Generalist Predators, Food Web Complexities and Biological Pest Control in Greenhouse Crops

AbstractEcological communities used in biological pest control are usually represented as three-trophic level food chains with top-down control. However, at least two factors complicate this simple way of characterizing agricultural communities. First, agro-ecosystems are composed of several interacting species forming complicated food webs. Second, the structure of agricultural communities may vary in time. Efficient pest management approaches need to integrate these two factors to generate better predictions for pest control. In this work, we identified the food web components of an avocado agro-ecosystem, and unravelled patterns of co-occurrence and interactions between these components through field and laboratory experiments. This allowed us to predict community changes that would improve the performance of the naturally occurring predators and to test these predictions in field population experiments. Field surveys revealed that the food-web structure and species composition of the avocado community changed in time. In spring, the community was characterized by a linear food chain ofEuseius stipulatus, an omnivorous mite, feeding on pollen. In the summer,E. stipulatusand a predatory mite,Neoseiulus californicus, shared a herbivorous mite prey. Laboratory experiments confirmed these trophic interactions and revealed thatN. californicuscan feed inside the prey nests, whereasE. stipulatuscannot, which may further reduce competition among predators. Finally, we artificially increased the coexistence of the two communities via addition of the non-herbivore food source (pollen) for the omnivore. This led to an increase in predator numbers and reduced populations of the herbivore. Therefore, the presence of pollen is expected to improve pest control in this system.

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Omnivorous predators for biological pest control in greenhouse crops

10.18174/373599 ◽

2016 ◽

Cited By ~ 1

Author(s):

B.L. Ingegno ◽

◽

G.J. Messelink

Keyword(s):

Pest Control ◽

Biological Pest Control ◽

Greenhouse Crops ◽

Omnivorous Predators

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Prey removal in cotton crops next to woodland reveals periodic diurnal and nocturnal invertebrate predation gradients from the crop edge by birds and bats

Scientific Reports ◽

10.1038/s41598-021-84633-8 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Heidi L. Kolkert ◽

Rhiannon Smith ◽

Romina Rader ◽

Nick Reid

Keyword(s):

Pest Control ◽

Open Space ◽

Optimal Foraging Theory ◽

Time Of Day ◽

Camera Traps ◽

Generalist Predators ◽

Crop Cover ◽

Foraging Preferences ◽

Experimental Feeding ◽

Natural Pest Control

AbstractFactors influencing the efficacy of insectivorous vertebrates in providing natural pest control services inside crops at increasing distances from the crop edge are poorly understood. We investigated the identity of vertebrate predators (birds and bats) and removal of sentinel prey (mealworms and beetles) from experimental feeding trays in cotton crops using prey removal trials, camera traps and observations. More prey was removed during the day than at night, but prey removal was variable at the crop edge and dependent on the month (reflecting crop growth and cover) and time of day. Overall, the predation of mealworms and beetles was 1-times and 13-times greater during the day than night, respectively, with predation on mealworms 3–5 times greater during the day than night at the crop edge compared to 95 m inside the crop. Camera traps identified many insectivorous birds and bats over crops near the feeding trays, but there was no evidence of bats or small passerines removing experimental prey. A predation gradient from the crop edge was evident, but only in some months. This corresponded to the foraging preferences of open-space generalist predators (magpies) in low crop cover versus the shrubby habitat preferred by small passerines, likely facilitating foraging away from the crop edge later in the season. Our results are in line with Optimal Foraging Theory and suggest that predators trade-off foraging behaviour with predation risk at different distances from the crop edge and levels of crop cover. Understanding the optimal farm configuration to support insectivorous bird and bat populations can assist farmers to make informed decisions regarding in-crop natural pest control and maximise the predation services provided by farm biodiversity.

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Landscape-scale approaches for enhancing biological pest control in agricultural systems

Environmental Monitoring and Assessment ◽

10.1007/s10661-020-08812-2 ◽

2021 ◽

Vol 193 (S1) ◽

Author(s):

Sandrine Petit ◽

Violaine Deytieux ◽

Stéphane Cordeau

Keyword(s):

Pest Control ◽

Landscape Scale ◽

Agricultural Systems ◽

Biological Pest Control

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Unexpected Effects of Local Management and Landscape Composition on Predatory Mites and Their Food Resources in Vineyards

Insects ◽

10.3390/insects12020180 ◽

2021 ◽

Vol 12 (2) ◽

pp. 180

Author(s):

Stefan Möth ◽

Andreas Walzer ◽

Markus Redl ◽

Božana Petrović ◽

Christoph Hoffmann ◽

...

