Variations in Community Assemblages and Trophic Networks of Aphids And

Variations in Community Assemblages and Trophic Networks of Aphids And

Variations in community assemblages and trophic networks of aphids and parasitoids in protected crops Estelle Postic, Anne Le Ralec, Christelle Buchard, Caroline Granado, Yannick Outreman To cite this version: Estelle Postic, Anne Le Ralec, Christelle Buchard, Caroline Granado, Yannick Outreman. Varia- tions in community assemblages and trophic networks of aphids and parasitoids in protected crops. Ecosphere, Ecological Society of America, 2020, 1 (5), pp.e03126. 10.1002/ecs2.3126. hal-02571710 HAL Id: hal-02571710 https://hal-agrocampus-ouest.archives-ouvertes.fr/hal-02571710 Submitted on 13 May 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Distributed under a Creative Commons Attribution| 4.0 International License AGROECOSYSTEMS Variations in community assemblages and trophic networks of aphids and parasitoids in protected crops 1,2 1, 3 ESTELLE POSTIC , ANNE LE RALEC , CHRISTELLE BUCHARD, 2 1 CAROLINE GRANADO, AND YANNICK OUTREMAN 1UMR IGEPP, Agrocampus Ouest, INRAE, Universite de Rennes 1, Rennes 35000 France 2AOPn Fraises de France, Estillac 47310 France 3UMR IGEPP, Agrocampus Ouest, INRAE, Universite de Rennes 1, Le Rheu 35650 France Citation: Postic, E., A. Le Ralec, C. Buchard, C. Granado, and Y. Outreman. 2020. Variations in community assemblages and trophic networks of aphids and parasitoids in protected crops. Ecosphere 11(5):e03126. 10.1002/ecs2.3126 Abstract. Greenhouse crops are thought to be simplified ecosystems because they often consist of mono- cultures that are relatively isolated from their environment. However, insect pests are still able to colonize these protected crops, which threaten their yields. Similarly, natural enemies of pests may be able to colonize greenhouses, providing a form of natural biological pest control. Protected strawberry crops are grown in several types of greenhouses that vary in their degree of openness. Crops often suffer from aphid outbreaks, which can be partly controlled by insect parasitoids immigrating from the surrounding environment. We investigated variations over space and time in both the aphid and parasitoid community diversity and spe- cies assemblages associated with protected strawberry crops. We sampled aphids and parasitoids in five regions of France in the spring and summer of two successive years. Despite the relative isolation of these protected crops, we identified a high aphid species richness in them, even at the greenhouse scale. Aphid community composition varied with spatial and temporal factors, but the species assemblages present were mostly determined by local factors. Parasitoid communities were mostly similar among the studied regions, but varied between seasons, with this temporal variation being related to changes in aphid species composi- tion. The study of trophic interactions occurring between aphids and parasitoids allowed the most prevalent and efficient parasitoid species to be identified. The structures of food webs strongly varied in time and space, compromising any prediction of “natural” biological control. We also highlighted ecological factors that can disrupt aphid biological control, such as the occurrence of hyperparasitism or the possibility of apparent mutualism between aphid species. Finally, we showed that the degree of openness of greenhouses influenced both the aphid communities and the hyperparasitism rates in them. These results provide valu- able information to improve aphid biological control in protected crops. Key words: biological control; direct and indirect interactions; insect pests; natural enemies; spatiotemporal variation; strawberry crops. Received 5 November 2019; revised 25 February 2020; accepted 26 February 2020; final version received 24 March 2020. Corresponding Editor: Karen A. Haubensak. Copyright: © 2020 The Authors. