Cell wall structure and composition is affected by light quality in tomato seedlings.

Light affects many aspects of cell development. Tomato seedlings growing at different light qualities (white, blue, green, red, far-red) and in the dark displayed alterations in cell wall structure and composition. A strong and negative correlation was found between cell wall thickness and hypocotyl growth. Cell walls was thicker under blue and white lights and thinner under far-red light and in the dark, while intermediate values was observed for red or green lights. Additionally, the inside layer surface of cell wall presented random deposited microfibrillae angles under far-red light and in the dark. However, longitudinal transmission electron microscopy indicates a high frequency of microfibrils close to parallels related to the elongation axis in the outer layer. This was confirmed by ultra-high resolution small angle X-ray scattering. These data suggest that cellulose microfibrils would be passively reoriented in the longitudinal direction. As the cell expands, the most recently deposited layers (inside) behave differentially oriented compared to older (outer) layers in the dark or under FR lights, agreeing with the multinet growth hypothesis. High Ca and pectin levels were found in the cell wall of seedlings growing under blue and white light, also contributing to the low extensibility of the cell wall. Low Ca and pectin contents were found in the dark and under far-red light. Auxins marginally stimulated growth in thin cell wall circumstances. Hypocotyl growth was stimulated by gibberellins under blue light.

Structure-function relationships of different vascular bundle types in the stem of the Mexican fanpalm (Washingtonia robusta).

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.