Genomic and Molecular Characterization of Pyrenphora teres f. teres

Wyatt, Nathan Andrew

January 2019

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

barley

fungal genomics

net blotch

pyrenophora

Mold Allergomics: Comparative and Machine Learning Approaches

Dang, Ha Xuan

05 June 2014

Fungi are one of the major organisms that cause allergic disease in human. A number of proteins from fungi have been found to be allergenic or possess immunostimulatory properties. Identifying and characterizing allergens from fungal genomes will help facilitate our understanding of the mechanism underlying host-pathogen interactions in allergic diseases. Currently, there is a lack of tools that allow us to rapidly and accurately predict allergens from whole genomes. In the context of whole genome annotation, allergens are rare compared to non-allergens and thus the data is considered highly skewed. In order to achieve a confident set of predicted allergens from a genome, false positive rates must be lowered. Current allergen prediction tools often produce many false positives when applied to large-scale data set such as whole genomes, and thus lower the precision. Moreover, the most accurate tools are relatively slow because they use sequence alignment to construct feature vectors for allergen classifiers. This dissertation presents computational approaches in characterizing the allergen repertoire in fungal genomes as part of the whole genome studies of Alternaria, an important allergenic/opportunistic human pathogenic fungus and necrotrophic plant parasite. In these studies, the genomes of multiple Alternaria species were characterized for the first time. Functional elements (e.g. genes, proteins) were first identified and annotated from these genomes using computational tools. Protein annotation and comparative genomics approaches revealed the link between Alternaria genotypes and its prolific saprophytic lifestyle that provides at least a partial explanation for the development of pathological relationships between Alternaria and humans. A machine learning based tool (Allerdictor) was developed to address the neglected problem of allergen prediction in highly skewed large-scale data sets. Allerdictor exhibited high precision over high recall at fast speed and thus it is a more practical tool for large-scale allergen annotation compared with existing tools. Allerdictor was then used together with a comparative genomics approach to survey the allergen repertoire of known allergenic fungi. We predicted a number of mold allergens that have not been experimentally characterized. These predicted allergens are potential candidates for further experimental and clinical validation. Our approaches will not only facilitate the study of allergens in the increasing number of sequenced fungal genomes but also will be useful for allergen annotation in other species and rapid prescreening of synthesized sequences for potential allergens. / Ph. D.

Fungal genomics

comparative genomics

allergy

allergen prediction

Genotypic and Phenotypic Characterization of <i>Penicillium marneffei</i> Mutants Produced by <i>Agrobacterium</i>-Mediated Transformation

Price, Eric C.

02 July 2012

No description available.

Biology

fungal genomics

fungal dimorphism

agrobacterium-mediated transformation

fungal pathogens