Bmp2 is required for cephalic neural tube closure in the mouse

BMPs have been shown to play a role in neural tube development particularly as dorsalizing factors. To explore the possibility that BMP2 could play a role in the developing neural tube (NT) beyond the lethality of Bmp2 null embryos, we created Bmp2 chimeras from Bmp2 null ES cells and WT blastocysts. Analysis of Bmp2 chimeras reveals NT defects at day 9.5 (E9.5). We found that exclusion of Bmp2 null ES cells from the dorsal NT did not always prevent defects. For further comparison, we used a Bmp2 mutant line in a mixed background. Phenotypes observed were similar to chimeras including open NT defects, postneurulation defects, and abnormal neural ectoderm in heterozygous and homozygous null embryos demonstrating a pattern of dose‐dependent signaling. Our data exposes BMP2 as a unique player in the developing NT for dorsal patterning and identity, and normal cephalic neural tube closure in a dose‐dependent manner. Developmental Dynamics 238:110–122, 2009. Published 2008 Wiley‐Liss, Inc.     

The influence of excess vitamin A on neural tube closure in the mouse embryo

Summary The effect of excess vitamin A on the closure of the neural tube in mouse embryos was examined with light microscopy, transmission and scanning electronmicroscopy. The embryos were treated with the vitamin just before closure of the brain vesicles and examined during the following 24 h, a period during which under normal conditions the brain completely closes.At 18–24 h after treatment the external features of the treated specimens began to differ from those of the controls. In the treated embryos the neural walls folded laterally and became widely separated, whereas those of the controls folded dorsomedially and fused in the midline. Histologically, the first difference between treated and control embryos was noted at two hours after treatment, when large intercellular spaces appeared between the neuroepithelial cells of the treated embryos. These spaces were mainly present between the apical ends of the wedge-shaped neuroepithelial cells. This accumulation of intercellular spaces interfered with the normal morphogenetic movement of the neural walls, which remained convex instead of becoming concave. This convex bending resulted in non-closure of the neural tube.In addition to the appearance of large intercellular spaces some neuroepithelial cells as well as some mesenchymal, endothelial, and surface ectoderm cells showed swelling and degeneration as a result of the vitamin A treatment. This cell degeneration probably contributes to failure of the neural tube to close due to loss of cohesion at the luminal surface and the lack of mesenchymal support needed for the elevation of the neural walls. However, the increase of intercellular spaces at the apical side of the neuroepithelium is in all probability the major cause for the failure of the neural tube to close.     

Studies of neural tube development in the chicken embryo tail

Summary The tail regions of chick embryos between stages 21 to 46 were studied by light microscopy using paraffinand epoxyembedded serial sections. The embryonic tail attains its maximum length at about stage 22. The present study examined the morphogenesis of the caudal neural tube during the reduction and remodelling processes of the embryonic tail. Between stages 21 and 28, the embryonic tail became markedly shorter, and the neural tube, with a single central canal, merged caudally with the short medullary cord and tail bud. Between stages 29 and 31, the neural tube elongated and curved rostrally, while the caudal end of the notochord and the tail bud disappeared. Between stages 32 and 39, after showing various structural changes such as dilatation or rupture and abnormal elongation of its marginal zone the neural tube became shorter. By stage 40, development of the caudal neural tube was essentially complete and the neural tube was shorter than the notochord. The neural tube opened dorsally, as in the adult chicken. The caudal opening may be newly-formed as the open portion was found to contain numerous macrophages.     

The ultrastructure of early cephalic neural crest cell migration in the mouse

Summary A study of the ultrastructural changes associated with the detachment of the presumptive neural crest cells from the neuroepithelium in the midbrain region in mouse embryos at 9 and 91/2 days of gestation was carried out. The first sign of neural crest cell formation occurred in this region before fusion of the neuroepithelium had occurred. Neural crest cells arose from both the neural plate and the adjoining surface ectoderm. Initially, the cells of the neural plate and the surface ectoderm were attached to each other by zonula occludens and zonula adherans at their apical surfaces however, these junctions disappeared just prior to the beginning of the migration of the crest cells. The first sign of migration of the crest cells was the disappearance of the basal lamina in the region of the presumptive crest cells. Once the basal lamina was lost, cell junctions were formed between the epithelial cells and the underlying mesenchymal cells. Once the crest cells had migrated into the underlying mesenchyme, they tended to form clumps of closely related, irregularly shaped cells. Phagosomes and accumulations of glycogen particles were found within some crest cells when they were still within 50 to 100 microns of the epithelium.     

