Cranial effects of retinoic acid in the loop-tail (Lp) mutant mouse

The effects of retinoic acid (RA) on the manifestation and nature of neural tube defects (NTD) in heterozygous embryos of mutant mice carrying the gene loop-tail (Lp) and in normal (+/+) littermates and embryos from normal homozygous matings were compared with NTD that occur in untreated abnormal homozygous (Lp/Lp) embryos. A single intraperitoneal dose (5 mg/kg) of RA administered at 9 AM or 3 PM on day 8 of gestation induced NTD in +/+ as well as Lp/+ embryos removed on day 12 of gestation. All of the NTD were confined to the brain and consisted of exencephaly involving the diencephalon, mesencephalon, and metencephalon. In neither phenotype (Lp/+; +/+) was the massive exencephaly and myeloschisis characteristic of untreated Lp/Lp embryos produced; thus, it is possible that the teratogenic mechanisms of RA-induced defects and of Lp-induced defects may differ.     

Abnormal elevation of the neural folds in the loop-tail mutant mouse.

The processes of elevation and convergence of the spinal neural folds were analyzed in normal (+/+; Lp/+) and abnormal (Lp/Lp) embryos of the loop-tail mutant mouse in order to determine possible mechanisms underlying the dysraphic defect characterized by a failure of the neural fold to close in this mutant. The results indicate that the neural folds are already defective during very early phases of elevation, with greater distances between the apical points of the paired walls of the neural groove, larger ventral angles and higher ratios of luminal/basal linear distances occurring in the abnormal embryos relative to those in normal embryos. The cross-sectional area of the neuroepithelium is also greater in abnormals, suggesting that faulty elongation of the neuraxis may contribute to the dysraphic condition.     

Ultrastructural analysis of the midaxial extracellular matrix in spinal dysraphism.

Ultrastructural aspects of the extracellular matrix (ECM) in the midaxial region of dysraphic embryos of the loop-tail (Lp) mutant mouse were analyzed by means of electron microscopy. In 17-23 somite embryos, ultrastructural differences in the ECM occurred with respect to the presence of a pair of long trailing basal laminar strands extending continuously from the ventral notochordal cells to the gut in abnormal (Lp/Lp) embryos, in contrast to short, ragged, discontinuous strands in normal (+/+; Lp/+) embryos. The ultrastructural localization and configuration of fibronectin (FN) and laminin (L) associated with these strands, however, were similar in normals and abnormals. In addition, FN occurred over interstitial bodies, fibrils, and sporadically along the basal laminae of the neural tube (or folds), notochord, gut, and vessels, whereas L was largely confined to the basal laminae. The results indicate that although the ultrastructural pattern of FN and L reactivity are similar in normal and abnormal embryos, a disturbance in the manner whereby the notochord detaches from the gut in dysraphic embryos may be of causal significance in the etiology of dysraphism in this mutant.     

All-or-none craniorachischisis in Loop-tail mutant mouse chimeras

Mouse embryos homozygous for the mutant gene Loop-tail (Lp) are characterized by craniorachischisis, an open neural tube extending from the midbrain to the tail. In the present study, experimental chimeric mice containing mixtures of genetically mutant (from Lp/+ x Lp/+ matings) and genetically normal cells were produced. Our aim was to determine whether a 'rescue,' phenotypic gradient, or intermediate expression (i.e. alternating areas of open and closed neural tube) would be observed in these chimeras. We report our analyses of Loop-tail mutant chimeras (n = 82) by gross examination, progeny testing and quantitative analysis of glucose phosphate isomerase (GPI) isozyme levels. An all-or-none craniorachischisis in Loop-tail mutant chimeras was observed. Two multicolored adult chimeras, without any gross evidence of a neural tube defect, were shown to be homozygous Loop-tail chimeras (Lp/Lp in equilibrium +/+) by progeny testing. These results indicate that the normal phenotype can be expressed in the presence of mutant cells. Conversely, six neonates with craniorachischisis were shown to be chimeras by GPI analyses. These results show that the full mutant phenotype can be expressed even when one-third to one-half of the cells are genotypically wild-type. This study did not determine which tissue is primarily responsible for the defective neurulation in this mutant, but suggests that a 'threshold' mechanism underlies the Loop-tail mutant phenotype. In some chimeras that threshold is not reached and the neural tube remains open, whereas in other chimeras the threshold is reached and the neural tube closes completely.     

