Uncovering the post-embryonic role of embryo essential genes in Arabidopsis using the controlled induction of visibly marked genetic mosaics: EMB506, an illustration.

The embryo essential gene EMB506 plays a crucial role in the transition of the Arabidopsis embryo from radial symmetry to bilateral symmetry just prior to the early heart stage of development. In addition to influencing embryo development EMB506 also affects chloroplast biogenesis. To further investigate the role of EMB506 gene expression in Arabidopsis we have generated green fluorescent protein (GFP) marked emb506 mosaic sectors at temporally defined stages during embryogenesis and additionally during various stages of vegetative growth, in otherwise phenotypically wild-type plants. We confirm the essential requirement for EMB506 gene expression in chloroplast biogenesis as reflected by the decreased chlorophyll content in emb506 mosaic sectors. We also show that the influence of EMB506 gene expression as it impinges on chloroplast biogenesis is first relevant at an intermediate stage in embryogenesis and that the role of EMB506 gene expression in chloroplast biogenesis is distinct from the essential role of EMB506 gene expression during early embryo development. By inducing emb506 mosaicism after the essential requirement for EMB506 gene expression in embryogenesis and also during vegetative growth we reveal that EMB506 gene expression additionally is required for correct cotyledon-, true leaf- and cauline leaf margin development. The strategy that we describe can be tailored to the mosaic analysis of any cloned EMB gene for which a corresponding mutant exists and can be applied to the mosaic analysis of mutant lethal genes in general.

Oleosin expression and trafficking during oil body biogenesis in tobacco leaf cells.

We have established a versatile method for studying the interaction of the oleosin gene product with oil bodies during oil body biogenesis in plants. Our approach has been to transiently express a green fluorescent protein (GFP)-tagged Arabidopsis oleosin gene fusion in tobacco leaf cells containing bona fide oil bodies and then to monitor oleosin-GFP expression using real-time confocal laser scanning microscopy. We show that normally non-oil-storing tobacco leaf cells are able to synthesize and then transport oleosin-GFP fusion protein to leaf oil bodies. Synthesis and transport of oleosin-GFP fusion protein to oil bodies occurred within the first 6 h posttransformation. Oleosin-GFP fusion protein exclusively associated with the endoplasmic reticulum and was trafficked in a Golgi-independent manner at speeds approaching 0.5 microm sec(-1) along highly dynamic endoplasmic reticulum positioned over essentially static polygonal cortical endoplasmic reticulum. Our data indicate that oil body biogenesis can occur outside of the embryo and that oleosin-GFP can be used to monitor early events in oil body biogenesis in real-time.

Altered cell cycle distribution, hyperplasia, and inhibited differentiation in Arabidopsis caused by the D-type cyclin CYCD3.

CYCD3;1 expression in Arabidopsis is associated with proliferating tissues such as meristems and developing leaves but not with differentiated tissues. Constitutive overexpression of CYCD3;1 increases CYCD3;1-associated kinase activity and reduces the proportion of cells in the G1-phase of the cell cycle. Moreover, CYCD3;1 overexpression leads to striking alterations in development. Leaf architecture in overexpressing plants is altered radically, with a failure to develop distinct spongy and palisade mesophyll layers. Associated with this, we observe hyperproliferation of leaf cells; in particular, the epidermis consists of large numbers of small, incompletely differentiated polygonal cells. Endoreduplication, a marker for differentiated cells that have exited from the mitotic cell cycle, is inhibited strongly in CYCD3;1-overexpressing plants. Transcript analysis reveals an activation of putative compensatory mechanisms upon CYCD3;1 overexpression or subsequent cell cycle activation. These results demonstrate that cell cycle exit in the G1-phase is required for normal cellular differentiation processes during plant development and suggest a critical role for CYCD3 in the switch from cell proliferation to the final stages of differentiation.