Abnormal neural fold development in mouse trisomy 12 and trisomy 14. II. LM and TEM

Effects of the curly tail genotype on neuroepithelial integrity and cell proliferation during late stages of primary neurulation

The curly tail (ct/ct) mouse mutant shows a high frequency of delay or failure of neural tube closure, and is a good model for human neural tube defects, particularly spina bifida. In a previous study we defined distinct domains of gene expression in the caudal region of non-mutant embryos during posterior (caudal) neuropore closure (Gofflot et al. Developmental Dynamics 210, 431-445, 1997). Here we use BrdU incorporation into S-phase nuclei to investigate the relationship between cell proliferation and the previously described gene expression domains in ct/ct mutant embryos. The BrdU-immunostained sections were also examined for abnormalities of tissue structure; immunohistochemical detection of perlecan (an extracellular heparan sulphate proteoglycan) was used as an indicator of neuroepithelial basement membrane structure and function. Quantitation of BrdU uptake revealed that at early stages of neurulation, cell proliferation was specifically reduced in the paraxial mesoderm of all ct/ct embryos compared with wild type controls, but at later stages (more cranial levels) it was increased. Those ct/ct embryos with enlarged posterior neuropore (indicating delay of closure) additionally showed an increased BrdU labelling index within the open neuroepithelium at all axial levels; however, this tissue was highly abnormal with respect to cell and nuclear morphology. It showed cell death and loss of cells from the apical surface, basement membrane defects including increased perlecan immunoreactivity, and increased separation from the underlying mesenchyme and notochord. These observations suggest that the mechanism of delay or failure of neuroepithelial curvature that leads to neural tube defects in curly tail embryos involves abnormalities of neuroepithelial-mesenchymal interactions that may be initiated by abnormal cellular function within the neuroepithelium. Minor histological and proliferation abnormalities are present in all ct/ct embryos, regardless of phenotype.

Mouse autosomal trisomy: two's company, three's a crowd

Autosomal trisomy causes a large proportion of all human pregnancy loss and so is a significant source of lethality in the human population. The autosomal trisomy syndromes each have a different phenotype and are probably caused by the effects of specific genes that are present in three copies, rather than the normal two. Identifying these genes will require the application of classical genetic and new genome-manipulation approaches. Recent advances in chromosome engineering are now allowing us to create precisely defined autosomal trisomies in the mouse, and so provide new routes to identifying the critical, dosage-sensitive genes that are responsible for these highly deleterious, yet very common, syndromes.

Genetic landmarks for defects in mouse neural tube closure

Many mutations cause neural tube closure defects (NTDs, exencephaly or spina bifida) in mice and the gene loci are widely distributed in the mouse genome. This compilation summarizes the map position of 40 mouse NTD mutations and the corresponding human linkage homology of each. It includes the nature of the gene product where known, and whether the NTD is part of a syndrome involving other developmental systems. Also listed are the several mouse strains known to have genetic susceptibility to exencephaly, with multifactorial genetic cause in at least one case. The purposes of this mouse NTD compilation are to enable recognition of patterns in genetic causes of NTDs, of molecular pathways essential for closure of specific regions of the mammalian neural tube, and of candidate regions for mapping loci contributing to human multifactorial NTDs.

Gene trap capture of a novel mouse gene, jumonji, required for neural tube formation

A mouse mutation, termed jumonji (jmj), was generated by a gene trap strategy. Expression of the trapped gene (jmj gene), as monitored by X-gal staining, was detected predominantly at the midbrain-hindbrain boundary and in the cerebellum, depending on the stage of development. All embryos homozygous for the jmj mutation died before embryonic day 15.5. Some, but not all, of the homozygotes developed an abnormal groove in a region just anterior to the midbrain-hindbrain boundary on the neural plate at embryonic day 8-8.5 and showed a defect in neural tube closure in the midbrain region. Analyses of jmj cDNA revealed that the jmj gene is novel, conserved among vertebrates, and disrupted by vector insertion in the jmj homozygotes. The amino acid sequence deduced from the cDNA shared a portion of significant homology with human retinoblastoma-binding protein RBP-2 and with a putative protein encoded by human gene XE169 that escapes X-chromosome inactivation. These results suggest that jmj gene is essential for normal morphogenesis of the neural tube.

