Natural enemy composition rather than richness determines pest suppression

Natural enemy (NE) biodiversity is thought to play an important role in agricultural pest suppression. However, the relative importance of the number of NE species (species richness), versus the particular combinations of species (species composition), in determining aphid suppression and ultimately...

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Bibliographic Details
Published in:BioControl (Dordrecht, Netherlands) Netherlands), 2018-08, Vol.63 (4), p.575-584
Main Authors: Alhadidi, Sanaa N., Griffin, John N., Fowler, Mike S.
Format: Article
Language:English
Subjects:
Acyrthosiphon pisum
Adalia bipunctata
Agriculture
Animal Biochemistry
Animal Ecology
Aphidius ervi
Aquatic insects
Behavioral Sciences
Biodiversity
Biological control
Biomass
Biomedical and Life Sciences
Broad beans
Chrysoperla carnea
Composition effects
Crop yield
Entomology
Experiments
Greenhouses
Herbivores
Insects
Larvae
Life Sciences
Natural enemies
Parasitoids
Pest control
Pests
Plant biomass
Plant Pathology
Planting density
Predation
Roles
Species composition
Species richness
Vicia faba
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Summary:Natural enemy (NE) biodiversity is thought to play an important role in agricultural pest suppression. However, the relative importance of the number of NE species (species richness), versus the particular combinations of species (species composition), in determining aphid suppression and ultimately crop yields, remains poorly understood. We tested the effects of NE richness and composition on pea aphids Acyrthosiphon pisum (Harris) and broad bean plants Vicia faba (Linn.). We used the larvae of two predator species, the ladybird Adalia bipunctata (Linn.) and the green lacewing Chrysopa carnea (Stephens), and the parasitic wasp Aphidius ervi (Haliday) as enemies. NEs generally reduced aphid density but did not increase final plant biomass, despite a significant negative correlation between aphid density and plant biomass. Among NE treatments, species richness had an inconsistent effect on aphid density. The composition of NEs within richness levels also affected final aphid density: the ladybird was a key species among the treatments in controlling aphid density and was especially effective in combination with the parasitoid. This ladybird/parasitoid combination also appeared to drive the higher level of suppression observed at the two, relative to three, species richness levels. Although these three species of aphid NEs are commonly used in aphid control, this is the first study, to our knowledge, that simultaneously examined these three species and highlighted the composition effect between the A. bipunctata and A. ervi . In conclusion, increasing NE species richness had an inconsistent effect on aphid density. Meanwhile, the presence of a key species (the ladybird) and its combination with a parasitoid was an important determinant of aphid biological control.
ISSN:1386-6141
1573-8248
DOI:10.1007/s10526-018-9870-z