Formation and distribution of neural crest mesenchyme to the first pharyngeal arch region of the mouse embryo

The normal microscopic and submicroscopic structure of the lower respiratory tract of the budgerigar (Melopsittacus undulatus) is described and compared with other birds and mammals. Granular (type II) pneumocytes are confined to linings of air sacs, parabronchi, and their atria; however, their secretions (surfactant) cover the surfaces of the infundibula and respiratory space. Infundibula extend from the atria and give rise to the air capillaries, which branch and anastomose freely with those of adjacent infundibula and other parabronchi (interparabronchial septa are not found). Infundibula and the respiratory labyrinth are lined by a continuous epithelium of squamous pneumocytes, whose perikarya are concentrated in the infundibula and whose peripheral cytoplasm is markedly attenuated. The squamous pneumocytes of the respiratory labyrinth share a basal lamina with the blood capillaries that they envelop.     

母体肥胖对胚胎神经管发育及线粒体结构和功能的影响

目的:研究母体肥胖对胚胎神经管发育及线粒体结构和功能的影响.方法:将16只C57BL/6J雌性小鼠随机分为正常饮食(normal diet,ND)组和高脂饮食(high-fat diet,HFD)组,连续喂食12周后,使雌鼠受孕,于孕14.5 d时进行后续实验.检测小鼠体重、血脂,行肝脏HE和油红O染色以判断肥胖模型是...     

Inhibition of cephalic neural tube closure by 5-azacytidine in neurulating rat embryos in vitro

Summary Head-fold stage rat embryos (9.5 days of gestation) were cultured for 48 h in rat serum with or without 0.8 M 5-azacytidine. Incomplete closure of the cephalic neural tube was observed in 5-azacytidine-treated embryos cultured for 48 h (25-somite stage). Control embryos showed complete fusion of cephalic neural folds at 33 h (16-somite stage) in culture. Drug administration or removal experiments revealed that embryos were sensitive to 5-azacytidine during 6–12 h of culture (three to five somite stages). Electron microscopical studies indicated that the arrangement and fine structure of cephalic neuroepithelial cells were almost the same in control and treated embryos. There was no significant difference in DNA and protein contents between control and treated embryos cultured for 36 h. Immunocytochemical observations using 5-methylcytosine-specific antibody revealed that the staining of neuroepithelial cells in the median part of the transversely sectioned cephalic neural plate, and of mesenchymal cells near the apices of the plate, was suppressed by 5-azacytidine. These results suggest that DNA methylation of these cells plays an important role in closure of the cephalic neural tube.     

Ultrastructural observations on closure of the neural tube in the mouse

Summary The fusion of the neural walls in the cephalic part of mouse embryos varying in age from 9 to 20 somites was examined with the electron microscope. In the rhombencephalic region the rim of the neural wall was formed from outside inward by ectodermal surface cells, a row of flattened cells without surface projections and neuroepithelial cells. At the junction of the surface ectoderm and the flat cells were seen large projections containing a cytoplasmic matrix without organelles and previously referred to as ruffles. The initial contact between the walls was made by the large cytoplasmic arms and numerous finger-like projections interdigitating with similar projections from the opposite wall. The projections originated from the surface ectoderm and possibly neural crest cells. During further fusion the surface ectoderm cells formed dense membrane specializations, thus establishing a firm contact.The initial contact in the mesencephalon was formed by extensions from the surface ectoderm and was followed by the formation of specialized membrane junctions, as seen between the surface ectoderm in the rhombencephalon. The neuroepithelial cells facing the gap between the neural walls with their apical ends made contact with the cells from the opposing wall by numerous finger-like projections but membrane specializations failed to develop.The closing mechanism in the prosencephalon and anterior neuropore regions differed from the previous areas in that the initial contact was established by the neuroepithelial cells. Only after this contact had been formed did the surface ectoderm cells close the gap. In contrast with the other areas many phagocytosed particles were seen in the prosencephalon and in the region of the anterior neuropore. Many particles from degenerated cells were found inside healthy surrounding cells. Some of these particles contained nuclear material and cytoplasmic organelles.     

