the disease was originally named, has characteristic narrow, dark-brown, longitudinal and transverse striations on infected leaves. The spot form symptom consists of dark-brown, circular to elliptical lesions surrounded by a chlorotic or necrotic halo of varying width. [ABSTRACT FROM AUTHOR]

Published

2011

83. A unique wheat disease resistance-like gene governs effector-triggered susceptibility to necrotrophic pathogens.

Author

Justin D. Faris, Zengcui Zhang, Huangjun Lu, Shunwen Lu, Reddy, Leela, Cloutier, Sylvie, Fellers, John P., Meinhardt, Steven W., Rasmussen, Jack B., Xu, Steven S., OIiver, Richard P., Simons, Kristin J., and Friesen, Timothy L.

Subjects

GENETICS of disease resistance of plants, NUCLEOTIDES, BINDING sites, PATHOGENIC microorganisms, DIAGNOSTIC microbiology, STAGONOSPORA, MUTAGENESIS, REGULATION of photosynthesis

Abstract

Plant disease resistance is often conferred by genes with nucleotide binding site (NBS) and leucine-rich repeat (LRR) or serine/threonine protein kinase (S/TPK) domains. Much less is known about mechanisms of susceptibility, particularly to necrotrophic fungal pathogens. The pathogens that cause the diseases tan spot and Stagonospora nodorum blotch on wheat produce effectors (host-selective toxins) that induce susceptibility in wheat lines harboring corresponding toxin sensitivity genes. The effector ToxA is produced by both pathogens, and sensitivity to ToxA is governed by the Tsnl gene on wheat chromosome arm 5BL. Here, we report the cloning of Tsnl, which was found to have disease resistance gene-like features, including SITPK and NBS-LRR domains. Mutagenesis revealed that all three domains are required for ToxA sensitivity, and hence disease susceptibility. Tsnl is unique to ToxA-sensitive genotypes, and insensitive genotypes are null. Sequencing and phylogenetic analysis indicated that Tsnl arose in the B-genome diploid progenitor of polyploid wheat through a gene-fusion event that gave rise to its unique structure. Although Tsnl is necessary to mediate ToxA recognition, yeast two-hybrid experiments suggested that the Tsnl protein does not interact directly with ToxA. Tsn1 transcription is tightly regulated by the circadian clock and light, providing further evidence that Tsnl-ToxA interactions are associated with photosynthesis pathways. This work suggests that these necrotrophic pathogens may thrive by subverting the resistance mechanisms acquired by plants to combat other pathogens. [ABSTRACT FROM AUTHOR]

Published

2010

84. Molecular and Cytogenetic Characterization of Wheat Introgression Lines Carrying the Stem Rust Resistance Gene Sr39.

Author

Guo Tai Yu, Qijun Zhang, Klindworth, Daryl L., Friesen, Timothy L., Ron Knox, Yue Jin, Shaobin Zhong, Xiwen Cai, and Xu, Steven S.

Subjects

WHEAT diseases & pests, PUCCINIA graminis, GENOMES, AEGILOPS, CHROMOSOMES, IN situ hybridization

Abstract

The stem rust (Puccinia graminis Pers.:Pers. f.sp. tritici Eriks. and Henn.) resistance gene Sr39, which confers resistance to TTKSK (Ug99), has been incorporated into the wheat (Triticum aestivum L.) genome from Aegilops speltoides in the form of a chromosome translocation but it has not been deployed into adapted cultivars. In this study, we characterized translocation lines carrying Sr39 in four different wheat backgrounds with fluorescent genomic in situ hybridization (GISH) and simple sequence repeat (SSR) markers. The results indicated that RL5711 and RL6082 had translocation chromosomes of comparable structure. The translocation chromosome in PI 600683 has lost Ae. speltoides chromatin in the telomeric end of the 2S long arm. Six translocation lines derived from the cross PI 600683/3*HY438 had translocation chromosomes of comparable structure to the one found in PI 600683. However, one line (P9714-AM03C51), showed a substantial reduction in Ae. speltoides chromatin in the short arm of the translocated chromosome. The study demonstrated that it is apparently feasible to shorten Ae. speltoides chromatin in some wheat-Ae. speltoides translocation lines. These results and the identification of diagnostic SSR markers will be useful in guiding chromosome manipulation efforts to further shorten the Ae. speltoides chromosome segments in these materials. Greenhouse inoculation of translocation lines with stem rust indicated that the Sr39 gene conditions resistance to at least seven stem rust races. [ABSTRACT FROM AUTHOR]

