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Purification and Characterization of Stagonospora nodorum Toxins and Mapping of Toxin InsensitivityBajracharya, Pratisara 13 February 2015 (has links)
Stagonospora nodorum is a pathogenic fungus of wheat causing Stagonospora nodorum blotch disease, an important disease in western Canada. S. nodorum produces a multitude of host selective toxins (HSTs), which when recognized by corresponding sensitivity gene in wheat results in a compatible interaction. In this study, novel HST-host sensitivity gene interactions were investigated. Two different putative HSTs were identified. SnTox3 was likely one of the HSTs present in S. nodorum isolate Swift Current culture filtrate as the chromosomal location of the compatible sensitivity gene corresponded to that of Snn3 locus. Another putative HST interacting with Tsn1 or a tightly linked sensitivity gene was identified from S. nodorum isolate Langham. SNOG_15679, a candidate gene for production of this putative HST was heterologously expressed in Pichia pastoris which caused chlorosis on a sensitive host. Additional tests will be required to confirm the bioactivity of putative novel HST(s) produced by isolate Langham. / May 2015
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Control of phenotypic variation in Pseudomonas tolaasiiSmith, Julia C. January 1996 (has links)
No description available.
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The life history of Mycosphaerella pinodes on Pisum sativumHare, Woodrow W. January 1943 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1943. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 41-42).
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Purple blotch of onion (Macrosporium porri Ell.)Angell, Herbert Raleigh. January 1928 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1928. / Typescript. With this is bound: Purple blotch of onion (Macrosporium porri Ell.), [by] H.R. Angell, reprinted from Journal of Agricultural research, v. 38, no. 9 (May 1, 1929), p. 467-487. Includes bibliographical references ([4] leaves after numbered leaves).
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Molecular analysis of resistance of Pseudomonas tolaasii to the lipodepsipeptide toxin tolaasinHutchison, Michael January 1993 (has links)
No description available.
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Genomic analysis of <i>Pyrenophora teres</i> : avirulence gene mapping, karyotyping and genetic map constructionBeattie, Aaron David 31 October 2006
<i>Pyrenophora teres</i> Drechs. (anamorph: <i>Drechslera teres</i> (Sacc.) Shoem.) is the causal agent of barley net blotch. Net blotch is an economically important disease commonly found throughout the barley producing regions of the world. Significant financial losses result from yield reductions, ranging from 15-35%, and decreased grain quality. Despite its prevalence, it is unclear if the P. teres-barley pathosystem follows a gene-for-gene model, and more generally, little is known about its genetic organization. Three studies were initiated to address these questions.<p>The first study investigated the genetic control of avirulence in <i>P. teres.</i> To establish an appropriate study system, a collection of ten net form (<i>P. teres f. teres</i>) and spot form (<i>P. teres f. maculata</i>) isolates were evaluated on a set of eight differential barley lines to identify two isolates with differential virulence on a specific host line. WRS 1906, exhibiting low virulence on the cultivar Heartland, and WRS 1607, exhibiting high virulence, were mated and 67 progeny were isolated and phenotyped for virulence on Heartland. The population segregated in a 1:1 ratio, 34 avirulent to 33 virulent (Chi-square = 0.0, P = 1.0), indicating single gene control of WRS 1906 avirulence on Heartland. Bulked segregant analysis was used to identify six amplified fragment length polymorphism (AFLP) markers closely linked to the avirulence gene (AvrHeartland). This work provides evidence that the P. teres-barley pathosystem conforms to the gene-for-gene model.