Heparitinase treatment of rat embryos during cranial neurulation

Vangl2-environment interaction causes severe neural tube defects, without abnormal neuroepithelial convergent extension

Planar cell polarity (PCP) signalling is vital for initiation of mouse neurulation, with diminished convergent extension (CE) cell movements leading to craniorachischisis, a severe neural tube defect (NTD). Some humans with NTDs also have PCP gene mutations but these are heterozygous, not homozygous as in mice. Other genetic or environmental factors may interact with partial loss of PCP function in human NTDs. We found that reduced sulfation of glycosaminoglycans interacts with heterozygosity for the Lp allele of Vangl2 (a core PCP gene), to cause craniorachischisis in cultured mouse embryos, with rescue by exogenous sulphate. We hypothesised this glycosaminoglycan-PCP interaction may regulate CE but, surprisingly, DiO labeling of the embryonic node demonstrates no abnormality of midline axial extension in sulfation-depleted Lp/+ embryos. Positive-control Lp/Lp embryos show severe CE defects. Abnormalities were detected in the size and shape of somites that flank the closing neural tube in sulfation-depleted Lp/+ embryos. We conclude that failure of closure initiation can arise by a mechanism other than faulty neuroepithelial CE, with possible involvement of matrix-mediated somite expansion, adjacent to the closing neural tube.

An explant assay for assessing cellular behavior of the cranial mesenchyme

The central nervous system is derived from the neural plate that undergoes a series of complex morphogenetic movements resulting in formation of the neural tube in a process known as neurulation. During neurulation, morphogenesis of the mesenchyme that underlies the neural plate is believed to drive neural fold elevation. The cranial mesenchyme is comprised of the paraxial mesoderm and neural crest cells. The cells of the cranial mesenchyme form a pourous meshwork composed of stellate shaped cells and intermingling extracellular matrix (ECM) strands that support the neural folds. During neurulation, the cranial mesenchyme undergoes stereotypical rearrangements resulting in its expansion and these movements are believed to provide a driving force for neural fold elevation. However, the pathways and cellular behaviors that drive cranial mesenchyme morphogenesis remain poorly studied. Interactions between the ECM and the cells of the cranial mesenchyme underly these cell behaviors. Here we describe a simple ex vivo explant assay devised to characterize the behaviors of these cells. This assay is amendable to pharmacological manipulations to dissect the signaling pathways involved and live imaging analyses to further characterize the behavior of these cells. We present a representative experiment demonstrating the utility of this assay in characterizing the migratory properties of the cranial mesenchyme on a variety of ECM components.

Organization of the neuroepithelial actin cytoskeleton is regulated by heparan sulfation during neurulation

Heparan sulfate and cytoskeletal actin microfilaments have both been shown to be important regulators of neural tube closure during embryonic development. To determine the functional relationship of these two molecules in formation of the spinal neural tube, we cultured ARC mouse embryos at embryonic day E8.5 in the presence of chlorate, a competitive inhibitor of glycosaminoglycan sulfation, and examined the effects on organization of actin microfilaments in the neuroepithelium. Compared against embryos cultured under control conditions, chlorate-treated embryos had shortened posterior neuropore, a loss of median hinge point formation and increased bending at the paired dorsolateral hinge points. Furthermore, apical organization of actin microfilaments in the neuroepithelial cells was absent, and this was associated with convex bending of the neuroepithelium. The results suggest that heparan sulfate is an important determinant of cytoskeletal actin organization during spinal neurulation, and that its biological action is dependent on sulfation of the heparan molecule.

Does the cranial mesenchyme contribute to neural fold elevation during neurulation?

The central nervous system is derived from the neural plate, which undergoes a series of complex morphogenetic events resulting in formation of the neural tube in a process known as neurulation. The cellular behaviors driving neurulation in the cranial region involve forces generated by the neural tissue itself as well as the surrounding epithelium and mesenchyme. Of interest, the cranial mesenchyme underlying the neural plate undergoes stereotypical rearrangements hypothesized to drive elevation of the neural folds. As the neural folds rise, the hyaluronate-rich extracellular matrix greatly expands resulting in increased space between individual cranial mesenchyme cells. Based on inhibitor studies, expansion of the extracellular matrix has been implicated in driving neural fold elevation; however, because the surrounding neural and epidermal ectoderm were also affected by inhibitor exposure, these studies are inconclusive. Similarly, treatment of neurulating embryos with teratogenic doses of retinoic acid results in altered organization of the cranial mesenchyme, but alterations in surrounding tissues are also observed. The strongest evidence for a critical role for the cranial mesenchyme in neural fold elevation comes from studies of genes expressed exclusively in the cranial mesenchyme that when mutated result in exencephaly associated with abnormal organization of the cranial mesenchyme. Twist is the best studied of these and is expressed in both the paraxial mesoderm and neural crest derived cranial mesenchyme. In this article, we review the evidence implicating the cranial mesenchyme in providing a driving force for neural fold elevation to evaluate whether there are sufficient data to support this hypothesis.