Chromosome translocation (T(2;4)1 Sn)-induced neural tube defects in the mouse embryo

Neural tube closure was studied in embryos obtained from matings of male mice heterozygous for a reciprocal chromosome translocation (T(2;4)1 Sn) with normal female (CFLP) mice. When litters were examined on the 9th to 12th days of gestation, there was a high incidence of resorption, developmental delay and neural tube closure defects in these embryos. SEM observations indicated that the neural tube closure defects ranged in severity from a side-to-side flattening of the midbrain to extensive anomalies in which the entire cephalic neural tube had failed to close. In addition to cephalic defects, a number of embryos exhibited open defects or abnormal subectodermal blebbing in the future lumbosacral region. In spinal regions, even in areas in which the neural tube had previously closed, it often was irregular and folded. These observations are discussed in relation to studies of gene-related defects of neural tube closure.     

Neurulation in the mouse: manner and timing of neural tube closure

The manner and timing of neural fold fusion in primary neurulation were studied in 1,575 normal ICR mouse embryos by using binocular dissecting, light, and scanning electron microscopy. The initial fusion of apposing neural folds occurred at the level of the intermediate point between the third and fourth somites (i.e., in the caudal myelencephalon) and proceeded both rostrally and caudally. A second fusion occurred at what was originally the rostral end of the neural plate and proceeded rostrodorsally. A third fusion occurred in the caudal diencephalon and proceeded both rostrally and caudally. This was followed by complete closure of the telencephalic neuropore at the midpoint of the telencephalic roof and then complete closure of the metencephalic neuropore at the rostral part of the metencephalic roof. A fourth fusion occurred at what was originally the caudal end of the neural plate and proceeded rostrally. Finally, the caudal neuropore completely closed at the level of the caudal end of the future 33rd somite.     

Morphogenetic movements during cranial neural tube closure in the chick embryo and the effect of homocysteine

In order to unravel morphogenetic mechanisms involved in neural tube closure, critical cell movements that are fundamental to remodelling of the cranial neural tube in the chick embryo were studied in vitro by quantitative time-lapse video microscopy. Two main directions of movements were observed. The earliest was directed medially; these cells invaginated into a median groove and were the main contributors to the initial neural tube closure. Once the median groove was completed, cells changed direction and moved anteriorly to contribute to the anterior neural plate and head fold. This plate developed into the anterior neuropore, which started to close from the 4-somite stage onwards by convergence of its neural folds. Posteriorly, from the initial closure site onwards, the posterior neuropore started to close almost instantaneously by convergence of its neural folds. Homocysteine is adversely involved in human neural tube closure defects. After application of a single dose of homocysteine to chick embryos, a closure delay at the initial closure site and at the neuropores, flattening of the head fold and neural tube, and a halt of cell movements was seen. A possible interference of Hcy with actin microfilaments is discussed. Electronic Supplementary Material Supplementary material is available for this article at     

Characterization of intercellular junctions in the caudal portion of the developing neural tube of the chick embryo