Deposition of laminin and fibronectin in dysraphic mutant mice: an immunofluorescent study

Abnormal loop-tail (Lp/Lp) mutant mouse embryos exhibiting severe exencephaly and myeloschisis were analyzed and compared with their normal (+/+; Lp/+) littermates by means of immunofluorescence histochemistry to determine regional differences in the distribution of laminin (L) and fibronectin (FN). In the neural basement membrane and adjacent mesenchymal cell matrix of the abnormal embryos, regional differences in the deposition of L and FN were similar to those in normal littermates. Moreover, most of the putative neural crest (NC) cells appeared to emigrate normally in terms of their site of detachment and migration pathways, despite the severe topographic distortions and loss of neuroepithelial integrity. However, some putative NC cells projected incorrectly from the 'luminal' surface of the neuroepithelium, suggesting that some of the NC may be abnormal or sequestered and prevented from appropriate detachment and emigration from the neural tube.     

Effects of the removal of neural crest anlage upon endodermal morphogenesis and primordial germ cells migration in toad embryo

Summary The anlagen of neural tube or neural tube and neural crests were removed from toad embryos at the early neurula stage. The removal of the neural tube anlage does not affects the normal development of embryos. The removal of neural tube plus neural crest anlagen results in major disturbances of both endodermal morphogenesis and primordial germ cell migration. The possible indirect influence of neural crest cells upon the migration of the primordial germ cells is discussed. The neural crests cells could be involved in the formation and/or release of an attractive morphogen from embryonic chordomesoderm responsible for the migration of the primordial germ cells.     

Rescue of the neural tube defect of loop-tail mice by a BAC clone containing the Ltap gene

The mouse mutant loop-tail (Lp) is an accepted model for the study of neural tube defects (NTDs) in humans. Whereas Lp/+ heterozygotes show a mild tail defect (looped), homozygous Lp/Lp embryos show a very severe form of NTD, with a completely open neural tube from the hindbrain region to the caudal portion of the spinal cord (craniorachischisis). We have recently identified a positional candidate for Lp on chromosome 1, designated as Ltap. Here, we have used an in vivo complementation approach in transgenic mice to attempt to correct the looped-tail phenotype with a bacterial artificial chromosome clone (BAC280A23) that harbors a full-length copy of the Ltap gene. Genotype:phenotype correlations in Lp/+ heterozygotes carrying BAC280A23 show that this clone can rescue the looped-tail phenotype in two independent founder lines (P < 0.05 and P < 0.0001). Importantly, BAC280A23 is also observed to rescue the lethal NTD of Lp/Lp homozygotes, because several viable transgenic Lp/Lp mice could be identified and appeared normal (P < 0.05). Results from these gain-of-function transgenic animals strongly suggest that the positional candidate Ltap present in this BAC is indeed the gene that is defective in loop-tail.     

The fine structure of ventricular cells in the brains of mouse embryos homozygous for the loop-tail gene

The neural tube in normal (+/+), heterozygous (Lp/+), and abnormal (Lp/Lp) mutant mouse embryos ranging in age from 10 to 12 days of gestation was studied by means of transmission electron microscopy. In the abnormal embryos, ventricular cells in defective regions of the brain show distortions and crowding together of internal cellular processes and a decrease in blebs and bulbous projections, as compared with their normal counterparts. At 12 days' gestation the abnormal brains show a scarcity of the T-shaped internal cellular processes characteristic of normal brains. The abnormal brains also show increased amounts of intercellular space and extensive gaps between the cells, particularly in basal regions. There are no striking differences between the normal and abnormal brains at 10 to 12 days' gestation with respect to the appearance and distribution of cilia, microfilaments, microtubules, tight junctions, and ribosomes.     