Methanol-induced neural tube defects in mice: pathogenesis during neurulation

A spectrum of cephalic neural tube defects was observed in near-term (gestation day [GD] 17) mouse fetuses following maternal inhalation of methanol at a high concentration (15,000 ppm) for 6 hr/day during neurulation (GD 7-9). Dysraphism, chiefly exencephaly, occurred in 15% of fetuses, usually in association with reduction or absence of multiple bones in the craniofacial skeleton and ocular anomalies (prematurely open eyelids, cataracts, retinal folds). Measurements of cerebrocortical width in grossly normal, methanol-exposed fetuses revealed significant semiquantitative differences in the thicknesses of the frontal cortex and its constituent layers (neuroepithelium, intermediate cortex/subventricular plate, and cortical layer 1) as well as apparent increases in subventricular plate cellularity relative to controls. Subsequently, the early morphogenesis of these neural changes was investigated in neurulating mouse embryos to define tissue-specific patterns of methanol-induced damage that lead to cephalic axial dysraphism. Following daily 6-hr maternal inhalations of 15,000 ppm methanol during GD 7-8, the cephalic neural fold margins were swollen, blunted, and poorly elevated on GD 8.5 and 9 relative to controls. Histopathology of exposed GD 8.5 embryos revealed microcephaly in association with reductions in the cell density and mitotic index of at least 47% in the cranial mesoderm. The mitotic index in the embryonic neuroepithelium was also reduced by 55%, and groups of neural crest cells were displaced to the neural folds dorsal to the foregut (relative to the more ventral location in the facial regions of control embryos). When examined on GD 9.5 and 10.5, maternal methanol exposure (15,000 ppm for 6 hr/day) during GD 7-9 resulted in stunting, delayed rotation, and microcephaly in over 90% of the affected embryos. Persistent patency of the anterior neuropore and prosencephalic hypoplasia were seen in > 40% and up to 90% of embryos, respectively. Shallow optic vesicles, stunted branchial arches, scoliosis, and hydropericardium were also observed. Many 10.5-day-old embryos were edematous. Occult dysraphism, recognized grossly by abnormally narrow cephalic conformation and histopathologically by the absence of mesoderm in the mesencephalon, was present in at least 21% of methanol-exposed embryos on GD 9.5 and 10.5. Nile blue vital dye staining of methanol-exposed embryos revealed no difference in dye accumulation between control and treated embryos on GD 8.5, 9.0, or 9.5. There were no apparent dysmorphogenic effects in control embryos at any stage of development.(ABSTRACT TRUNCATED AT 400 WORDS)

Development of anencephaly and its variants

Extreme variants of anencephaly in two human embryos of the same stage, namely 22 (54 days), shed new light on problems such as craniocerebral interrelationships and the timing of developmental events. Embryo X had a chondrocranium that possessed features typical of a holoacranial anencephalic skull and an extremely well-preserved brain, in which some of the neural tracts were comparable to those in a normal control. On the other hand, embryo Y of the same stage had a completely degenerated brain, although the chondrocranium was more nearly normal and represented the precursor of a meroacranial skull. A comparison of the two cases seems to indicate a certain independence between skull and brain. Moreover, it appears possible that the disturbances are related primarily to the skeletal, and only secondarily to the nervous, component. Comparisons with experimental data allow the conclusion that the maldevelopment involves mostly paraxial mesenchyme and little or no disturbance of neural crest. The timing of the mesenchymal defect is probably as early as stages 8 and 9 (18-20 days). This is also the time at which mesenchymal defects can result in failure of the neural tube to close.

Methionine and neural tube closure in cultured rat embryos: morphological and biochemical analyses

When headfold-stage rat embryos were cultured on cow serum, their neural tubes failed to close unless the serum was supplemented with methionine. Methionine deficiency did not appear to affect the ability of the neural epithelium to fuse as a type of fusion was observed between anterior and posterior regions of the open neural tube in methionine-deficient embryos. Although methionine deficiency reduced the cell density and mitotic indices of cranial mesenchyme and neural epithelial cells, this did not appear to be a factor in failure of the neural tube to close. For example, embryos cultured on diluted cow serum also had fewer mesenchymal cells yet could complete neural tube closure if provided with methionine. Examination of the tips of the neural folds suggested that microfilament contraction could be involved; in the absence of methionine the neural folds failed to turn in. This possibility was supported by the reductions in neurite extension of isolated neural tubes cultured without methionine and by the reductions in microfilament associated methylated amino acids contained in embryo neural tube proteins.

