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ARS Home » Northeast Area » Beltsville, Maryland (BARC) » Beltsville Agricultural Research Center » Mycology and Nematology Genetic Diversity and Biology Laboratory » Research » Research Project #432548

Research Project: Enhancing Plant Protection through Fungal Systematics

Location: Mycology and Nematology Genetic Diversity and Biology Laboratory

Project Number: 8042-22000-298-000-D
Project Type: In-House Appropriated

Start Date: Apr 15, 2017
End Date: Apr 14, 2022

Objective:
Objective 1: Identify genotypes and species limits of emerging, invasive or other pathogenic fungal species associated with plants and plant pests. [NP303, C1, PS1] Objective 2: Develop systematic resources for agriculturally important fungi, including diagnostic methods, genome sequences and phylogenies. [NP303, C1, PS1]

Approach:
Emerging, insect, and quarantine-significant pathogenic fungi in historically understudied groups important to U.S. agriculture will be studied using cutting edge molecular technologies to determine species boundaries, phylogenetic relationships and gene regions most useful for diagnostic methods development. Fungi to be studied include smut species closely related to the flag smut of wheat pathogen (Urocystis tritici), rust species on imported plants, and downy mildew species in the genera Peronospora and Plasmopora. Anthracnose, canker, and leaf spot fungi in various ascomycete genera will be studied as they emerge in pathogenic situations. For determining initial identities and superficial relationships of non-insect associated fungi, the ITS regions of the nuclear ribosomal repeat unit will be sequenced, compared with existing data, and correlated with morphological data. Insect-associated fungi will be screened utilizing nuclear intergenic regions Bloc for Beauveria, MzIGS3 for Metarhizium, and RPB1 for Lecanicillium and Simplicillium. ITS, LSU, tef1-a, beta-tub, and rpb gene regions will be analyzed to determine species boundaries and phylogenetic relationships for canker and anthracnose fungi. The genetic diversity of insect-pathogenic species in Beauveria, Lecanicillium, and Metarhizium in soil and other habitats will be determined through both culture and direct DNA sequencing methodologies. Soils will be sampled for insect-associated fungi from agricultural fields and natural habitats from the mid-Atlantic region. Candidate intergenic sequences that minimize both amplicon length (500-700 bp) and percentage gapped sites while simultaneously maximizing the average pairwise divergence and the proportion of parsimony informative sites will be evaluated for utility. Genomic libraries for agriculturally important fungi including Diaporthe, Plasmopara, Pseudoperonospora, Neonectria, Sclerotinia, Microdochium and Urocystis will be prepared utilizing current kit-based technologies and sequenced on an Illumina MiSeq sequencer or other platforms as they become available. Sequence reads will be processed and assembled using bioinformatics software packages or custom-developed software as appropriate. New markers will be identified using a comparative genomic approach or through whole genome-scale comparative analysis of all single copy orthologous proteins. It is expected that species previously unknown to science will be described, illustrated, and characterized. Expected outputs include diagnostic assays, DNA sequences, digital images, monographs, and phylogenies for fungi important as insect or plant pathogens. Knowledge gained will enable development and enhancement of resources critical for effective disease management strategies and for making sound plant quarantine and biocontrol decisions.