<p>In the second study, five isolates of P. teres, representing both net and spot forms, were analyzed by the germ tube burst method (GTBM) and pulsed field gel electrophoresis (PFGE) to determine the species karyotype. Nine chromosomes were observed in all isolates using the GTBM and estimation of chromosome lengths varied from 0.5 to 3.0 µm. PFGE separated 7 to 8 bands depending on isolate, but analysis of bands by densitometry indicated nine chromosomes. Chromosome size ranged from 1.8 to ~6.0 Mb providing a genome size estimate of 32 to 39 Mb. Significant chromosome-length polymorphisms (CLP) were observed between isolates. These CLP did not hinder mating between mating-type compatible net form isolates. No particular CLP or individual chromosome could be associated with differences in disease symptoms observed between pathogen forms. This study provides the first karyotype of both P. teres forms and will assist genetic mapping of this pathogen.<p>A genetic linkage map of <i>P. teres f. teres</i>, was constructed in the third study using the population of 67 progeny derived from the WRS 1906 WRS 1607 cross. The map consists of 138 markers including 114 AFLPs, 21 telomere RFLPs, the mating-type (MAT) locus and an avirulence locus (AvrHeartland) controlling interaction with barley cultivar Heartland. Markers were distributed across 24 linkage groups ranging in length from 2 to 110 cM with an average marker interval of 8.5 cM. The total map length was 797 cM. A telomere-specific probe, consisting of the sequence (TTAGGC)4, was used to map 15 of the 18 telomeres. One of these telomeres mapped to within 3 cM of the AvrHeartland locus. Attempts to consolidate linkage groups by hybridizing markers to the electrophoretically separated chromosomes was unsuccessful because probes bound to multiple chromosomes, likely due to repetitive DNA within the probe. This is the first genetic map reported for this species and it will be a useful genetic tool for map-based cloning of the AvrHeartland gene tagged in this study. <p>This research has provided a number of new insights into the net blotch pathogen and provides a useful research tool in the form of a genetic map. This information lays the foundation for further genetic study of P. teres and will complement studies on barley resistance to net blotch that may potentially lead to more durable resistance.
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Genomic analysis of <i>Pyrenophora teres</i> : avirulence gene mapping, karyotyping and genetic map constructionBeattie, Aaron David 31 October 2006 (has links)
<i>Pyrenophora teres</i> Drechs. (anamorph: <i>Drechslera teres</i> (Sacc.) Shoem.) is the causal agent of barley net blotch. Net blotch is an economically important disease commonly found throughout the barley producing regions of the world. Significant financial losses result from yield reductions, ranging from 15-35%, and decreased grain quality. Despite its prevalence, it is unclear if the P. teres-barley pathosystem follows a gene-for-gene model, and more generally, little is known about its genetic organization. Three studies were initiated to address these questions.<p>The first study investigated the genetic control of avirulence in <i>P. teres.</i> To establish an appropriate study system, a collection of ten net form (<i>P. teres f. teres</i>) and spot form (<i>P. teres f. maculata</i>) isolates were evaluated on a set of eight differential barley lines to identify two isolates with differential virulence on a specific host line. WRS 1906, exhibiting low virulence on the cultivar Heartland, and WRS 1607, exhibiting high virulence, were mated and 67 progeny were isolated and phenotyped for virulence on Heartland. The population segregated in a 1:1 ratio, 34 avirulent to 33 virulent (Chi-square = 0.0, P = 1.0), indicating single gene control of WRS 1906 avirulence on Heartland. Bulked segregant analysis was used to identify six amplified fragment length polymorphism (AFLP) markers closely linked to the avirulence gene (AvrHeartland). This work provides evidence that the P. teres-barley pathosystem conforms to the gene-for-gene model.<p>In the second study, five isolates of P. teres, representing both net and spot forms, were analyzed by the germ tube burst method (GTBM) and pulsed field gel electrophoresis (PFGE) to determine the species karyotype. Nine chromosomes were observed in all isolates using the GTBM and estimation of chromosome lengths varied from 0.5 to 3.0 µm. PFGE separated 7 to 8 bands depending on isolate, but analysis of bands by densitometry indicated nine chromosomes. Chromosome size ranged from 1.8 to ~6.0 Mb providing a genome size estimate of 32 to 39 Mb. Significant chromosome-length polymorphisms (CLP) were observed between isolates. These CLP did not hinder mating between mating-type compatible net form isolates. No particular CLP or individual chromosome could be associated with differences in disease symptoms observed between pathogen forms. This study provides the first karyotype of both P. teres forms and will assist genetic mapping of this pathogen.