Leaf biomechanical properties as mechanisms of resistance to black cutworm (Agrotis ipsilon) among Poa species

• Published in: Entomologia experimentalis et applicata Vol. 145; no. 3; pp. 201 - 208
• Main Authors: Hong, Seung Cheon, Williamson, R. Chris, Held, David W.
• Format: Journal Article
• Language: English
• Published: Amsterdam Blackwell Publishing Ltd 01.12.2012; Wiley Subscription Services, Inc
• Subjects: Age; Agrotis ipsilon; Detergents; Development; Fibers; Foliage; Fractures; Grasses; Herbivores; host plant resistance; Host plants; integrated pest management; IPM; Leaves; Lepidoptera; Mechanical properties; Noctuidae; Ontogeny; Pests; plant fiber; plant maturity; plant-insect interaction; Planting; Poa; Poa pratensis; Poaceae
• ISSN: 0013-8703; 1570-7458
• DOI: 10.1111/eea.12005

Biomechanical properties can be important parameters in resistance of plants to herbivorous insects. As plants age, however, there can be dramatic changes in physical defenses that can then influence their susceptibility to insect herbivores. We measured changes in leaf biomechanical properties during ontogeny of Poa species and the relationship of these changes to the development of a generalist herbivore, the black cutworm, Agrotis ipsilon Hufnagel (Lepidoptera: Noctuidae), was investigated. Larvae were reared on two representative age classes, i.e., young (<60 days after planting) and old (>1 year after planting), of foliage in laboratory assays. Foliage generally reaches a peak fracture force between 80 and 109 days after planting depending on grass type. Foliage from old plants was significantly tougher than that of young plants, and black cutworm larvae reared on foliage from young plants gained significantly (ca. four times) more weight than those fed on foliage from old Poa plants. In addition, fracture force has a negative relationship with black cutworm development. Plant fiber, particularly neutral detergent fiber accounted for 65 and 46% of the variation in fracture force and larval development, respectively. These results provide additional insight into how plant ontogeny influences physical defenses to an insect herbivore in a grass system. Likewise, this is seemingly the first study to suggest a mechanism for host plant resistance to black cutworm. Plant fiber may be a useful trait to explore in plant improvement programs in which black cutworm is a primary pest (e.g., managed turfgrass).