Keyword(s):

Pest Control ◽

Predatory Mites ◽

Mite Species ◽

Landscape Composition ◽

Pesticide Use ◽

Biological Pest Control ◽

Phytophagous Mites ◽

Spontaneous Vegetation ◽

Important Food Source ◽

Eriophyoid Mite

Viticultural practices and landscape composition are the main drivers influencing biological pest control in vineyards. Predatory mites, mainly phytoseiid (Phytoseiidae) and tydeoid mites (Tydeidae), are important to control phytophagous mites (Tetranychidae and Eriophyidae) on vines. In the absence of arthropod prey, pollen is an important food source for predatory mites. In 32 paired vineyards located in Burgenland/Austria, we examined the effect of landscape composition, management type (organic/integrated), pesticide use, and cover crop diversity of the inter-row on the densities of phytoseiid, tydeoid, and phytophagous mites. In addition, we sampled pollen on vine leaves. Typhlodromus pyri Scheuten was the main phytoseiid mite species and Tydeus goetzi Schruft the main tydeoid species. Interestingly, the area-related acute pesticide toxicity loading was higher in organic than in integrated vineyards. The densities of phytoseiid and tydeoid mites was higher in integrated vineyards and in vineyards with spontaneous vegetation. Their population also profited from an increased viticultural area at the landscape scale. Eriophyoid mite densities were extremely low across all vineyards and spider mites were absent. Biological pest control of phytophagous mites benefits from less intensive pesticide use and spontaneous vegetation cover in vineyard inter-rows, which should be considered in agri-environmental schemes.

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Biological Pest Control in Mexico

Annual Review of Entomology ◽

10.1146/annurev-ento-120811-153552 ◽

2013 ◽

Vol 58 (1) ◽

pp. 119-140 ◽

Cited By ~ 30

Author(s):

Trevor Williams ◽

Hugo C. Arredondo-Bernal ◽

Luis A. Rodríguez-del-Bosque

Keyword(s):

Pest Control ◽

Biological Pest Control

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Computational Fluid Dynamics Modelling of the Microclimate within the Boundary Layer of Leaves Leading to Improved Pest Control Management and Low-Input Greenhouse

Sustainability ◽

10.3390/su13158310 ◽

2021 ◽

Vol 13 (15) ◽

pp. 8310

Author(s):

Hicham Fatnassi ◽

Thierry Boulard ◽

Christine Poncet ◽

Nikolaos Katsoulas ◽

Thomas Bartzanas ◽

...

Keyword(s):

Boundary Layer ◽

Pest Control ◽

Fluid Dynamic ◽

Natural Habitat ◽

Greenhouse Production ◽

Greenhouse Crops ◽

Leaf Surfaces ◽

Measurement Tools ◽

Use Efficiency ◽

Control Management

This work aims at using the Computational Fluid Dynamic (CFD) approach to study the distributed microclimate in the leaf boundary layer of greenhouse crops. Understanding the interactions in this microclimate of this natural habitat of plant pests (i.e., boundary layer of leaves), is a prerequisite for their control through targeted climate management for sustainable greenhouse production. The temperature and humidity simulations, inside the greenhouse, were performed using CFD code which has been adapted to simulate the plant activity within each mesh in the crop canopy. The air temperature and air humidity profiles within the boundary layer of leaves were deduced from the local surrounding climate parameters, based on an analytical approach, encapsulated in a Used Defined Function (UDF), and dynamically linked to the CFD solver, a work that forms an innovative and original task. Thus, this model represents a new approach to investigate the microclimate in the boundary layer of leaves under greenhouses, which resolves the issue of the inaccessibility of this area by the conventionnel measurement tools. The findings clearly showed that (i) contrarily to what might be expected, the microclimate parameters within the boundary layer of leaves are different from the surrounding climate in the greenhouse. This is particularly visible during photoperiods when the plant’s transpiration activity is at its maximum and that (ii) the climatic parameters in the leaf boundary layer are more coupled with leaf surfaces than with those of greenhouse air. These results can help developing localized intervention strategies on the microclimate within boundary layer of plant leaves, leading to improved and sustainable pest control management. The developed climatic strategies will make it possible to optimize resources use efficiency.

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