The asymmetric cell division of the zygote is the initial and crucial developmental step in most multicellular organisms. In flowering plants, whether zygote polarity is inherited from the preexisting organization in the egg cell or reestablished after fertilization has remained elusive. How dynamically the intracellular organization is generated during zygote polarization is also unknown. Here, we used a live-cell imaging system with Arabidopsis zygotes to visualize the dynamics of the major elements of the cytoskeleton, microtubules (MTs), and actin filaments (F-actins), during the entire process of zygote polarization. By combining image analysis and pharmacological experiments using specific inhibitors of the cytoskeleton, we found features related to zygote polarization. The preexisting alignment of MTs and F-actin in the egg cell is lost on fertilization. Then, MTs organize into a transverse ring defining the zygote subapical region and driving cell outgrowth in the apical direction. F-actin forms an apical cap and longitudinal arrays and is required to position the nucleus to the apical region of the zygote, setting the plane of the first asymmetrical division. Our findings show that, in flowering plants, the preexisting cytoskeletal patterns in the egg cell are lost on fertilization and that the zygote reorients the cytoskeletons to perform directional cell elongation and polar nuclear migration.Arabidopsis thaliana | zygote polarity | microtubule | actin filament | apical-basal axis B ody axis formation is one of the first developmental events occurring after fertilization in multicellular eukaryotes. In most flowering plants, the apical-basal (shoot-root) axis is formed along the longitudinal cell polarity of the egg cell and the zygote, marked by the apical position of the nucleus (1, 2) (Fig. 1A). In Arabidopsis thaliana, within 24 h of fertilization, the zygote elongates markedly and becomes polarized with the nucleus lying close to the apical region, leading to the asymmetric zygotic division, which produces a small apical cell and a large basal cell (2-4) (Fig. 1A). The apical cell gives rise to the embryo lineage that generates most of the plant body, whereas the basal cell produces the short-lived suspensor lineage and the hypophysis, the most apically located cell, which becomes essential in the organization of the root meristem (5, 6) (Fig. 1A).In most animal zygotes, the unfertilized oocyte has a clear cell polarity, but the sperm entry site changes its direction to set the first zygote division plane in many species, such as mouse, Caenorhabditis elegans, Xenopus, and bivalve (7-10). Therefore, the initial body axis of their embryos is determined by fertilization. In flowering plants, the sperm cell enters from the apex of the egg cell, and thus, the apical-basal axis seems unaltered before and after fertilization (2,11,12). Therefore, it has remained unclear whether zygote polarity is inherited from the egg cell or newly generated after fertilization. In vitro fertilization assays of rice ...