Published

2010

85. SnTox3 Acts in Effector Triggered Susceptibility to Induce Disease on Wheat Carrying the Snn3 Gene.

Author

Zhaohui Liu, Faris, Justin D., Oliver, Richard P., Kar-Chun Tan, Solomon, Peter S., McDonald, Megan C., McDonald, Bruce A., Nunez, Alberto, Lu, Shunwen, Rasmussen, Jack B., and Friesen, Timothy L.

Subjects

FUNGI, MICROBIAL toxins, WHEAT germ, GENETIC vectors, MYCOSES, PROTEIN C gene, PICHIA pastoris, PRIONS

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. [ABSTRACT FROM AUTHOR]

Published

2009

86. Reevaluation of a Tetraploid Wheat Population Indicates that the Tsnl-ToxA Interaction Is the Only Factor Governing Stagonospora nodorum Blotch Susceptibility.

Author

Faris, Justin D. and Friesen, Timothy L.

Subjects

*PLANT chromosomes, *PLANT toxins, *STAGONOSPORA diseases, *WHEAT diseases & pests, *PLANT gene mapping, WHEAT genetics

Abstract

The wheat Tsn1 gene on chromosome 5B confers sensitivity to a host-selective toxin produced by the pathogens that cause tan spot and Stagonospora nodorum blotch (SNB) known as Ptr ToxA and SnToxA, respectively (hereafter referred to as ToxA). A compatible Tsn1-ToxA interaction is known to play a major role in conferring susceptibility of hexaploid (common) wheat to SNB. However, a recent study by another group suggested that the Tsn1-ToxA interaction was not relevant in conferring susceptibility of the tetraploid (durum) wheat cv. Langdon (LDN). Here, we reevaluated the role of the Tsn1-ToxA interaction in governing SNB susceptibility using the same mapping population and Stagonospora nodorum isolate (Sn2000) as were used in the previous study. Results of our quantitative trait locus analysis showed that the Tsn1 locus accounted for 95% of the variation in SNB. In addition, inoculation of the mapping population with two ToxA-knockout strains of Sn2000 revealed that the entire population was resistant. Furthermore, several LDN Tsn1-disrupted mutants were evaluated and found to be resistant to SNB. Together, these results prove unequivocally that Tsn1 is the only factor present along chromosome 5B that governs response to SNB in this population and that a compatible Tsn1-ToxA interaction is necessary for the manifestation of disease. Therefore, the results from the previous study are refuted. [ABSTRACT FROM AUTHOR]

Published

2009

87. Development, identification, and validation of markers for marker-assisted selection against the Stagonospora nodorum toxin sensitivity genes Tsn1 and Snn2 in wheat.

Author

Zengcui Zhang, Friesen, Timothy L., Simons, Kristin J., Xu, Steven S., and Faris, Justin D.

