Calcium Fluorescence Recordings from Neuroepithelial Stem Cells.

Neuroepithelial cells act as neural stem cells by renewing themselves during embryonic development. These cells are tightly interconnected and make contact with the basement membrane of the neuroepithelium. Under such circumstances, Ca2+ fluorescence recording is a successful method to study physiological properties of the neuroepithelial stem cell. This chapter describes detailed techniques of Ca2+ fluorescence recording from neuroepithelial stem cells.

Cytokinesis of neuroepithelial cells can divide their basal process before anaphase.

Neuroepithelial (NE) cells, the primary stem and progenitor cells of the vertebrate central nervous system, are highly polarized and elongated. They retain a basal process extending to the basal lamina, while undergoing mitosis at the apical side of the ventricular zone. By studying NE cells in the embryonic mouse, chick and zebrafish central nervous system using confocal microscopy, electron microscopy and time-lapse imaging, we show here that the basal process of these cells can split during M phase. Splitting occurred in the basal-to-apical direction and was followed by inheritance of the processes by either one or both daughter cells. A cluster of anillin, an essential component of the cytokinesis machinery, appeared at the distal end of the basal process in prophase and was found to colocalize with F-actin at bifurcation sites, in both proliferative and neurogenic NE cells. GFP-anillin in the basal process moved apically to the cell body prior to anaphase onset, followed by basal-to-apical ingression of the cleavage furrow in telophase. The splitting of the basal process of M-phase NE cells has implications for cleavage plane orientation and the relationship between mitosis and cytokinesis.

Conserved role of the Vsx genes supports a monophyletic origin for bilaterian visual systems.

BACKGROUND: Components of the genetic network specifying eye development are conserved from flies to humans, but homologies between individual neuronal cell types have been difficult to identify. In the vertebrate retina, the homeodomain-containing transcription factor Chx10 is required for both progenitor cell proliferation and the development of the bipolar interneurons, which transmit visual signals from photoreceptors to ganglion cells. RESULTS: We show that dVsx1 and dVsx2, the two Drosophila homologs of Chx10, play a conserved role in visual-system development. DVSX1 is expressed in optic-lobe progenitor cells, and, in dVsx1 mutants, progenitor cell proliferation is defective, leading to hypocellularity. Subsequently, DVSX1 and DVSX2 are coexpressed in a subset of neurons in the medulla, including the transmedullary neurons that transmit visual information from photoreceptors to deeper layers of the visual system. In dVsx mutant adults, the optic lobe is reduced in size, and the medulla is small or absent. These results suggest that the progenitor cells and photoreceptor target neurons of the vertebrate retina and fly optic lobe are ancestrally related. Genetic and functional homology may extend to the neurons directly downstream of the bipolar and transmedullary neurons, the vertebrate ganglion cells and fly lobula projection neurons. Both cell types project to visual-processing centers in the brain, and both sequentially express the Math5/ATO and Brn3b/ACJ6 transcription factors during their development. CONCLUSIONS: Our findings support a monophyletic origin for the bilaterian visual system in which the last common ancestor of flies and vertebrates already contained a primordial visual system with photoreceptors, interneurons, and projection neurons.

Molecular cloning of three zebrafish lin7 genes and their expression patterns in the retina.

The vertebrate retina develops from an undifferentiated sheet of neuroepithelial cells, whose differentiation requires the generation and maintenance of the correct cellular polarity. To examine the role of cell polarity in retinal development, we cloned three zebrafish lin7 genes (lin7a, lin7b, and lin7c), which each encodes a protein candidate that is required for generation/maintenance of neuroepithelial cell junctions. These three zebrafish Lin7 proteins share over 78% amino acid identity and contain both L27 and PDZ domains that are present in all Lin7 homologs. Immunoblots revealed that the Lin7b and Lin7c proteins were first expressed in the developing eye by 24hr postfertilization (hpf), while Lin7a was not detected in the eye until 72 hpf. At 33 hpf, the Lin7 proteins localized at, or slightly apical of, the actin-associated adherens junctions in the retinal neuroepithelium. This subcellular distribution required the expression of the Nok protein. In the absence of Nok, the Lin7 proteins failed to localize to either the ectopic adherens junctions or the cell membrane. At 4 days postfertilization, in situ hybridisation revealed that all three lin7 genes were expressed in both the ganglion cell layer and the bipolar cell region of the inner nuclear layer. The lin7a gene was also expressed in the amacrine and horizontal cell regions of the inner nuclear layer, while lin7c was also expressed in the outer nuclear layer. In the adult retina, where Lin7a is the predominant form expressed, the Lin7 proteins were localized to the outer and inner plexiform layers, the bipolar and horizontal cells of the inner nuclear layer, and the ganglion cells. These results suggest that the three zebrafish Lin7 proteins possess partially redundant, yet essential, roles in retinal development.

Histopathological changes in the brain of mouse fetuses by etoposide-administration.

Etoposide (VP-16), a topoisomerase II inhibitor, is an anti-tumor agent which is also known to show embryotoxicity, and teratogenicity when administered to pregnant rodents. We examined VP-16-induced histopathological changes in the brain of mouse fetuses. Pregnant mice were intraperitoneally injected with VP-16 (4 mg/kg) on day 12 of gestation (GD 12), and fetuses were collected from 1 to 48 hours after treatment (HAT). Mitotic neuroepithelial cells in the telencephalic wall prominently decreased at 2 HAT, and were hardly observed at 4 HAT. The number of pyknotic neuroepithelial cells in the fetal brain began to increase at 4 HAT, and became prominent from 8 to 24 HAT. These pyknotic cells were also positively stained by TUNEL method, which can detect fragmented DNA, and showed ultrastructural characteristics of apoptosis. Additionally, these cells were also positive for cleaved caspase-3, an essential executioner of apoptosis. This indicated that excessive neuroepithelial cell apoptosis was induced in the brain of mouse fetuses following VP-16 treatment on GD 12.