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Tritrophic interactions on cultivated maize and its wild ancestor "teosinte"
Auteur(s)
De Lange, Elvira Simone
Editeur(s)
Date de parution
2014
Mots-clés
- <i>Campoletis sonorensis</i>
- Écologie Chimique
- <i>Cotesia marginiventris</i>
- Maïs
- Domestication
- Légionnaire d'automne
- Green leaf volatiles
- Odeurs induites
- Plante hôte
- Insecte herbivore
- Ravageur du maïs
- Mexique
- Ennemi naturel
- Guêpe parasitoïde
- Défense des plantes
- <i>Spodoptera frugiperda</i>
- Téosinte
- Interactions tritrophiques
- Composés organiques volatils
- <i>Zea mays</i>
- <i>Campoletis sonorensis</i>
- Chemical ecology
- <i>Cotesia marginiventris</i>
- Corn
- Domestication
- Fall armyworm
- Green leaf volatiles
- Herbivore‐induced plant volatiles
- Host plant
- Insect herbivore
- Maize pest
- Mexico
- Natural enemy
- Parasitoid wasp
- Plant defense
- <i>Spodoptera frugiperda</i>
- Teosinte
- Tritrophic interactions
- Volatile organic compounds
- <i>Zea mays</i>
<i>Campoletis sonoren...
Écologie Chimique
<i>Cotesia marginiven...
Maïs
Domestication
Légionnaire d'automne...
Green leaf volatiles
Odeurs induites
Plante hôte
Insecte herbivore
Ravageur du maïs
Mexique
Ennemi naturel
Guêpe parasitoïde
Défense des plantes
<i>Spodoptera frugipe...
Téosinte
Interactions tritroph...
Composés organiques v...
<i>Zea mays</i>
<i>Campoletis sonore...
Chemical ecology
<i>Cotesia marginive...
Corn
Domestication
Fall armyworm
Green leaf volatiles
Herbivore‐induced pla...
Host plant
Insect herbivore
Maize pest
Mexico
Natural enemy
Parasitoid wasp
Plant defense
<i>Spodoptera frugipe...
Teosinte
Tritrophic interactio...
Volatile organic comp...
<i>Zea mays</i>
Résumé
Modern maize plants (<i>Zea mays</i> ssp. <i>mays</i>, Poaceae) are characterized by large cobs that contain juicy grains, although they have not always had these characteristics. Approximately 9000 years ago, maize was domesticated from teosinte (<i>Z. mays</i> ssp. <i>parviglumis</i>), its closest wild ancestor, which produces much less and much smaller seeds. Teosinte still grows in the wild in Mexico, while maize is produced all over the world. Continuous selection for improved yield and quality has had a cost for the plant in terms of the loss or alteration of other potentially useful traits, such as resistance to pathogens and herbivorous insects. This thesis focuses on the resistance of maize and teosinte against insect pests, in particular with respect to the emission of herbivore-induced volatiles. This feature is considered an indirect defense trait, as the volatiles can betray the presence of prey or hosts to predators and parasitoids, natural enemies of herbivorous insects. Among these natural enemies are parasitoid wasps, of which females have an ovipositor with which they can lay single or multiple eggs in individual hosts. When the wasp larvae develop inside the host they will eventually kill it, potentially benefitting the plant. <br> At first, we assessed in nature which insects occur on teosinte. Fall armyworm, <i>Spodoptera frugiperda</i> (Lepidoptera: Noctuidae), is reported as an important maize pest in the Americas and is frequently attacked by many species of parasitoids. However, little is known about the presence of this herbivore and its associated parasitoids on teosinte. <br> In a laboratory setting, we then assessed whether maize and teosinte emit a similar blend of volatiles when induced by lepidopteran herbivores. We also evaluated the attractiveness of the odor blends to females of two species of parasitoid wasps. Although the odor blends appeared similar upon gas chromatography analysis, the foraging parasitoids responded differentially to them. We obtained similar results when testing real plants and extracts of collected odors, indicating that these extracts can be used to identify the key compounds that are responsible for parasitoid attraction. <br> There is surprisingly little field evidence for fitness benefits for plants due to the action of natural enemies. This is still an important point in the discussion on the possible indirect defense role of inducible plant volatiles, especially in the case of parasitoids that, unlike predators, do not directly kill their hosts. Therefore, we evaluated how parasitoid wasps can affect plant performance in a semi-natural setting in Mexico. The presence of parasitoid wasps in field tents containing teosinte plants and fall armyworm significantly reduced herbivore damage, which, for the smallest plants, resulted in a reduction in plant mortality. These findings support the notion that plants may benefit from the presence of parasitoids and may help to resolve the current debate on the defensive function of herbivore-induced volatiles. <br> To further explore the importance of volatiles for the attraction of parasitoids under field conditions, we studied maize <i>lox10</i> mutants, impaired in the biosynthesis of green leaf volatiles (GLVs). These volatiles, responsible for the smell of cut grass, are commonly emitted by plants when wounded or attacked by herbivores. Previously, laboratory studies have shown that GLVs can be used as foraging cues by predators and parasitoids. However, our results imply that GLVs are not of key importance for parasitoid attraction in the field. <br> Collectively, these studies provide novel insights into the importance of herbivore-induced volatiles for the attraction of parasitoid wasps, and their indirect importance for plant growth and survival. We identified differences between maize and its wild ancestor, teosinte, with respect to the attraction of parasitoids that could possibly be exploited for ecologically sound methods to better protect maize against insect pests.
Notes
Thèse de doctorat : Université de Neuchâtel, 2014
Identifiants
Type de publication
doctoral thesis
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