Effects of Terpene Chemotypes of Melaleuca alternifolia on Two Specialist Leaf Beetles and Susceptibility to Myrtle Rust

Plant chemical polymorphisms, or plant chemotypes, are characterized by intraspecific discrete differences of plant secondary metabolites in the same plant tissue. Chemotypes that differ in foliar terpene composition are found commonly in Myrtaceae. In this study, we focused on terpene chemotypes of...

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Bibliographic Details
Published in:Journal of chemical ecology 2015-10, Vol.41 (10), p.937-947
Main Authors: Bustos-Segura, Carlos, Külheim, Carsten, Foley, William
Format: Article
Language:English
Subjects:
adults
Agriculture
Animals
Basidiomycota - physiology
Biochemistry
Biological Microscopy
Biomedical and Life Sciences
chemotypes
Chrysomelidae
cineole
Coleoptera
Coleoptera - genetics
Coleoptera - growth & development
Coleoptera - microbiology
Coleoptera - physiology
diet
Ecology
Ecology, environment
Entomology
Female
Flowers & plants
Herbivores
Herbivory
Insects
Larva - genetics
Larva - growth & development
Larva - microbiology
Larva - physiology
larvae
Larval development
Life Sciences
Male
Melaleuca
Melaleuca - chemistry
Melaleuca alternifolia
Metabolites
Myrtaceae
Myrtus communis
natural enemies
Oviposition
Paropsisterna
pests
plant damage
Plant tissues
Polymorphism
Puccinia
Puccinia psidii
Secondary metabolites
Species Specificity
Terpenes - chemistry
terpinolene
trees
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Summary:Plant chemical polymorphisms, or plant chemotypes, are characterized by intraspecific discrete differences of plant secondary metabolites in the same plant tissue. Chemotypes that differ in foliar terpene composition are found commonly in Myrtaceae. In this study, we focused on terpene chemotypes of medicinal tea tree, Melalecua alternifolia, to explore whether this variation affects two specialist herbivores Paropsisterna tigrina and Faex sp. (Coleoptera: Chrysomelidae), and if this could explain the maintenance of this variation. We tested whether insect performance, oviposition preference, and plant damage were associated with different chemotypes. We found that larval growth rate of Faex sp. was higher in chemotypes with high concentrations of 1,8-cineole, and that oviposition preference depended on the chemotype of the larval diet. Although performance traits and preference for oviposition of P. tigrina did not vary among chemotypes, adults inflicted less damage on plants with a high concentration of terpinolene. Additionally, we tested whether different chemotypes showed different levels of susceptibility by myrtle rust (Puccinia psidii). We found that plants with a high concentration of 1,8-cineole were more likely to be infected under controlled conditions. Although there is evidence that terpene chemotypes are a mediator of the interaction with natural enemies, the most detrimental pest of this plant, P. tigrina, does not seem to be affected by variation in plant terpenes.
ISSN:0098-0331
1573-1561
DOI:10.1007/s10886-015-0628-0