Subjects

*POPULATION, *WHEAT, *HEREDITY, *TOXINS, *STAGONOSPORA, *COOKING

Abstract

The wheat- Stagonospora nodorum pathosystem involves a number of pathogen-produced host-selective toxins that interact with host genes in an inverse gene-for-gene manner to cause disease. The wheat intervarietal recombinant inbred population derived from BR34 and Grandin (BG population) segregates for the toxin sensitivity genes Tsn1, Snn2, and Snn3, which confer sensitivity to the toxins ToxA, SnTox2, and SnTox3, respectively. Here, we report the addition of 141 molecular markers to the BG population linkage maps, the identification and/or development of markers tightly linked to Tsn1 and Snn2, and the validation of the markers using a set of diverse wheat accessions. The BG population maps now contain 787 markers, and new simple sequence repeat (SSR) markers closely linked to Snn2 on chromosome arm 2DS were identified. In an effort to target more markers to the Snn2 locus, STS markers were developed from 2DS bin-mapped ESTs resulting in the development and mapping of 36 markers mostly to the short arms of group 2 chromosomes. Together, SSR and EST-STS markers delineated Snn2 to a 4.0 cM interval. SSRs developed in related work for Tsn1 were mapped in the BG population and delineated the gene to a 1.0 cM interval. Evaluation of the markers for Tsn1 and Snn2 in a diverse set of wheat genotypes validated their utility for marker-assisted selection, which is particularly efficient for removing toxin sensitivity alleles from elite germplasm and varieties. [ABSTRACT FROM AUTHOR]

Published

2009

88. Host-specific toxins: effectors of necrotrophic pathogenicity.

Author

Friesen, Timothy L., Faris, Justin D., Solomon, Peter S., and Oliver, Richard P.

Subjects

*MICROBIOLOGY, *TOXINS, *GENOTYPE-environment interaction, *PATHOGENIC microorganisms, *TOXICITY testing, *PLEOSPORALES, *GENES, *GENETIC transformation, *METABOLITES

Abstract

Host-specific toxins (HSTs) are defined as pathogen effectors that induce toxicity and promote disease only in the host species and only in genotypes of that host expressing a specific and often dominant susceptibility gene. They are a feature of a small but well-studied group of fungal plant pathogens. Classical HST pathogens include species of Cochliobolus, Alternaria and Pyrenophora. Recent studies have shown that Stagonospora nodorum produces at least four separate HSTs that interact with four of the many quantitative resistance loci found in the host, wheat. Rationalization of fungal phylogenetics has placed these pathogens in the Pleosporales order of the class Dothideomycetes. It is possible that all HST pathogens lie in this order. Strong evidence of the recent lateral gene transfer of the ToxA gene from S. nodorum to Pyrenophora tritici-repentis has been obtained. Hallmarks of lateral gene transfer are present for all the studied HST genes although definitive proof is lacking. We therefore suggest that the Pleosporales pathogens may have a conserved propensity to acquire HST genes by lateral transfer. [ABSTRACT FROM AUTHOR]

Published

2008

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

Author

Zhaohui Liu, Friesen, Timothy L., Hua Ling, Meinhardt, Steven W., Oliver, Richard P., Rasmussen, Jack B., and Faris, Justin D.

Subjects

*TOXINS, *NECROSIS, *CHROMOSOMES, *STAGONOSPORA, *GENES

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. [ABSTRACT FROM AUTHOR]

Published

2006

90. Emergence of a new disease as a result of interspecific virulence gene transfer.

Author

Friesen, Timothy L., Stukenbrock, Eva H., Zhaohui Liu, Meinhardt, Steven, Hua Ling, Faris, Justin D., Rasmussen, Jack B., Solomon, Peter S., McDonald, Bruce A., and Oliver, Richard P.