Totally tubular: the mystery behind function and origin of the brain ventricular system

A unique feature of the vertebrate brain is the ventricular system, a series of connected cavities which are filled with cerebrospinal fluid (CSF) and surrounded by neuroepithelium. While CSF is critical for both adult brain function and embryonic brain development, neither development nor function of the brain ventricular system is fully understood. In this review, we discuss the mystery of why vertebrate brains have ventricles, and whence they originate. The brain ventricular system develops from the lumen of the neural tube, as the neuroepithelium undergoes morphogenesis. The molecular mechanisms underlying this ontogeny are described. We discuss possible functions of both adult and embryonic brain ventricles, as well as major brain defects that are associated with CSF and brain ventricular abnormalities. We conclude that vertebrates have taken advantage of their neural tube to form the essential brain ventricular system.

Normal neurulation in mammals

During mammalian neurulation regional differences are evident between the cranial region, in which neurulation is most complex, the trunk as far as the caudal neuropore and the secondary neurulation region of the caudal trunk plus tail. Differences among these three regions are characterized by specific patterns of morphogenesis and by specific patterns of gene expression. During cranial neurulation distinct regions develop in the brain and the presomitic hindbrain forms seven rhombomeric divisions. The first clear morphological boundary is the preotic sulcus (later transformed into the gyrus between rhombomeres 2 and 3), which may limit cell movement as neuroepithelial cells rostral to it flow towards and into the rapidly expanding forebrain region. The formation of rhombomeres as morphological entities and the development of a normal rhombomere-specific pattern of homeobox and other gene expression domains depend on relatively low levels of retinoic acid. Retinoic acid receptors, which are retinoic acid-activated transcription factors, and retinoid binding proteins, which control the availability of retinoic acid to the receptors, show regional patterns of expression in the cranial, trunk and caudal regions of the neuroepithelium during neurulation. These patterns suggest a possible mechanism for region-specific gene expression during neurulation.

Investigation of Direct Toxic and Teratogenic Effects of Anticoagulants on Rat Embryonic Development Using In Vitro Culture Method and Genotoxicity Assay

Heparin and low molecular weight heparins (LMWHs) are used to reduce the incidence of venous thromboembolism in pregnancy. Although, these agents have been shown to be safe when used during pregnancy, the studies about direct toxic and teratogenic effects of these drugs on embryonic development are limited. In this study, the effects of heparin and LMWHs on rat embryonic development were investigated by using in vitro embryo culture and micronucleus (MN) assay methods. Rat embryos were cultured in vitro in the presence of different concentrations of heparin (5-40 IU/ml), dalteparin (2.5-20 IU/ml), enoxaparin (25-100 microg/ml) and nadroparin (1-4 IU/ml). Effects of anticoagulants on embryonic developmental parameters were compared and embryos were evaluated for the presence of any malformations. After culturing the embryos, classic MN assay was performed. Anticoagulants significantly decreased all growth and developmental parameters dose-dependently. Dalteparin and enoxaparin were found to cause more developmental toxicity than heparin and nadroparin. Along with haematoma in general, heparin and nadroparin caused maxillary deformity, situs inversus and oedema most frequently, while neural tube defects were observed with dalteparin and enoxaparin. All agents also significantly induced MN formation in rat embryonic blood cells. These results indicate the possible genotoxic effects of anticoagulant agents on the developing rat embryo when applied directly.

Sulfated proteoglycans as modulators of neuronal migration and axonal decussation in the developing midbrain

Proteoglycans are abundant in the developing brain and there is much circumstantial evidence for their roles in directional neuronal movements such as cell body migration and axonal growth. We have developed an in vitro model of astrocyte cultures of the lateral and medial sectors of the embryonic mouse midbrain, that differ in their ability to support neuritic growth of young midbrain neurons, and we have searched for the role of interactive proteins and proteoglycans in this model. Neurite production in co-cultures reveals that, irrespective of the previous location of neurons in the midbrain, medial astrocytes exert an inhibitory or nonpermissive effect on neuritic growth that is correlated to a higher content of both heparan and chondroitin sulfates (HS and CS). Treatment of astrocytes with chondroitinase ABC revealed a growth-promoting effect of CS on lateral glia but treatment with exogenous CS-4 indicated a U-shaped dose-response curve for CS. In contrast, the growth-inhibitory action of medial astrocytes was reversed by exogenous CS-4. Treatment of astrocytes with heparitinase indicated that the growth-inhibitory action of medial astrocytes may depend heavily on HS by an as yet unknown mechanism. The results are discussed in terms of available knowledge on the binding of HS proteoglycans to interactive proteins, with emphasis on the importance of unraveling the physiological functions of glial glycoconjugates for a better understanding of neuron-glial interactions.

