Wind dispersal of Puccinia psidii urediniospores and progress of eucalypt rust

To identify and implement Puccinia psidii control strategies, it is essential to understand the role of environmental factors on rust‐disease development and spread among eucalypt (Eucalyptus spp.) plantations. In this study, we evaluated the wind dispersal of P. psidii urediniospores and the progre...

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Published in:Forest pathology = Journal de pathologie forestière = Zeitschrift für Forstpathologie 2015-04, Vol.45 (2), p.102-110
Main Authors: Zauza, E. A. V, Lana, V. M, Maffia, L. A, Araujo, M. M. F. C, Alfenas, R. F, Silva, F. F, Alfenas, A. C, Klopfenstein, N. B
Format: Article
Language:English
Subjects:
air
branches
correlation
disease incidence
environmental factors
Eucalyptus
field experimentation
leaves
light intensity
meteorological data
plantations
Puccinia
Puccinia psidii
rain
relative humidity
temperature
time series analysis
urediniospores
wind speed
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Summary:To identify and implement Puccinia psidii control strategies, it is essential to understand the role of environmental factors on rust‐disease development and spread among eucalypt (Eucalyptus spp.) plantations. In this study, we evaluated the wind dispersal of P. psidii urediniospores and the progress of eucalypt rust in a field trial in Brazil. Urediniospores of P. psidii were trapped in a Burkard®spore trap from July 2004 to June 2005. To evaluate the progress of eucalypt rust, plots were established in March 2002 using a clonal hedge scheme. The incidence of both branches and leaves with rust was assessed weekly from February 2003 to October 2005. Disease progress was studied using time‐series analysis. Urediniospores were trapped on 77% of the days sampled. The highest average urediniospore concentration was detected from July to November, and most of the urediniospores (58%) were trapped at night. Urediniospore concentration was negatively correlated with rainfall, light intensity, minimum, average and maximum temperatures and wind speed, whereas urediniospore concentration was positively correlated with leaf‐wetness duration and relative humidity. From December 2004 to June 2005, average urediniospore concentration was 0.22 spores m⁻³ air h⁻¹and had no correlation with meteorological data. The highest average urediniospore concentration was associated with a combination of low average temperature, low light intensity, low wind speed, high relative humidity and high leaf wetness, which reflect conditions observed at night. The disease incidence was positively correlated with the urediniospores trapped at 12 days prior to disease assessment. According to the models obtained by the time series, a seasonal yearly effect was found on rust progress. Using our models, we were also able to forecast disease incidence up to 3 months after the last field assessment.
ISSN:1437-4781
1439-0329
DOI:10.1111/efp.12133