Subjects

*MICROBIAL virulence, *GENETIC transformation, *GENETIC recombination, *MICROBIAL genetics, *GENETICS, *MICROBIOLOGY

Abstract

New diseases of humans, animals and plants emerge regularly. Enhanced virulence on a new host can be facilitated by the acquisition of novel virulence factors. Interspecific gene transfer is known to be a source of such virulence factors in bacterial pathogens (often manifested as pathogenicity islands in the recipient organism) and it has been speculated that interspecific transfer of virulence factors may occur in fungal pathogens. Until now, no direct support has been available for this hypothesis. Here we present evidence that a gene encoding a critical virulence factor was transferred from one species of fungal pathogen to another. This gene transfer probably occurred just before 1941, creating a pathogen population with significantly enhanced virulence and leading to the emergence of a new damaging disease of wheat. [ABSTRACT FROM AUTHOR]

Published

2006

91. ‘Velva’ Spring Wheat: An Adapted Cultivar to North‐Central Plains of the United States with High Agronomic and Quality Performance

Author

Mergoum, Mohamed, Simsek, Senay, Zhong, Shaobin, Acevedo, Maricelis, Friesen, Timothy L., Singh, Pawan K., Adhikari, Tika B., Alamri, Mohammed S., and Frohberg, Richard C.

Abstract

Spring wheat (Triticum aestivumL.) growers and industry value adapted wheat cultivars with high quality attributes, essential criteria for maintaining wheat as a competitive crop in the spring wheat growing region of the United States. To address this goal, the breeding program at North Dakota State University (NDSU) aims to develop modern wheat cultivars using both traditional and modern breeding tools. Among these cultivars, ‘Velva’ (Reg. No. CV‐1090, PI 665417) hard red spring wheat (HRSW) was developed at NDSU. It was released by the North Dakota Agricultural Experiment Station in 2012. Velva was tested as experimental line ND811 and was released because it is well adapted to the wheat growing conditions of North Dakota. It combines high yield potential with good end‐use quality and has a good disease resistance package including Fusarium head blight (FHB) [caused by Fusarium graminearumSchwabe (teleomorph Gibberella zeae(Schwein.) Petch)] and leaf diseases including stem rust (caused by Puccinia graminisPers.:Pers. f. sp. triticiEriks. & E. Henn.), leaf rust (caused by Puccinia triticinaEriks.), and leaf spotting diseases. Velva has the Lr21gene that confers resistance to leaf rust. However, 2011 field observations showed that Velva is susceptible to the new race that overcomes the Lr21gene. The name Velva was chosen after a small town in central North Dakota where Velva performed very well.

Published

2014

92. ND 803 Spring Wheat Germplasm Combining Resistance to Scab and Leaf Diseases with Good Agronomic and Quality Traits

Author

Mergoum, Mohamed, Frohberg, Richard C., Stack, Robert W., Singh, Pawan K., Adhikari, Tika B., Rasmussen, Jack B., Alamri, Mohammed S., and Friesen, Timothy L.

Abstract

The development of adapted wheat germplasm is essential so that breeding programs can develop superior cultivars, which was the objective of this research. ND 803 is hard red spring wheat (HRSW; Triticum aestivumL.) line that was developed at North Dakota State University (NDSU) and released by the North Dakota Agricultural Experiment Station (NDAES). ND 803 (Reg. No. GP‐947, PI 665931 was derived from the ND2831/FO.2808 cross made at NDSU in fall 1997. ND2831 (‘Sumai3’ [PI 481542]/‘Stoa’ [PI 520297]) is a hard red spring experimental line with good resistance to Fusarium head blight (FHB), or scab [caused by Fusarium graminearumSchwabe; telomorph Gibberella zeae(Schwein.) Petch] originating from ‘Sumai3’, which is known to possess the Fhb1quantitative trait locus. Sumai3 is a spring wheat from China that is arguably the most widely used source of resistance to FHB in the world. Stoa is an HRSW cultivar released by NDSU in 1984. FO.2808 (‘Grandin’ [PI 531005]/3/IAS20*4/H567.71//‘Amidon’ [PI 527682]/ND674) is an HRSW line developed by the NDSU HRSW breeding program. Amidon and Grandin are HRSW cultivars released by NDAES in 1988 and 1989, respectively. IAS20*4/H567.71 is a public breeding line received from CIMMYT. ND 803 was produced from a bulk of one purified F5:6plot selected in 2000 at Prosper, ND. ND 803 was released because it combines good agronomic and end‐use quality with resistance to both FHB and leaf diseases.