Heparan sulphate proteoglycans and spinal neurulation in the mouse embryo

Heparan sulphate proteoglycans have been implicated in the binding and presentation of several growth factors to their receptors, thereby regulating cellular growth and differentiation. To investigate the role of heparan sulphate proteoglycans in mouse spinal neurulation, we administered chlorate, a competitive inhibitor of glycosaminoglycan sulphation, to cultured E8.5 embryos. Treated embryos exhibit accelerated posterior neuropore closure, accompanied by suppression of neuroepithelial bending at the median hinge point and accentuated bending at the paired dorsolateral hinge points of the posterior neuropore. These effects appear specific, as they can be prevented by addition of heparan sulphate to the culture medium, whereas heparitinase-treated heparan sulphate and chondroitin sulphate are ineffective. Both N- and O-sulphate groups appear to be necessary for the action of heparan sulphate. In situ hybridisation analysis demonstrates a normal distribution of sonic hedgehog mRNA in chlorate-treated embryos. By contrast, patched 1 transcripts are abnormally abundant in the notochord, and diminished in the overlying neuroepithelium, suggesting that sonic hedgehog signalling from the notochord may be perturbed by inhibition of heparan sulphation. Together, these results demonstrate a regulatory role for heparan sulphate in mouse spinal neurulation.

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.

Toxicity of heparin in postimplantation whole-embryo culture

Cranial neural tube defects occur when heparin is added to the culture media of postimplantation rat embryos undergoing organogenesis in vitro. Timed-exposure studies were undertaken to determine whether the defects caused by heparin were the result of defective folding and fusion of the neural folds, or due to reopening of a closed neural tube. Experiments were also undertaken to elucidate whether the in vitro toxicity of heparin was due to an effect of heparin at the level of the culture medium, at the level of the visceral yolk sac, or at the level of the embryo proper. Heparin was found to cause defective folding and closure of the neural folds at between 9.5 and 10.5 days' gestation. Neural tube defects did not occur when embryos were cultured in media prepared using a culture medium depleted of heparin ligands by heparin-agarose affinity chromatography. However, studies with [G-(3)H]heparin demonstrated visceral yolk sac uptake and transfer of the radiolabel to the embryo proper. In addition, microinjection of heparin directly into the amniotic cavity of early head-fold embryo explants resulted in cranial neural tube defects similar to those caused by the addition of heparin to culture medium. These data indicate that heparin causes closure defects of cranial neurulation, primarily by an effect at the tissue level of the embryo proper.

Changes in cell adhesion and extracellular matrix molecules in spontaneous spinal neural tube defects in avian embryos

Quail embryos (embryonic days 2-2.5) with spontaneous neural tube defects (NTDs), along with age-matched normal embryos, were examined immunocytochemically for the extracellular matrix (ECM) molecules laminin, fibronectin, and chondroitin sulfate proteoglycan, the cell adhesion molecules (CAMs) E- and N-cadherin and neural CAM (NCAM), and the neural crest marker HNK-1. The embryos with NTDs were at the lower limit of the normal stage range and the affected region was about 25% shorter than in normal embryos. Open NTDs occurred in cervical and upper thoracic level, although often the ventral neural tube was morphologically normal. Widened, irregular but closed neural tubes (lower thoracic to sacral levels) showed disorganized mesenchyme-like cells centrally and often multiple lumens. Finger-like tabs projecting from the ectoderm over the neural tube also occurred at lower thoracic to sacral levels. In open NTDs, the E-cadherin-labeled epidermis was incomplete dorsally, and was continuous with the N-cadherin-labeled neural tissue, with a sharp demarcation between E- and N-cadherin-expressing regions, as in the early stages of normal primary neurulation. A sharp inverted peak of epidermis extended ventrally, closely applied to the side of the neural tissue. The intervening matrix labeled less intensely for chondroitin sulfate proteoglycan relative to laminin and fibronectin, in comparison to control embryos. In closed NTDs, the dorsal superficial cell layer (i.e., positionally epidermis) was not separated from the underlying neural tissue by a band of matrix as in control embryos. In addition, this layer expressed E-cadherin (as in normal embryos), but coexpressed N-cadherin and NCAM, which are not normally found here at this stage. This overlap region resembled the mid-dorsal tissue at earlier stages in normal secondary neurulation in the tail-bud. The tabs of tissue appeared to be localized hypertrophy of the epidermal and neural ectoderm, and also showed codistribution of E- and N-cadherin. In all these defects, matrix molecules occurred within (rather than around) the neural and epidermal epithelia. HNK-1-labeled neural crest cells were frequently absent in regions of NTDs, in contrast to control embryos. These results show that matrix and cell adhesion molecules are disturbed in spontaneous NTDs at the time of neurulation, and therefore could be involved in the generation of the defects by altering cell adhesion-dependent morphogenetic events.