The types of intercellular junctions present within caudal levels of the chick neural tube (i.e., future lower thoracic and lumbosacral regions of the spinal cord) were determined by freeze-fracture of stage 14 to 16 embryos. Two levels of the developing neural tube were examined: the region of the neurulation overlap zone–consisting of primary neural tube dorsally and secondary neural tube ventrally–and the portion of the primary neural tube located just cranial to the overlapping region. Gap junctions were the most numerous type of intercellular junction present within the primary neural tube. These junctions were located primarily in juxtaluminal areas, near the apices of neuroepithelial cells, and sometimes also at the bases of these same cells. In addition, focal, poorly defined tight junctions occasionally occupied juxtaluminal regions of the primary neural tube. The medullary cord (i.e., the immediate precursor of the secondary neural tube) and secondary neural tube contained gap junctions exclusively. Gap junctions were first found in these areas at the lateral borders of the medullary cord, concomitant with formation of this structure, and then at the interface between the elongated, peripheral cells of the cord and the irregularly shaped and loosely arranged central cells of this structure. Finally, gap junctions were distributed radially around secondary lumina formed by cavitation. The precise spatial and temporal correlation between the appearance of gap junctions and the specific changes occurring in cellular morphology and arrangement during secondary neurulation strongly suggest that gap junctions may have a role in coordinating cellular activities during formation of both the medullary cord and the secondary neural tube.     

Cytoskeletal architecture of the matrix cell and neuroblast in the neural tube of the chick embryo.

Cytoskeletal architecture of the matrix cell and neuroblast in the wall of midbrain of 4-6 day-old chick embryos was examined by electron microscopy and immunohistochemistry. The matrix cell, the undifferentiated stem cell later producing neurons and glial cells in the central nervous system, is characterized ultrastructurally by abundant free ribosomes and a poorly developed cytomembrane system. A few microtubules running in random directions are observed in the matrix cell body. In the cell processes, microtubules are oriented longitudinally, and linked with each other by cross-bridges, presumably composed of microtubule-associated proteins (MAPs). The cell processes contain abundant cytoplasmic filaments including a large amount of actin filaments which adhere to the plasma membrane of junctional complexes located immediately below the inner surface of the neural tube. In the neuroblast which has been differentiated from the matrix cell, the cytomembranous organelles, especially rough endoplasmic reticulum are markedly better developed than in the matrix cell; microtubules are more numerous in the cell body. The cell process contains many microtubules with cross-bridges and a few intermediate filaments, which are relatively characteristic of the cytoskeleton of the neuroblast. Phalloidin-staining and immunohistochemistry showed that the neuroblast was richer in F-actin, beta-tubulin, MAP1, MAP2, tau, calspectin, and synapsin I than the matrix cell. As the matrix cell differentiates into the neuroblast, both the cytoskeletal and cytomembranous systems proved to develop features, characteristic of a neuron.     

Acetylcholinesterase in neural tube defects: A model using chick embryo amniotic fluid

Acetylcholinesterase was measured in amniotic fluid from normal chick embryos and embryos with neural tube defects. Neural tube defects were induced in the chick embryos by three procedures, removal of albumen, mechanical disruption of the closed neural tube or injection of tetanus toxin.The concentration of acetylcholinesterase in amniotic fluid from untreated normal embryos changed throughout the period examined (5–14 days incubation) but was stable at 0.5 Ul^?1 over the time period 6–11 days. Amniotic fluid taken from treated embryos with neural tube defects at 8 days always contained a higher concentration of acetylcholinesterase than fluid from sham operated but otherwise normal embryos, mean 40.9 Ul^?1,S.E.M. = 10.1 Ul^?1,versus 1.0 Ul^?1,S.E.M. = 0.2 Ul^?1. The range of values (6.1–393 Ul^?1) was clearly separated from the normal values, range 0.0–5.5 Ul^?1. In 13 cases with developmental abnormalities other than neural tube defects, the concentration of acetylcholinesterase was elevated in only one. Two different forms of acetylcholinesterase, as shown by gel electrophoresis, were present in fluid form both normal and defective embryos. These forms were also present in blood plasma, cerebrospinal fluid and in the high speed supernatant from brain extracts, the latter tissue contained an additional form of greater electrophoretic mobility.After irreversible inhibition, enzyme activity in amniotic fluid recovered slowly; only half the control value was reached by 140 h compared with complete recovery in the tissues of the embryo within 19 h. Histochemical staining for acetycholinesterase showed that the spinal cord in the region of the lesion contained high concentrations of the enzyme. The possible sources of acetylcholinesterase in amniotic fluid are discussed.This chicken model of neural tube defects provides support for the use of acetylcholinesterase tests in the detection of neural tube defects clinically, and provides a model for experimentation with this system.