Application of a Mechanistic Model to Explore Management Strategies for Biological Control of an Agricultural Pest

Application of a Mechanistic Model to Explore Management Strategies for Biological Control of an Agricultural Pest

Despite the known benefits of integrated pest management, adoption in Australian broadacre crops has been slow, in part due to the lack of understanding about how pests and natural enemies interact. We use a previously developed process-based model to predict seasonal patterns in the population dyna...

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Bibliographic Details
Published in:Agriculture (Basel) Vol. 14; no. 1; p. 150
Main Authors: Barton, Madeleine G., Parry, Hazel, Umina, Paul A., Binns, Matthew R., Heddle, Thomas, Hoffmann, Ary A., Holloway, Joanne, Severtson, Dustin, Van Helden, Maarten, Ward, Samantha, Wood, Rachel, Macfadyen, Sarina
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-01-2024
Subjects:
Agricultural pests
Agricultural practices
Animal behavior
Aphididae
Australia
Biological control
Candidate species
Canola
Chemical control
Chemical pest control
Crops
Density ratio
Diaeretiella rapae
Insects
Integrated pest management
integrated pest management (IPM)
Kehoe, Stasia Ward
Myzus persicae
Natural enemies
Natural resources
Outbreaks
Pest control
Pesticide application
Pesticides
Pests
Phenology
Population biology
Population dynamics
population models
Seasonal variations
Seeds
Simulation
Simulation methods
Wasps
Australia
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Summary:Despite the known benefits of integrated pest management, adoption in Australian broadacre crops has been slow, in part due to the lack of understanding about how pests and natural enemies interact. We use a previously developed process-based model to predict seasonal patterns in the population dynamics of a canola pest, the green peach aphid (Myzus persicae), and an associated common primary parasitic wasp (Diaeretiella rapae), found in this cropping landscape. The model predicted aphid population outbreaks in autumn and spring. Diaeretiella rapae was able to suppress these outbreaks, but only in scenarios with a sufficiently high number of female wasps in the field (a simulated aphid:wasp density ratio of at least 5:1 was required). Model simulations of aphid-specific foliar pesticide applications facilitated biological control. However, a broad-spectrum pesticide negated the control provided by D. rapae, in one case leading to a predicted 15% increase in aphid densities compared to simulations in which no pesticide was applied. Biological and chemical control could therefore be used in combination for the successful management of the aphid while conserving the wasp. This modelling framework provides a versatile tool for further exploring how chemical applications can impact pests and candidate species for biological control.
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture14010150