Analysis of the effect of the loop-tail gene in mouse embryos]

Mitotic index and parameters of the cell cycle were determined in the brain and spinal cord of 10 days old Lp/Lp and +/+ mouse embryos. The mitotic index and duration of the cell cycle periods proved to be the same for embryos of both the genotypes. The generation time of the brain and spinal cord cells both in the mutant and normal embryos is 9 hrs, durations of S- and G2-periods 6 and 1, resp., and the total duration of G1- and M-periods 2. The gene Lp does not interact with the gene Sp in double heterozygotes. The gene Lp does not manifest itself in the cells of differentiating central nervous system and the failure of the neural tube closure is not due to the changes in the proliferative activity of its cells and is a secondary gene effect.     

Ultrastructural analysis of the midaxial extracellular matrix in spinal dysraphism

Ultrastructural aspects of the extracellular matrix (ECM) in the midaxial region of dysraphic embryos of the loop-tail (Lp) mutant mouse were analyzed by means of electron microscopy. In 17–23 somite embryos, ultrastructural differences in the ECM occurred with respect to the presence of a pair of long trailing basal laminar strands extending continuously from the ventral notochordal cells to the gut in abnormal (Lp/Lp) embryos, in contrast to short, ragged, discontinuous strands in normal (+ /+;Lpj +) embryos. The ultrastructural localization and configuration of fibronectin (FN) and laminin (L) associated with these strands, however, were similar in normals and abnormals. In addition, FN occurred over interstitial bodies, fibrils, and sporadically along the basal laminae of the neural tube (or folds), notochord, gut, and vessels, whereas L was largely confined to the basal laminae. The results indicate that although the ultrastructural pattern of FN and L reactivity are similar in normal and abnormal embryos, a disturbance in the manner whereby the notochord detaches from the gut in dysraphic embryos may be of causal significance in the etiology of dysraphism in this mutant.     

Zebrafish foxi1 mediates otic placode formation and jaw development

The otic placode is a transient embryonic structure that gives rise to the inner ear. Although inductive signals for otic placode formation have been characterized, less is known about the molecules that respond to these signals within otic primordia. Here, we identify a mutation in zebrafish, hearsay, which disrupts the initiation of placode formation. We show that hearsay disrupts foxi1, a forkhead domain-containing gene, which is expressed in otic precursor cells before placodes become visible; foxi1 appears to be the earliest marker known for the otic anlage. We provide evidence that foxi1 regulates expression of pax8, indicating a very early role for this gene in placode formation. In addition, foxi1 is expressed in the developing branchial arches, and jaw formation is disrupted in hearsay mutant embryos.     

Invagination of the otic placode: normal development and experimental manipulation

The inner ear forms from paired ectodermal primordia that lie to either side of the developing hindbrain. Initially each primordium forms a shallow depression in the ectodermal surface. Invagination to form an otic pit coincides with the formation of several deep folds in the epithelial surface. An initial fold appears parallel to the embryonic axis and at the junction of the rhombencephalon with somitomeric mesoderm. This is followed by formation of cranial and caudal folds perpendicular to the axis and minor folds that are within the pit formed by earlier folding. The central region of the otic primordium remains in close apposition to the lateral surface of the neural tube during the process of fold formation, until the otic pit becomes quite deep. At that time, mesenchymal cells penetrate between the two layers. Experimental analysis of invagination supports the conclusion that otic invagination is controlled differently from that of similar organ primordia, such as the eye and thyroid. Whereas these other primordia can be stimulated to undergo normal morphogenetic shape changes precociously by treatments that presumably activate motile processes in the cytoskeleton, the same conditions have little effect on the otic placode. Similarly, neither inhibitors of calcium transport nor inactivators of calmodulin activity prevent otic pit formation, while these drugs block invagination of other primordia. These results suggest that otic invagination may be caused by changes in the surrounding tissues rather than by an activation of motility within the primordium.     