Published

2013

93. ‘Prosper’: A High‐Yielding Hard Red Spring Wheat Cultivar Adapted to the North Central Plains of the USA

Author

Mergoum, Mohamed, Frohberg, Richard C., Stack, Robert W., Simsek, Senay, Adhikari, Tika B., Rasmussen, Jack B., Zhong, Shaobin, Acevedo, Maricelis, Alamri, Mohammed S., Singh, Pawan K., Friesen, Timothy L., and Anderson, James A.

Abstract

Providing wheat (Triticum aestivumL.) growers and industry with adapted wheat cultivars with high‐quality attributes is essential for maintaining wheat as a competitive crop in the spring‐wheat growing region of the USA. Therefore, our breeding program aims to develop modern wheat cultivars using both traditional and modern breeding tools. ‘Prosper’ (Reg. No. CV‐1080, PI 662387) hard red spring wheat was developed at North Dakota State University and released jointly by the North Dakota Agricultural Experiment Station and the Minnesota Agricultural Experiment Station because of its good adaptation to the spring‐wheat‐growing regions in the U.S. North Central Plains. However, the high yield potential of Prosper under high rainfall conditions makes it more adapted mainly to wheat‐growing regions in eastern North Dakota, western Minnesota, and high‐rainfall regions of neighboring states. It has high yield potential and good milling and baking properties. Gene postulation shows that Prosper has the Lr21gene, which confers resistance to leaf rust (caused by Puccinia triticinaEriks.). However, 2011 field observations show that Prosper is susceptible to a new race that overcomes the Lr21gene. Prosper is resistant to stem rust (caused by Puccinia graminisPer.:Pers. f. sp. triticiEriks. & E. Henn) and moderately resistant to Fusarium head blight (FHB), or scab [caused by Fusarium graminearumSchwabe; telomorph Gibberella zeae(Schwein.) Petch].

Published

2013

94. ‘Barlow’: A High‐Quality and High‐Yielding Hard Red Spring Wheat Cultivar Adapted to the North Central Plains of the USA

Author

Mergoum, Mohamed, Simsek, Senay, Frohberg, Richard C., Rasmussen, Jack B., Friesen, Timothy L., and Adhikari, Tika

Abstract

‘Barlow’ (Reg. No. CV‐1055, PI 658018) hard red spring wheat (HRSW) (Triticum aestivumL.) was developed at North Dakota State University and released by the North Dakota Agricultural Experiment Station (NDAES). Barlow was released in 2009 primarily for its good adaptation to the spring‐wheat‐growing regions in the U.S. North Central Plains. However, Barlow also shows superior adaptation, particularly to the rainfed western wheat‐production regions of North Dakota and counties in adjacent states. It has high yield potential and excellent milling and baking properties. Barlow is resistant to leaf rust (caused by Puccinia triticinaEriks.), stem rust (caused by Puccinia graminisPer.:Pers. f. sp. triticiEriks. & E. Henn), tan spot [caused by [Pyrenophora tritici‐repentis(Died.) Drechs] race 3, Septoria tritici blotch (caused by Mycosphaerella graminicola(Fückl) J. Schröt. in Cohn), and Stagonospora nodorum blotch [caused by Stagonospora nodorum(Berk.) Castellani & E.G. Germano]. It also has an intermediate level of resistance to Fusarium head blight, or scab [caused by Fusarium graminearumSchwabe (telomorph Gibberella zeae(Schwein.) Petch)]. Barlow is derived from the ND 744/ND 721 cross made at NDSU in fall 1999. ND 744 (PI634936), a ‘Glenn’ (PI 639273) sister line, is a public HRSW breeding line developed at NDSU and released by NDAES as a germplasm in 2005. ND 721 is a public breeding line derived from the cross ‘Grandin’/3/IAS20*4/H567.71//‘Amidon’/4/ND 674. Barlow was produced from a bulk of 180 purified F11headrow increase plots grown at Prosper, ND in 2007. Barlow was released because it combines high yield, excellent end‐use quality, and resistance to many diseases.