Developmental study of neural tube closure in a mouse stock with a high incidence of exencephaly

About 17% of embryos and fetuses in the SELH/Bc mouse stock have the anterior neural tube defect, exencephaly. No other malformations are seen. The genetic liability to exencephaly was shown to be probably genetically fixed in the SELH/Bc stock. This means that SELH/Bc embryos with successful neural tube closure are genetically the same as exencephalics. Females were significantly more likely to be affected than males (66% females). The pattern of morphological developmental events during anterior neural tube closure on days 8 and 9 of gestation was compared among 322 ICR/Bc (normal), 304 SWV/Bc (normal), and 265 SELH/Bc embryos. Anterior neural tube closure was found to follow a strikingly different pattern in almost all SELH/Bc embryos than in either of the normal strains or in previous published studies. SELH/Bc embryos lack the initial contact between the anterior folds in the posterior prosencephalon/anterior mesencephalon region (Closure 2). In spite of this, all but 17% manage to close the anterior neural tube by extending caudally the later occurring normal anterior zone of contact and fusion at the most rostral aspect of the prosencephalon (Closure 3) through the region of Closure 2 to meet the zone of closure of the rhombencephalon, Closure 4. Anterior neural tube closure was completed late, and in some SELH/Bc embryos, elevation and fusion in the mesencephalon did not occur at all. In histological sections of six- and eight-somite embryos, elevated numbers of pyknotic cells in the neuroepithelium and mesenchyme, and elevated numbers of unstained inclusions in the neuroepithelium were found; but their relationship, if any, to the abnormal pattern of neural tube closure is not clear.

Basal lamina and extracellular matrix alterations in the caudal neural tube of the delayed Splotch embryo

Regional patterns of deposition of laminin (LN), fibronectin (FN), type IV collagen (IV), and heparan sulfate proteoglycan (HSPG) were examined during the formation of the caudal neural tube in embryos homozygous for the delayed Splotch gene and in their normal littermates. Delayed Splotch embryos had neural tube closure defects which extended from the posterior neuropore into the region formed by secondary neurulation. During posterior neuropore closure these components were normally restricted to forming basal laminae, with FN and HSPG additionally deposited in the mesenchyme. Unlike control embryos in which medial regions of the neuroepithelial basal lamina contained greatest amounts of all four, the dorsolateral zone contained less LN and IV and more FN and HSPG, in affected embryos these components were less densely deposited medially, reflecting perhaps the poor structural organization of the notochord. The neuroepithelial basal lamina was often disorganized and wavy compared to the linear pattern typical of controls. By the 12th day, the posterior neuropore of controls had closed and secondary neurulation was underway; however in delayed Splotch embryos, the neural folds remained widely splayed and epithelium newly formed via secondary neurulation extended that abnormally open configuration to the tip of the tailbud. In controls, with mesenchymal cell aggregation FN and HSPG were displaced from between cells to the forming basal lamina. As a central lumen formed within the aggregate LN and IV were added to the basal lamina, and the newly formed epithelium merged with the anterior neural tube. In delayed Splotch embryos, FN and HSPG were incompletely removed from aggregating cell surfaces, the normal morphogenetic cell shaping changes failed to occur and in many embryos a central lumen did not form; the overgrown, aggregated cells merging with the abnormally splayed anterior neural folds. In addition, the critical enrichment of FN and HSPG present between newly formed and consolidated neuroepithelium was displaced in delayed Splotch embryos.

Autosomal aneuploidy in mice: generation and developmental consequences

Spontaneous aneuploidy in the mouse is uncommon, but specific mating schemes have been developed that produce aneuploid conceptuses at high frequencies. The most commonly reported aneuploid condition in the mouse is autosomal trisomy, in which there is an extra copy (in whole or in part) of a chromosome. In this review, we present several of the schemes used in producing trisomic, partially (tertiary) trisomic, and monosomic conceptuses and summarize the developmental consequences that are associated with each of the autosomal trisomies of the mouse.