Tissue, cellular and sub-cellular localization of the Vangl2 protein during embryonic development: effect of the Lp mutation

Loop-tail (Lp) mice show a very severe neural tube defect, craniorachischisis, which is caused by mis-sense mutations in the Vangl2 gene. The membrane protein Vangl2 belongs to a highly conserved group of proteins that regulate planar polarity in certain epithelia, and that are also important for convergent extension movements during gastrulation and neurulation. A specific anti-Vangl2 antiserum was produced and used to examine the tissue, cell type, and sub-cellular localization of Vangl2 during embryogenesis. Vangl2 protein is expressed at high levels in the neural tube and shows a dynamic expression profile during neurulation. After neural tube closure, robust Vangl2 staining is detected in several neural and neurosensory tissues, including cerebral cortex, dorsal root ganglia, olfactory epithelium, retina, mechanosensory hair cells of the cochlea, and optic nerve. Vangl2 is also expressed during organogenesis in a number of tubular epithelia, including the bronchial tree, intestinal crypt/villus axis, and renal tubular segments derived from ureteric bud and from metanephric mesenchyme. Examination of Vangl2 localization in the neural tubes and cochleas of the normal and Lp/Lp embryos shows disruption of normal membrane localization of Vangl2 in independent alleles at Lp (Lp, Lp(m1Jus)) as well as overall decrease in the expression level.     

Gap junctional vesicles in the neural tube of the splotch (Sp) mutant mouse.

The lumbosacral region of the neural tube was studied by means of transmission electron microscopy in retrospectively confirmed normal (+/+; Sp/+) and abnormal (Sp/Sp) embryos of the splotch mutant mouse early on the ninth day of gestation when the caudal neural groove is normally in the process of closing to form the neural tube. In abnormal embryos, a consistent feature is the presence of gap junctional vesicles, particularly in the region of the neural groove which subsequently fails to close, whereas these structures are rarely observed in similar areas of normal embryos. The possible significance of gap junctional vesicles is discussed in terms of cellular adhesion during early neurogenesis.     

The Hectd1 ubiquitin ligase is required for development of the head mesenchyme and neural tube closure

Closure of the cranial neural tube depends on normal development of the head mesenchyme. Homozygous-mutant embryos for the ENU-induced open mind (opm) mutation exhibit exencephaly associated with defects in head mesenchyme development and dorsal-lateral hinge point formation. The head mesenchyme in opm mutant embryos is denser than in wildtype embryos and displays an abnormal cellular organization. Since cells that originate from both the cephalic paraxial mesoderm and the neural crest populate the head mesenchyme, we explored the origin of the abnormal head mesenchyme. opm mutant embryos show apparently normal development of neural crest-derived structures. Furthermore, the abnormal head mesenchyme in opm mutant embryos is not derived from the neural crest, but instead expresses molecular markers of cephalic mesoderm. We also report the identification of the opm mutation in the ubiquitously expressed Hectd1 E3 ubiquitin ligase. Two different Hectd1 alleles cause incompletely penetrant neural tube defects in heterozygous animals, indicating that Hectd1 function is required at a critical threshold for neural tube closure. This low penetrance of neural tube defects in embryos heterozygous for Hectd1 mutations suggests that Hectd1 should be considered as candidate susceptibility gene in human neural tube defects.     

