RESUMO
Cuticular ridges on plant surfaces can control insect adhesion and wetting behaviour and might also offer stability to underlying cells during growth. The growth of the plant cuticle and its underlying cells possibly results in changes in the morphology of cuticular ridges and may also affect their function. We present spatial and temporal patterns in cuticular ridge development on the leaf surfaces of the model plant, Hevea brasiliensis. We have identified, by confocal laser scanning microscopy of polymer leaf replicas, an acropetally directed progression of ridges during the ontogeny of Hevea brasiliensis leaf surfaces. The use of Colorado potato beetles (Leptinotarsa decemlineata) as a model insect species has shown that the changing dimensions of cuticular ridges on plant leaves during ontogeny have a significant impact on insect traction forces and act as an effective indirect defence mechanism. The traction forces of walking insects are significantly lower on mature leaf surfaces compared with young leaf surfaces. The measured walking traction forces exhibit a strong negative correlation with the dimensions of the cuticular ridges.
RESUMO
Structure and mechanics of fibre caps of different types of vascular bundles were studied at a certain height in the trunk of the palm Washingtonia robusta. By correlating these features with the distribution of the different bundle types across the trunk, possible strategies to cope with mechanical loads were elucidated. Micromechanical properties, cell parameters, microfibril orientation and lignification were studied using micromechanical testing, image analysis, synchrotron X-ray diffraction and UV-microspectrophotometry. The adjustment of stiffness followed a common principle in the fibre caps of all bundle types. Gradients in stiffness appeared across the caps in the centre of the trunk whereas stiffness remained high across the caps in the periphery of the trunk. The difference in stiffness profiles was interpreted as an adaptation to different mechanical constraints arising across the trunk. The gradual transition in stiffness prevents high local stress discontinuities between cap fibres and parenchyma and might be beneficial for trunk damping. At the periphery, the fibre caps without stiffness gradients contribute to a high flexural stiffness of the trunk as this has to be exclusively maintained by the material properties because geometric adjustments through increasing trunk diameter hardly occur in monocotyledonous palms.