1 |
Determining Fitness Cost in Qoi-Resistant Isolates of the Frogeye Leaf Spot PathogenBrochard, Nicole Rochelle 06 May 2017 (has links)
Frogeye leaf spot is a foliar disease of soybean caused by Cercospora sojina Hara, which until recently had been successfully managed by quinone outside inhibitor (QoI) fungicides. After widespread resistance to the QoI fungicides was reported throughout Mississippi, the next step in characterizing C. sojina was to study the fitness of selected isolates. Fitness measurements of resistance stability, colony growth, conidia production and germination, and virulence were assessed. A phylogenetic analysis was also conducted to assess the genetic similarity of the QoI-resistant and -sensitive C. sojina isolates. All isolates remained stable in terms of QoI resistance. Results of all fitness measurements indicated no significant differences between the QoI-resistant and -sensitive C. sojina isolates. The phylogenetic analysis supported these results revealing similarity between QoI-resistant and -sensitive C. sojina isolates. Based on these results no indication of a fitness cost is associated with QoI resistance in C. sojina isolates from Mississippi soybean.
|
2 |
Genotypic characterization and fungicide resistance monitoring for Virginia populations of Parastagonospora nodorum in wheatKaur, Navjot 28 June 2021 (has links)
Stagonospora nodorum blotch (SNB), is a major foliar disease of wheat in the mid-Atlantic U.S., is caused by the necrotrophic fungus Parastagonospora nodorum. SNB is managed using cultural practices, resistant varieties, and foliar fungicides. There are increasing trends of severity and incidence of SNB in Virginia and the surrounding mid-Atlantic region, but it is not known if changes in the pathogen population are contributing to this trend. The overall goal of this research was to 1) determine the occurrence of quinone outside inhibitor (QoI) resistance in Virginia populations of P. nodorum infecting wheat, 2) quantify the distribution of G143A mutations conferring fungicide resistance in Virginia populations of P. nodorum, and 3) characterize genetic diversity of P. nodorum populations in Virginia and assess influences of cultivars and environments on population structure and SNB severity. For Objective 1, QoI resistant isolates of P. nodorum were identified from Virginia wheat fields, and this was the first report of QoI resistant P. nodorum in the United States. The G143A substitution in the cytochrome b gene of P. nodorum was associated with reduced QoI sensitivity, and in Objective 2, a state-wide, two-year survey of P. nodorum populations in Virginia determined that the G143A mutation was widespread in the state and among sampled fields the frequency ranged from 5-32% (mean = 19%). For Objective 3, P. nodorum was isolated from five different wheat cultivars across seven locations over two years in Virginia. SNB severity varied by cultivar but greater differences in disease severity were observed among locations and years suggesting environment plays an important role in SNB development. Among the necrotrophic effector (NE) genes examined, SnTox1 was predominant followed by SnTox3, and frequencies of NE genes did not vary by cultivar or location. P. nodorum populations in Virginia had high genetic diversity, but there was no genetic subdivision among locations or wheat cultivars from which individuals were isolated. Results also indicated that the P. nodorum population in Virginia undergoes a mixed mode of reproduction, but sexual reproduction made the greatest contribution to population structure. Overall, this work provides insights into the population biology of P. nodorum in Virginia and information on variability in fungicide sensitivity and cultivar susceptibility to SNB that has implications for the current and future efficacy of fungicides and host resistance for management of SNB. / Doctor of Philosophy / Wheat (Triticum aestivum L.) is one of the major cereal crops grown worldwide for food, feed, and other products. However, yields of this crop are often limited by fungal diseases including Stagonospora nodorum blotch (SNB) caused by Parastagonospora nodorum. Increasing trends of severity and incidence of SNB may be due to reduced sensitivity of P. nodorum to fungicides or increased virulence of P. nodorum populations on commonly grown cultivars. Fungicides such as quinone outside inhibitors (QoIs) are one of the major classes of fungicides used for disease control and G143A substitution is the most common point mutation associated with complete resistance to QoIs. Therefore, the overall goal of this research was to better understand genotypic and phenotypic variation in Virginia populations of P. nodorum in the context of fungicide sensitivity and susceptibility of wheat cultivars to SNB. The specific objectives were to 1) determine the occurrence of quinone outside inhibitor (QoI) fungicide resistance in Virginia populations of P. nodorum infecting wheat, 2) quantify the distribution of G143A mutations conferring QoI fungicide resistance in Virginia populations of P. nodorum, and 3) characterize genetic diversity of P. nodorum populations in Virginia and assess influences of cultivars and environments on population structure and SNB severity. Results from this research indicate that QoI fungicide resistance occurs in Virginia populations of P. nodorum due to a target site mutation (G143A substitution in the cytochrome b gene), and this mutation is widespread and relatively common in Virginia wheat fields. Based on a multi-year multilocation study, P. nodorum populations were genetically diverse, but there was no genetic subdivision among locations or wheat cultivars. SNB severity varied by location and cultivar, but disease severity was greatest at site-years with moderate springtime temperatures and high rainfall. Overall, this work contributes to a better understanding of P. nodorum populations including the current efficacy of fungicides and host resistance for management of SNB in the region.
|
3 |
FUNGICIDE TIMING, RESISTANCE MONITORING, AND PHYTOPATHOMETRY FOR FIELD CROP DISEASES IN INDIANAKaitlin G Waibel (15353782) 26 April 2023 (has links)
<p> </p>
<p>Protecting crops from disease requires continuous research because plant pathogen incidence, geographical range, and pathogenicity, are constantly shifting variables as agronomic practices and climate continue to evolve. The objectives of this research are to i.) evaluate field-scale fungicide timing programs for corn (<em>Zea mays L.</em>) diseases at multiple locations in Indiana; ii.) evaluate field-scale fungicide timing programs for soybean (<em>Glycine Max</em> (L.) Merr.) diseases at multiple locations in Indiana; iii.) continue to identify, document, and confirm the distribution of populations of the soybean frogeye leaf spot pathogen (<em>Cercospora sojina)</em> that contain the G143A mutation conferring resistance to quinone outside inhibitor (QoI) fungicides in Indiana; and iv.) assess the incidence, severity, and prevalence of tar spot (<em>Phyllachora maydis</em>) in Indiana. For the first and second objectives, field scale trials were established at three locations in Indiana from 2019 to 2022. No application timings at any location provided significant yield protection for corn or soybeans. To achieve the third objective, 165 isolates of <em>C. Sojina </em>were tested. In total, 24 out of the 32 counties sampled in 2021 and 2022 were documented with QoI-resistance. The fourth objective was accomplished by surveying Indiana counties for incidence and severity of tar spot. As of 2022, 86 out of 92 Indiana counties have been confirmed for the presence of tar spot.</p>
|
Page generated in 0.0797 seconds