Histochemical analysis of the neural basal lamina in the hindbrain region of exencephalic mutant mice

The neural basal lamina in hindbrain regions of exencephalic loop-tail (Lp/Lp) mice and of their normal (+/+; Lp/+) littermates was analyzed histochemically at the electron microscopic level by means of enzyme digestion and alcian blue staining with critical electrolyte concentrations (CEC) of MgCl2. At 9 days of gestation, the normal and abnormal embryos showed a similar pattern of alcian blue staining with a CEC of 0.00 M or 0.05 M MgCl2. However, with a CEC of 0.30 M MgCl2, the basal lamina in the abnormals stained more prominently, particularly the lamina rara externa, suggesting the presence of more sulfated glycosaminoglycans (GAG) in the abnormals. Moreover, predigestion of the tissues with Streptomyces hyaluronidase, which removes hyaluronic acid (HA), indicated that the abnormal basal lamina contained relatively less HA than in the normal embryos. By 10 days of gestation the normal basal lamina contained relatively more sulfated GAG and less HA and was thus more similar in appearance to that in the abnormal embryos. This apparently premature shift from HA predominance to sulfated GAG predominance in the abnormal basal lamina may be of significance in the etiology of dysraphism in this mutant.     

In vivo effect of brain-derived neurotrophic factor on the survival of developing dorsal root ganglion cells.

Implantation of silastic membranes between neural tube and somites at somitic levels 20-24 in 30-somite-stage chick embryos results in separation of early migrated neural crest cells of the dorsal root ganglion (DRG) anlage from the neural tube and their death within a few hours [Kalcheim and Le Douarin, (1986) Dev. Biol., 116, 451-460]. The in vivo effects of brain-derived neutrotrophic factor (BNDF) on survival of HNK-1 immunoreactive DRG cells separated from the tube were examined by implantation of laminin-treated silastic membranes (controls) or BDNF/laminin-treated membranes. In the presence of BDNF/laminin-treated membranes, 20/25 grafted embryos fixed 10 h after implantation, contained many rescued cells on the operated side. In contrast, only a few rescued cells on the operated side. In contrast, only a few rescued cells were observed in sections on the operated in 2/11 embryos implanted with laminin-treated silastic membranes, and no rescued cells at all could be detected in embryos implanted with NGF/laminin-treated (seven embryos) or untreated silastic membranes (12 embryos). The data presented support the hypothesis that early survival and differentiation of neural crest-derived sensory cells depend on central nervous system-derived factor(s). Moreover, this is the first evidence for the in vivo activity of BDNF on survival of developing DRG cells.     

Pre‐/post‐otic rhombomeric interactions control the emergence of a fetal‐like respiratory rhythm in the mouse embryo

How regional patterning of the neural tube in vertebrate embryos may influence the emergence and the function of neural networks remains elusive. We have begun to address this issue in the embryonic mouse hindbrain by studying rhythmogenic properties of different neural tube segments. We have isolated pre‐ and post‐otic hindbrain segments and spinal segments of the mouse neural tube, when they form at embryonic day (E) 9, and grafted them into the same positions in stage‐matched chick hosts. Three days after grafting, in vitro recordings of the activity in the cranial nerves exiting the grafts indicate that a high frequency (HF) rhythm (order: 10 bursts/min) is generated in post‐otic segments while more anterior pre‐otic and more posterior spinal territories generate a low frequency (LF) rhythm (order: 1 burst/min). Comparison with homo‐specific grafting of corresponding chick segments points to conservation in mouse and chick of the link between the patterning of activities and the axial origin of the hindbrain segment. This HF rhythm is reminiscent of the respiratory rhythm known to appear at E15 in mice. We also report on pre‐/post‐otic interactions. The pre‐otic rhombomere 5 prevents the emergence of the HF rhythm at E12. Although the nature of the interaction with r5 remains obscure, we propose that ontogeny of fetal‐like respiratory circuits relies on: (i) a selective developmental program enforcing HF rhythm generation, already set at E9 in post‐otic segments, and (ii) trans‐segmental interactions with pre‐otic territories that may control the time when this rhythm appears. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006