monensin and oryzalin

Embryogenesis of flowering plants establishes a basic body plan with apical-basal, radial and bilateral patterns from the single-celled zygote. Arabidopsis embryogenesis exhibits a nearly invariant cell division pattern and therefore is an ideal system for studies of early plant development. However, plant embryos are difficult to access for experimental manipulation, as they develop deeply inside maternal tissues. Here we present a method for the culture of zygotic Arabidopsis embryos in vitro. The technique omits excision of the embryo by culturing the entire ovule, thus greatly facilitating the time and effort involved. It enables external manipulation of embryo development and culture from the earliest developmental stages up to maturity. Administration of various chemical treatments as well as the use of different molecular markers is demonstrated together with standard techniques for visualizing gene expression and protein localization in in vitro cultivated embryos. The presented set of techniques allows for so far unavailable molecular physiology approaches in the study of early plant development.

Topics: Arabidopsis; Biological Transport; Biomarkers; Brefeldin A; Bridged Bicyclo Compounds, Heterocyclic; Cell Culture Techniques; Cytoskeleton; Dinitrobenzenes; Germination; Monensin; Seeds; Sulfanilamides; Thiazoles; Thiazolidines

During the establishment of polarity, fucoid algal zygotes adhere to the substratum and select a growth axis according to environmental cues. Since little is known about the early events leading to axis selection, we investigated the chronology of cell adhesion, adhesive deposition, and axis selection induced by light (photopolarization). The requirements for secretion and the cytoskeleton in these processes and in the process of changing the orientation of an axis in response to new environmental cues (axis realignment) were also tested. Adhesive deposition occurred in two distinct stages: it was deposited uniformally on young zygotes (uniform primary adhesive) and later was deposited asymmetrically (polar secondary adhesive). Uniform primary adhesive deposition, cell adhesion, and photopolarization occurred simultaneously, and shortly thereafter, polar secondary adhesive deposition occurred at the future growth site. Uniform primary adhesive deposition and cell adhesion required secretion, but were independent of filamentous-actin (F-actin) and microtubule function. Photopolarization of young zygotes and polar secondary adhesive deposition required secretion but not microtubules. F-actin served to localize secondary adhesive deposition at the rhizoid pole; its function in polarization was more complex. F-actin was required for axis selection; however, its role in realignment of an axis depended on the light regime. The differing requirements for F-actin during development indicates that the axis is not static, but changes with time. These findings indicate that previous and future work on "axis formation" must be interpreted in the context of the developmental stage of the zygote.

Topics: Actins; Anti-Bacterial Agents; Bodily Secretions; Brefeldin A; Bridged Bicyclo Compounds, Heterocyclic; Cell Adhesion; Cyclopentanes; Cytochalasin D; Cytoskeleton; Dinitrobenzenes; Eukaryota; Light; Macrolides; Microscopy, Confocal; Monensin; Sulfanilamides; Thiazoles; Thiazolidines; Zygote