Modelling of the spread of Dothistroma septosporum in Europe

Summary Dothistroma needle blight (DNB), a disease affecting several pine species, is currently generating great concern in Europe. Caused by Dothistroma pini and Dothistroma septosporum, DNB affects pine needles and causes premature defoliation, which results in growth reduction and, in extreme cas...

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Bibliographic Details
Published in:Forest pathology = Journal de pathologie forestière = Zeitschrift für Forstpathologie 2017-06, Vol.47 (3), p.n/a
Main Authors: Möykkynen, T., Fraser, S., Woodward, S., Brown, A., Pukkala, T., Cleary, M.
Format: Article
Language:English
Subjects:
Blight
Computer simulation
Defoliation
Dispersal
Dispersion
Dothistroma pini
Dothistroma septosporum
Forests
Infections
invasive pathogen
Mathematical models
Mist
Mortality
Needle blight
Outbreaks
pathogen pathways
Pest outbreaks
Pine
Pine needles
Pine trees
Prevention
red band needle blight
Seedlings
Simulation
spatiotemporal model
Spores
spread model
Transport
Trees
Wind
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Summary:Summary Dothistroma needle blight (DNB), a disease affecting several pine species, is currently generating great concern in Europe. Caused by Dothistroma pini and Dothistroma septosporum, DNB affects pine needles and causes premature defoliation, which results in growth reduction and, in extreme cases, mortality. The disease has increased in importance in Europe over the last 20 years, with an increase in the number of observations of DNB in regions with large areas of Pinus sylvestris in northern Europe. This article presents a cell‐based spatiotemporal model for predicting the likelihood and intensity of the future spread of D. septosporum in Europe. Here, “spread” includes both invasion of new regions and infection of healthy stands within already‐colonized regions. Predicted spread depends on the availability of host species, climatic suitability of different regions to D. septosporum and dispersal of sexual and asexual spores from infected trees to surrounding forests via water splash, mist and wind. Long‐distance spread through transport of infected seedlings is also included in the model. Simulations of spread until 2007 and 2015 were used to validate the model. These simulations produced similar patterns of spread to those observed in Europe. Simulations for 2030 suggested that additional and new outbreaks are likely to occur in Scotland, southern Norway, southern and central Sweden, northern parts of Germany and Poland, Estonia, Latvia and south‐west Finland. Preventing the delivery of infected seedlings would be an effective method for reducing the spread of D. septosporum in the Nordic countries, Scotland and Ireland, the Baltic countries, and parts of Germany, Poland and Belarus. In these states, prevention of transport of infected seedlings can reduce the probability of additional spread by 15%–40%.
ISSN:1437-4781
1439-0329
DOI:10.1111/efp.12332