Published

2011

95. Prevalence and importance of sensitivity to the Stagonospora nodorumnecrotrophic effector SnTox3 in current Western Australian wheat cultivars

Author

Waters, Ormonde D. C., Lichtenzveig, Judith, Rybak, Kasia, Friesen, Timothy L., and Oliver, Richard P.

Abstract

Stagonospora nodorum is a major pathogen of wheat in many parts of the world and particularly in Western Australia. The pathosystem is characterised by interactions of multiple pathogen necrotrophic effectors (NE) (formerly host-specific toxins) with corresponding dominant host sensitivity loci. To date, five NE interactions have been reported in S. nodorum. Two proteinaceous NE (ToxA and SnTox3) have been cloned and expressed in microbial systems. The identification of wheat cultivars lacking sensitivity to one or more NE is a promising way to identify cultivars suitable for use in breeding for increased resistance to this economically important pathogen. The prevalence of sensitivity to the NE SnTox3 was investigated in 60 current Western Australian-adapted bread wheat (Triticum aestivum L.) cultivars. Infiltration of SnTox3 into seedling leaves caused a moderate or strong necrotic response in 52 cultivars. Six cultivars were insensitive and two cultivars exhibited a weak chlorotic response. Five of the cultivars that were insensitive or weakly sensitive to SnTox3 were noticeably more resistant to the disease. The 60 cultivars gave a very similar reaction to SnTox3 and to the crude S. nodorum SN15 culture filtrate demonstrating that SnTox3 is the dominant NE in this isolate. We conclude that a simple screen using both SnTox3 and ToxA effectors combined with simple greenhouse disease evaluation, will allow breeders to select cultivars that are more resistant to the disease, allowing them to concentrate resources on other still intractable breeding objectives.

Published

2011

96. Breeding for CLEARFIELD Herbicide Tolerance: Registration of ‘ND901CL’ Spring Wheat

Author

Mergoum, Mohamed, Frohberg, Richard C., Rasmussen, Jack W., Friesen, Timothy L., Hareland, Gary, and Simsek, Senay

Abstract

‘ND901CL’ (Reg. No. CV‐1029, PI 655233) hard red spring wheat (HRSW) (Triticum aestivumL.) was developed at North Dakota State University (NDSU) and released by the North Dakota Agricultural Experiment Station (NDAES). ND901CL was released in 2008 primarily for its tolerance to imadazolinone herbicides. It has superior adaptation to rainfed wheat production in western regions of North Dakota and counties in adjacent states. It is a CLEARFIELD‐tolerant wheat intended to be used with Beyond herbicide (active ingredient imazamox, 2‐[4,5‐dihydro‐4‐methyl‐4‐(1‐methylethyl)‐5‐oxo‐1H‐imidazol‐2‐yl]‐5‐(methoxymethyl)‐3‐pyridinecarboxylic acid; BASF Corporation, Research Triangle Park, NC). The tolerance to CLEARFIELD herbicide in ND901CL is controlled by two genes. The als1locus for acetolactate synthase, is located on the D genome and was transferred from ‘FS4’ wheat. The als2locus is located on the B genome and originated from ‘Teal 11A’ wheat. ND901CL was derived from the Teal 11A/3/‘Grandin’ (PI 531005)/FS4//*3 ‘Kulm’ cross made at NDSU in 2002. Grandin and Kulm are two HRSW cultivars released by NDAES in 1989 and 1994, respectively. Both FS4 and Teal 11A were provided by the BASF Corporation to our breeding program. ND901CL was produced from a bulk of one purified F4:5plot selected in 2004 at Christchurch, New Zealand. ND901CL was released because it combines high yield with good end‐use quality and tolerance to BEYOND herbicide.