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. E-mail: [email protected] INTRODUCTION provide plant protection. Protected crops are often regarded as simplified ecosystems with In agriculture, crops can be cultivated in green- very low biodiversity (Enkegaard and Brøds- houses to optimize growing conditions and gaard 2006, Messelink et al. 2012). For instance, ❖ www.esajournals.org 1 May 2020 ❖ Volume 11(5) ❖ Article e03126 AGROECOSYSTEMS POSTIC ET AL. greenhouse crops are often monocultures and and improvement of biological pest control pro- held in closed systems, which prevents entry of grams. crop pests from the local environment, but also Our study aimed to investigate the sources of restricts colonization by these pests’ primary nat- variations in the diversity of both pest and bene- ural enemies (Perdikis et al. 2011). However, ficial species, the compositions of their respective these systems are not completely pest-proof, as communities, and the food webs involving these numerous harmful species still threaten green- species in protected crops. For this purpose, we house crops (Messelink et al. 2012). Phy- considered a large French network of green- tophagous insect pests can colonize greenhouses houses used for strawberry production. Cultiva- directly, via openings in greenhouses, or indi- tion of strawberries, Fragaria 9 ananassa rectly, via contaminated plant material (Buiten- Duchesne (Rosales: Rosaceae), in soilless sub- huis et al. 2016) or accidental transportation by strate under protected structures is widespread workers between infested and uninfested crops. globally (Rondon et al. 2005). In France, produc- Once an insect pest colonizes a greenhouse, the tion is based on several coexisting geographic crop system offers excellent conditions for its regions, which all include different climatic con- development, leading to rapid population ditions and production systems. Strawberries are growth (van Lenteren 2000). On the other hand, mostly grown under polytunnels or greenhouses, it has also been shown that, in some cases, natu- which vary in their degree of openness. Several ral enemies of pests can enter greenhouses, and arthropods can cause damage to strawberry may then control the crop pest populations crops (e.g., thrips, spider mites, Drosophila suzu- (Castan~e et al. 2004, Gabarra et al. 2004, Bosco kii, and others), including aphids, which cause et al. 2008). While it has been suggested that substantial losses to yield and quality by feeding greenhouses are simplified ecosystems, they are on phloem sap, excreting honeydew, and trans- still subject to unpredictable species colonization mitting plant pathogenic viruses (Dedryver et al. events that may generate complex ecological sys- 2010). There is a particularly high diversity of tems with high variation in species richness, aphids that are potential pest species of straw- community assemblages, and trophic network. berry crops, which makes their control more Such ecological variations limit the ability of pro- complex (Cingolani and Greco 2018). To control ducers to predict both pest pressure on their aphid populations, strawberry producers have crops and pest regulation by natural enemies. experimented with the limited use of insecticides Several studies have focused on the influence and inundative releases of natural enemies of of environmental, ecological, and agricultural aphids for several years, but with insufficient factors on both the diversity and relative abun- results, especially concerning parasitoid releases dances of pests and their natural enemies in (Turquet et al. 2019). Consequently, there is a greenhouses (Heinz 1998, Castan~e et al. 2004, need to study the ecology of species interacting Gabarra et al. 2004, Bosco et al. 2008, Sanchez in greenhouses before implementing biological et al. 2011, Dong et al. 2019). However, few control programs. By studying both aphid and studies have considered the possibility of there parasitoid communities and food webs including being large-scale spatiotemporal variations in these antagonists, our study’s aim was to identify these systems’ ecological metrics, such as spe- species of interest for the efficient biological con- cies richness, community composition, and con- trol of aphids. nectivity within their food webs. Investigating Herein, the relative frequencies of occurrence such variations would help to (1) determine of aphid and parasitoid species in five French whether greenhouse crops are simplified or production regions during two successive years complex and predictable or unpredictable sys- were measured in a large number of green- tems; (2) understand the spatiotemporal houses. For each sampling year, the relative fre- dynamics of pests and their natural enemies in quencies of different species in greenhouses were greenhouses; and (3) identify the most preva- determined in both spring and summer. From lent beneficial natural enemies of pests through the results of these insect collections, we ana- food web analyses. Combining all of this infor- lyzed the following patterns: (1) the diversity of

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