| One of the most important features characterizing plant cells and differentiating them from animal cells is the cell wall that surrounds them. The cell wall plays a critical role in providing protection to the protoplast; it acts as a filtering mechanism and is the location of many biochemical reactions implicated in the regulation of the cell metabolism and the mechanical properties of the cell. The local stiffness, extensibility, plasticity and elasticity of the different cell wall components determine the shape and geometry of the cell during differentiation and morphogenesis. The goal of my thesis is to understand the role played by the different cell wall components in shaping the plant cell and controlling its growth behaviour. To achieve this goal, I studied the pollen tube, or male gametophyte, as a cellular model system. The pollen tube is a cellular protuberance formed by the pollen grain upon its contact with the stigma. Its main purpose is to deliver the sperm cells to the female gametophyte to ensure double fertilization. The pollen tube is a tip-growing cell characterized by its simple cell wall composition and by the fact that it is the fastest growing cell of the plant kingdom. This makes it the ideal model to study the effects of drugs, mutations or stresses on cellular growth behaviour, metabolism and cell wall mechanics. The pollen tube cell wall consists mainly of proteins and three major polysaccharidic components: pectins, cellulose and callose. To understand the role played by these components in regulating pollen tube growth, I investigated the effects of mutations, enzymatic treatments, hyper-gravity and omni-directional gravity on the pollen tube cell wall. Using mathematical modeling combined with molecular biology and high-resolution electron and fluorescent microscopy I was able to show that the regulation of pectin chemistry is required for the regulation of the growth rate and pollen tube shape and that cellulose is crucial for determining the pollen tube diameter in the sup-apical region. Moreover, I investigated the role of the pectate lyases, a group of pectin digesting enzymes expressed during pollen tube development, and I showed that this enzyme activity is required for the initiation of pollen germination. More importantly, I directly showed for the first time that the pollen tube secretes cell wall loosening enzymes to facilitate its penetration through the style. |