Published

2009

97. Registration of ‘Faller’ Spring Wheat

Author

Mergoum, Mohamed, Frohberg, Richard C., Stack, Robert W., Rasmussen, Jack W., and Friesen, Timothy L.

Abstract

‘Faller’ (Reg. No. CV‐1026, PI 648350) hard red spring wheat (HRSW) (Triticum aestivumL.) was developed at North Dakota State University (NDSU) and released by the North Dakota Agricultural Experiment Station (NDAES). Faller was derived from the ND2857/ND2814 cross made at NDSU in fall 1997. ND2857 (ND2709/ND688) is a hard red spring experimental line with good resistance to Fusarium head blight (FHB) (caused by Fusarium graminearumSchwabe [telomorph Gibberella zeae(Schwein.) Petch]) originating from ND2709, a line known to possess the Fhb1 quantitative trait locus derived from ‘Sumai3’ (PI 481542). Sumai3, a spring wheat from China, is arguably the most widely used source of resistance to FHB in the world. Both ND2709 and ND688 are HRSW experimental lines developed by the NDSU breeding program. ND2814 (‘Kitt’ [PI 518818]/‘Amidon’ [PI 527682]/3/‘Grandin’ [PI 531005]/‘Stoa S’ [PI 520297]) is an HRSW line developed by the NDSU HRSW breeding program. Kitt is an HRSW cultivar released in 1975 by the Minnesota Agricultural Experiment Station and the USDA‐ARS, while Amidon, Grandin, and Stoa are HRSW cultivars released by NDAES in 1988, 1989, 1984, respectively. Faller was produced from a bulk of one purified F4:5plot selected in 2001 at Christchurch, New Zealand. Faller was released because it combines very high yield with good end‐use quality and resistance to FHB and leaf diseases.

Published

2008

98. Registration of Spring Wheat Germplasm ND 756 Combining Resistances to Foliar Diseases and Fusarium Head Blight

Author

Mergoum, Mohamed, Frohberg, Richard C., Stack, Robert W., Singh, Pawan K., Ali, Shaukat, Rasmussen, Jack W., Friesen, Timothy L., and Adhikari, Tika B.

Abstract

ND 756 hard red spring wheat (HRSW) (Triticum aestivumL.) (Reg. No. GP‐837, PI 648034) was developed at North Dakota State University and released by the North Dakota Agricultural Experiment Station. ND 756 was derived from the ND 2849/ND 721 cross made in 1996. ND 2849 and ND 721 are two experimental lines developed by NDSU HRSW breeding program. ND 2849 is derived from a cross (ND 674//ND 2710/ND 688) involving NDSU HRSW experimental lines (ND 674 and ND 688) and ND 2710 (PI 633976, Frohberg et al., 2004) that was previously released for its resistance to Fusarium head blight (FHB) [caused by Fusarium graminearumSchwabe (telomorph Gibberella zeae(Schwein.) Petch]. ND 756 was produced from a bulk of one F5:6 head row selected in 2002 at the Christchurch, New Zealand off‐season nursery. ND 756 was released mainly for its resistance to Septoria nodorum blotch (SNB) [caused by Phaeosphaeria nodorum(E.Müller) Hedjarroude], Septoria tritici blotch (STB) [caused by Mycosphaerella graminicola(Fückl) J. Schröt. in Cohn] and tan spot [caused by Pyrenophora tritici‐repentis(Died.) Drechs]. ND 756 is also resistant to the prevalent races of stem rust (caused by Puccinia graminisPers:Pers. f. sp.triticiEriks. & E. Henn) and leaf rust (caused by Puccinia triticinaEriks.). ND 756 is moderately resistant to FHB and has good agronomic performance but does not meet the high grain quality requirements to qualify for release by NDAES.

