Several processes during sexual reproduction in higher plants involve the movement of water between cells or tissues. Before flower anthesis, anther and pollen dehydration takes place before the release of mature pollen at dehiscence. Aquaporins represent a class of proteins that mediates the movement of water over cellular membranes. Aquaporins of the plasmamembrane PIP2 family are expressed in tobacco (Nicotiana tabacum) anthers and may therefore be involved in the movement of water in this organ. To gain more insight into the role these proteins may play in this process, we have analyzed their localization using immunolocalizations and generated plants displaying RNA interference of PIP2 aquaporins. Our results indicate that PIP2 protein expression is modulated during anther development. Furthermore, in tobacco PIP2 RNA interference plants, anther dehydration was slower, and dehiscence occurred later when compared with control plants. Together, our results suggest that aquaporins of the PIP2 class are required for efficient anther dehydration prior to dehiscence.In plant sexual reproduction, control of water movement plays an important role. During development, for example, young anthers must first take up water for growth, but at later stages anthers and pollen dehydrate before dehiscence. In tobacco (Nicotiana tabacum) and many other species, pollen dehydration starts after the degeneration of the tapetum, and pollen grains are partially dehydrated at dehiscence (Goldberg, 1988;Franchi et al., 2002). The significance of correct pollen dehydration for the functions of the pollen grain is illustrated by the Arabidopsis (Arabidopsis thaliana) mutant raring-to-go (Johnson and McCormick, 2001). In these plants, pollen grains do not dehydrate as wild-type pollen and germinate within the anther when it is exposed to high humidity. However, besides this example, not much is known about the detailed mechanism of pollen dehydration.Correct timing of anther dehiscence is important, as the time of pollen release is crucial for successful fertilization. It was shown that plant hormones are implicated in the dehiscence process. In Arabidopsis, mutations in several genes involved in jasmonic acid biosynthesis all result in delayed anther dehiscence, suggesting the involvement of jasmonic acid signaling in its regulation (Sanders et al., 2000;Ishiguro et al., 2001;Park et al., 2002). In tobacco, however, ethylene has been shown to control the timing of anther dehiscence (Rieu et al., 2003). Other processes associated with dehiscence involve the formation of secondary wall thickenings, the consecutive degeneration of various anther tissues, changes in carbohydrate metabolism, and the movement of water out of the anther (Keijzer, 1987;Bonner and Dickinson, 1990;Clement and Audran, 1995;Beals and Goldberg, 1997;Dawson et al., 1999;Steiner-Lange et al., 2003;Scott et al., 2004; see Table I for an overview of tobacco anther development). It has been suggested that the formation of secondary wall thickenings, in combination wi...