<p>A genetic linkage map of <i>P. teres f. teres</i>, was constructed in the third study using the population of 67 progeny derived from the WRS 1906 WRS 1607 cross. The map consists of 138 markers including 114 AFLPs, 21 telomere RFLPs, the mating-type (MAT) locus and an avirulence locus (AvrHeartland) controlling interaction with barley cultivar Heartland. Markers were distributed across 24 linkage groups ranging in length from 2 to 110 cM with an average marker interval of 8.5 cM. The total map length was 797 cM. A telomere-specific probe, consisting of the sequence (TTAGGC)4, was used to map 15 of the 18 telomeres. One of these telomeres mapped to within 3 cM of the AvrHeartland locus. Attempts to consolidate linkage groups by hybridizing markers to the electrophoretically separated chromosomes was unsuccessful because probes bound to multiple chromosomes, likely due to repetitive DNA within the probe. This is the first genetic map reported for this species and it will be a useful genetic tool for map-based cloning of the AvrHeartland gene tagged in this study. <p>This research has provided a number of new insights into the net blotch pathogen and provides a useful research tool in the form of a genetic map. This information lays the foundation for further genetic study of P. teres and will complement studies on barley resistance to net blotch that may potentially lead to more durable resistance.
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The taxonomy, phylogeny and impact of Mycosphaerella species on eucalypts in South-Western Australia /Maxwell, Aaron. January 2004 (has links)
Thesis (Ph.D.)--Murdoch University, 2004. / Thesis submitted to the Division of Science and Engineering. Bibliography: p. 214-231.
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Genomic and Molecular Characterization of Pyrenphora teres f. teresWyatt, Nathan Andrew January 2019 (has links)
Pyrenophora teres f. teres is the causal agent of net form net blotch of barley. P. teres f. teres is prevalent globally across all barley growing regions and globally is the most devastating foliar disease of barley. Though economically important, the molecular mechanism whereby P. teres f. teres causes disease is poorly understood and investigations into these mechanisms have been hindered by a lack of genomic resources. To set a genomic foundation for P. teres f. teres the reference isolate 0-1 was sequenced and assembled using PacBio single molecule real-time (SMRT) sequencing and scaffolded into 12 chromosomes to provide the first finished genome of P. teres f. teres. High confidence gene models were generated for the reference genome of isolate 0-1 using a combination of pure culture and in planta RNA sequencing. An additional four P. teres f. teres isolates were sequenced and assembled to the same quality as the reference isolate 0-1 and used in a comparative genomic study. Comparisons of the five P. teres f. teres isolates showed a two-speed genome architecture with the genome being partitioned into core and accessory genomic compartments. Accessory genomic compartments clustered in sub-telomeric regions of the P. teres f. teres genome with a majority of previously identified quantitative trait loci (QTL) associated with avirulence/virulence being spanned by these accessory regions. Using these genomic resources, with a bi-parental mapping population and a natural population for QTL analysis and genome wide association study (GWAS), respectively, we identified a candidate gene for the previously mapped AvrHar. QTL analysis identified a locus extending off the end of P. teres f. teres chromosome 5 and GWAS analysis identified significant associations with a gene encoding a small secreted protein. The candidate AvrHar gene was validated using CRISPR-Cas9-RNP gene disruption in parental isolates 15A and 0-1. Disruption of AvrHar in isolate 15A did not result in a phenotypic change while disruption of the 0-1 allele resulted in a complete loss of pathogenicity. This is the first identification of an effector from P. teres f. teres validated using CRISPR-Cas9-RNP gene editing. / North Dakota Barley Council
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Specificity of quantitatively expressed host resistance to Mycosphaerella graminicola /Krenz, Jennifer E. January 2007 (has links)
Thesis (M.S.)--Oregon State University, 2007. / Printout. Includes bibliographical references (leaves 41-47). Also available on the World Wide Web.
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