Published

2008

99. Genomic Targeting and High‐Resolution Mapping of the Tsn1Gene in Wheat

Author

Haen, Karri M., Lu, Huangjun, Friesen, Timothy L., and Faris, Justin D.

Abstract

Tan spot, caused by the fungal pathogen Pyrenophora tritici‐repentis(Died.) Drechs. causes severe yield losses in wheat (Triticum aestivumL., 2n= 6x= 42, AABBDD) and durum (T. turgidumL., 2n= 4x= 28, AABB). The Tsn1gene acts dominantly to confer sensitivity to a host‐selective proteinaceous toxin (Ptr ToxA) produced by the fungus. Our objectives were to: (i) target markers to the Tsn1genomic region and (ii) develop a high‐resolution map of the Tsn1locus. The techniques of methylation‐sensitive AFLP, traditional AFLP, and cDNA‐AFLP were combined with bulked segregant analysis (BSA) using various wheat and durum cytogenetic stocks to target markers to the Tsn1genomic region. Over 500 primer combinations were screened resulting in the identification of 18 low‐copy markers closely linked to Tsn1.High‐resolution mapping of the markers delineated the Tsn1gene to a 0.2 cM interval in a hexaploid wheat population consisting of 1266 gametes, and to 0.8 cM in a durum wheat population consisting of 1860 gametes. Comparisons with rice BAC/PAC sequences indicated the lack of colinearity within the Tsn1genomic region. Tsn1was located within a gene‐rich recombination hot spot region, and the physical distance separating the flanking markers may be as little as 200 kb. Therefore, these markers will serve as a basis for the map‐based cloning of Tsn1The isolation of Tsn1will further our knowledge of wheat–tan spot interactions as well as host–pathogen interactions in general.

Published

2004

100. Evolution, diversity, and function of the disease susceptibility gene Snn1 in wheat.

Author

Seneviratne, Sudeshi, Shi, Gongjun, Szabo‐Hever, Agnes, Zhang, Zengcui, Peters Haugrud, Amanda R., Running, Katherine L. D., Singh, Gurminder, Nandety, Raja Sekhar, Fiedler, Jason D., McClean, Phillip E., Xu, Steven S., Friesen, Timothy L., and Faris, Justin D.

Abstract

SUMMARY Septoria nodorum blotch (SNB), caused by Parastagonospora nodorum, is a disease of durum and common wheat initiated by the recognition of pathogen‐produced necrotrophic effectors (NEs) by specific wheat genes. The wheat gene Snn1 was previously cloned, and it encodes a wall‐associated kinase that directly interacts with the NE SnTox1 leading to programmed cell death and ultimately the development of SNB. Here, sequence analysis of Snn1 from 114 accessions including diploid, tetraploid, and hexaploid wheat species revealed that some wheat lines possess two copies of Snn1 (designated Snn1‐B1 and Snn1‐B2) approximately 120 kb apart. Snn1‐B2 evolved relatively recently as a paralog of Snn1‐B1, and both genes have undergone diversifying selection. Three point mutations associated with the formation of the first SnTox1‐sensitive Snn1‐B1 allele from a primitive wild wheat were identified. Four subsequent and independent SNPs, three in Snn1‐B1 and one in Snn1‐B2, converted the sensitive alleles to insensitive forms. Protein modeling indicated these four mutations could abolish Snn1–SnTox1 compatibility either through destabilization of the Snn1 protein or direct disruption of the protein–protein interaction. A high‐throughput marker was developed for the absent allele of Snn1, and it was 100% accurate at predicting SnTox1‐insensitive lines in both durum and spring wheat. Results of this study increase our understanding of the evolution, diversity, and function of Snn1‐B1 and Snn1‐B2 genes and will be useful for marker‐assisted elimination of these genes for better host resistance. [ABSTRACT FROM AUTHOR]

Published

2024