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ARS Home » Pacific West Area » Corvallis, Oregon » Horticultural Crops Production and Genetic Improvement Research Unit » Research » Publications at this Location » Publication #400074

Research Project: Water and Nutrient Management for Sustainable Production of Small Fruit and Nursery Crops

Location: Horticultural Crops Production and Genetic Improvement Research Unit

Title: Temperature and fungicide sensitivity in three prevalent Phytophthora species causing Phytophthora root rot in rhododendron

Author
item Scagel, Carolyn
item Weiland, Gerald - Jerry
item Beck, Bryan
item Mitchell, Jesse

Submitted to: Plant Disease
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 3/2/2023
Publication Date: 3/7/2023
Citation: Scagel, C.F., Weiland, G.E., Beck, B.R., Mitchell, J.N. 2023. Temperature and fungicide sensitivity in three prevalent Phytophthora species causing Phytophthora root rot in rhododendron. Plant Disease. https://doi.org/10.1094/pdis-11-22-2670-re.
DOI: https://doi.org/10.1094/pdis-11-22-2670-re

Interpretive Summary: Phytophthora root rot causes major losses in nursery crops. There is speculation that increased temperatures from global climate change may increase disease risk from pathogens that thrive under these conditions. There are few studies that compare the effects of temperature on Phytophthora species that are important to the nursery industry. To address this, we conducted a series of experiments to evaluate how temperature affects the biology and control of three soilborne Phytophthora species prevalent in the nursery industry. Our findings help define the temperatures at which these pathogens will be the most damaging and help delineate the temperatures at which fungicides should be applied for maximum efficacy. An important environmental goal for the nursery industry is to reduce environmental impact from chemical treatments; therefore determining optimal temperatures for fungicide application not only reduces financial costs of production but also decreases environmental impact.

Technical Abstract: Temperature is an important environmental variable affecting Phytophthora species biology. It alters the ability species to grow, sporulate, and infect their plant host, and it is also important in mediating pathogen responses to disease control measures. Average global temperatures are increasing as a consequence of climate change. Yet, there are few studies that compare the effects of temperature on Phytophthora species that are important to the nursery industry. To address this, we conducted a series of experiments to evaluate how temperature affects the biology and control of three soilborne Phytophthora species prevalent in the nursery industry. In the first set of experiments, we evaluated the mycelial growth and sporulation of several P. cinnamomi, P. plurivora, and P. pini isolates at temperatures ranging from 4 to 42°C for different amounts of time (0-120 h). In the second set of experiments, we evaluated the response of three isolates of each species to the fungicides mefenoxam and phosphorous acid at temperatures ranging from 6 to 40°C. Results showed that each species responds differently to temperature, with P. plurivora having the greatest optimal temperature (26.6°C), P. pini the least (24.4°C), and P. cinnamomi between the two (25.3°C). P. plurivora and P. pini had the lowest minimum temperatures (~2.4°C) compared to P. cinnamomi (6.5°C), while all three species had a similar maximum temperature (~35°C). When tested against mefenoxam, all three species were generally more sensitive to mefenoxam at cool temperatures (6-14°C) than at warmer temperatures (22-30°C). P. cinnamomi was also more sensitive to phosphorous acid at cool temperatures 6-14°C. However, both P. plurivora and P. pini tended to be more sensitive to phosphorous acid at warmer temperatures (22-30°C). These findings help define the temperatures at which these pathogens will be the most damaging and help delineate the temperatures at which fungicides should be applied for maximum efficacy.