Deborah B. Dehart scite author profile

Development of the node and formation of the notochordal plate in gestational day 7-9 mice (Theiler stages 10-14) has been documented principally with scanning electron microscopy (SEM) and cell fate analyses utilizing DiI andlor CFSE as a cell label. With SEM, cells composing these two populations are initially identifiable at stage 10 at the ventral midline of the rostral half of the embryo. They can be recognized by their relatively small ventral surface area, as compared to that of the peripherally adjacent prospective gut endodermal cells, and by the presence on the ventral side of each cell of a prominent single, central cilium, which is lacking on endodermal cells. At stage 10, the node is located at the apex of the cup-shaped embryo. It represents the rostral end of the primitive streak (although its structure differs from that of the rest of the streak), and it consists of a localized two-layered area (i.e., epiblast and the most caudal aspect of the notochordal plate). By stage 11, the notochordal plate constitutes a relatively broad, circular area (at the level of the node) that tapers rostrally into a narrower midline strip (beneath the future floor plate of the neural tube). The tip of the notochordal plate terminates rostrally at the much broader prechordal plate, which underlies the future forebrain level of the neuraxis. The prechordal plate cells, like the ventral node and notochordal plate cells, each have a relatively small ventral surface area and displays a single central cilium on their ventral surface. The most caudal aspect of the notochordal plate remains morphologically distinct on the dorsal, midline surface of the open gut through stage 13; the more rostral levels progressively fold off from the roof of the gut to form the definitive notochord. Videomicroscopy reveals that the cilia extending from the ventral surfaces of the cells of node and of the prechordal and notochordal plates are motile. The potential significance of this motile behavior remains unknown. Labeling studies, which marked cells in both the dorsal and ventral layers of the node, reveal that the stage-10 node contributes cells to the notochordal plate and overlying midline ectodermal cells of the neural plate, the future floor plate of the neural tube. The results of our labeling studies, in which cells in both layers of the node were marked, when compared with the 0 1994 WILEY-LISS, INC. results of a recent study in which only the ventral layer of the node was marked (Beddington [19941 Development 1206134320) provide strong evidence that the ventral layer of the node forms notochord, whereas the dorsal layer forms floor plate of the neural tube. A similar origin for these two populations of cells has been suggested for the chick embryo (Selleck and Stern [19911 Development 112615-626). The morphology of the murine notochordal plate and labeling studies support the concept of origin and rostrocaudal elongation of this structure in large part by accretion of cells from the node. In addition, cell division a...

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Selective Vulnerability of Embryonic Cell Populations to Ethanol‐Induced Apoptosis: Implications for Alcohol‐Related Birth Defects and Neurodevelopmental Disorder

Dunty

Chen

Zucker

et al. 2001

Alcoholism Clin & Exp Res

205

177

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Magnetic Resonance Microscopy Defines Ethanol‐Induced Brain Abnormalities in Prenatal Mice: Effects of Acute Insult on Gestational Day 8

Parnell

O’Leary‐Moore

Godin

et al. 2009

Alcoholism Clin & Exp Res

129

142

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Background Magnetic resonance microscopy (MRM), magnetic resonance imaging (MRI) at microscopic levels, provides unprecedented opportunities to aid in defining the full spectrum of ethanol’s insult to the developing brain. This is the first in a series of reports that, collectively, will provide an MRM-based atlas of developmental stage-dependent structural brain abnormalities in a Fetal Alcohol Spectrum Disorders (FASD) mouse model. The ethanol exposure time and developmental stage examined for this report is gestational day (GD) 8 in mice, when the embryos are at early neurulation stages; stages present in humans early in the fourth week postfertilization. Methods For this study, pregnant C57Bl/6J mice were administered an ethanol dosage of 2.8 g/kg intraperitoneally at 8 days, 0 hour and again at 8 days, 4 hours postfertilization. On GD 17, fetuses that were selected for MRM analyses were immersion fixed in a Bouin’s/Prohance solution. Control fetuses from vehicle-treated dams were stage-matched to those that were ethanol-exposed. The fetal mice were scanned ex vivo at 7.0 T and 512 · 512 · 1024 image arrays were acquired using 3-D spin warp encoding. The resulting 29 lm (isotropic) resolution images were processed using ITK-SNAP, a 3-D segmentation/visualization tool. Linear and volume measurements were determined for selected brain, head, and body regions of each specimen. Comparisons were made between control and treated fetuses, with an emphasis on determining (dis)proportionate changes in specific brain regions. Results As compared with controls, the crown-rump lengths of stage-matched ethanol-exposed GD 17 fetuses were significantly reduced, as were brain and whole body volumes. Volume reductions were notable in every brain region examined, with the exception of the pituitary and septal region, and were accompanied by increased ventricular volumes. Disproportionate regional brain volume reductions were most marked on the right side and were significant for the olfactory bulb, hippocampus, and cerebellum; the latter being the most severely affected. Additionally, the septal region and the pituitary were disproportionately large. Linear measures were consistent with those of volume. Other dysmorphologic features noted in the MR scans were choanal stenosis and optic nerve coloboma. Conclusions This study demonstrates that exposure to ethanol occurring in mice at stages corresponding to the human fourth week postfertilization results in structural brain abnormalities that are readily identifiable at fetal stages of development. In addition to illustrating the utility of MR microscopy for analysis of an FASD mouse model, this work provides new information that confirms and extends human clinical observations. It also provides a framework for comparison of structural brain abnormalities resulting from ethanol exposure at other developmental stages and dosages.

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Deborah B. Dehart

Morphogenesis of the murine node and notochordal plate

Selective Vulnerability of Embryonic Cell Populations to Ethanol‐Induced Apoptosis: Implications for Alcohol‐Related Birth Defects and Neurodevelopmental Disorder

Magnetic Resonance Microscopy Defines Ethanol‐Induced Brain Abnormalities in Prenatal Mice: Effects of Acute Insult on Gestational Day 8

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