Evaluation of neural fold fusion and coincident initiation of spinal cord occlusion in the chick embryo

Although it is known that rapid expansion of the vertebrate brain begins near the time that the spinal neurocoel is occluded, it still remains unknown when occlusion occurs in relation to neurulation. Since both morphogenetic events are critical for normal brain growth, it is important to decipher the temporal relationship between the two processes. This study assessed the temporal relationship of the two events with the rationale that if it could be demonstrated that occlusion occurs coincident with the completion of neurulation, then it could be argued that factors shown to direct neurulation could also initiate occlusion. Nearly 600 chick embryos (stages 9- through 12+) were cultured atop egg-agar, the caudal extent of neurulation determined, the cranial five pairs of somites removed and the neurocoels assessed for occlusion. In stage 9- through 10- chicks, neurulation of the spinal cord is incomplete. Stages 10 through 12+ exhibit neurulation and occlusion from the 8th to 19th somites. When lateral tissues were removed in embryos 8 through 10-, the neural folds became dysraphic whereas in embryos stage 10 and older, the folds remained fused dorsomedially and occluded. The only surgical manipulation that was found to prevent occlusion was elimination of the lateral tissues responsible for elevation and closure of the neural folds. Analysis of particular components of the lateral tissues essential for convergence, by treating embryos (n = 75) with chemicals known to degrade tissue-tissue bonds or specific components of the perineural matrix, indicated that more than 75% of the embryos treated with EDTA, EDTA plus Ca2+, trypsin, collagenase, or hyaluronidase exhibited little or no effect on convergence, dorsomedial fusion, and concomitant occlusion.

In vitro development of rat embryos undergoing organogenesis in heparin-plasma

This study examines the use of heparin-plasma as a culture medium for mammalian postimplantation whole-embryo culture. The growth and differentiation of head-fold rat embryo explants over 48 hours in a standard serum medium was compared with development of same stage explants over 48 hours in a plasma medium prepared using sodium heparin. Heparin disrupted the morphological differentiation of embryos, in a concentration-dependent manner, from 25 micrograms sodium heparin/ml media (i.e., 5 IU/ml media), with overall embryo growth being adversely affected from a concentration of 200 micrograms sodium heparin/ml media (i.e., 40 IU/ml media). Defects of cranial neural tube development were the first apparent structural anomalies resulting from culture in heparin media. Forebrain development was grossly abnormal and associated with failure of eye development. As the heparin concentration in media increased, the cephalic neural folds remained widely open and the edges became increasingly everted, although differentiation of the heart, otic primordia, and pharyngeal arch persisted. Similar concentration-dependent dysmorphogenic effects were seen when embryos were cultured in the standard serum media with added heparin. A minimum heparin concentration of 100 micrograms sodium heparin/ml media (i.e., 20 IU/ml media) was required to effectively inhibit coagulation of the plasma medium over the 48 hour culture period. Although embryonic growth was not adversely affected at this heparin concentration, morphological differentiation was severely disrupted. Therefore, heparin is not a suitable anticoagulant for the preparation of plasma for use in postimplantation whole-embryo culture.

Immunohistochemical localization of chondroitin and heparan sulfate proteoglycans in pre-spina bifida splotch mouse embryos

The splotch (Sp) mutation on mouse chromosome I is a genetic model for the neural tube defects spina bifida and exencephaly. Embryos carrying Sp or its allele splotch-delayed (Spd), have been shown to have delays in neural tube closure, and neural crest cell emigration, as well as a reduction in extracellular space around the neural tube. Pre-spina bifida Sp and Spd embryos have abnormalities of notochord, mesoderm and neuroepithelial development. Chondroitin sulphate proteoglycans (CSPG) and heparan sulfate proteoglycans (HSPG) have been shown to play essential roles during neural tube closure and neural crest cell emigration and migration and thus might well be affected by the splotch mutation. Therefore, the effects of Sp and Spd on the temporal and spatial distributions of CSPG and HSPG were studied in pre-spina bifida embryos cytogenetically identified as Sp/Sp (Spd/Spd), Sp/ + (Spd/ +) or +/+. Immunohistochemical localization of CSPG by means of the CS-56 monoclonal antibody showed that in Sp/Sp head sections, the neuroepithelial basement membranes stained more intensely at 5-, 10-, and 15-somite stages, whereas similar staining was observed at 16- and 19-somite stages compared with matched +/+ sections. In caudal sections Sp/Sp again showed a more intense stain for CSPG in the neuroepithelial basement membranes in all sections (except one comparison, in which staining was similar) from embryos of 14-, 15-, 16-, and 19-somite stages, compared to matched +/+ sections. Heterozygotes did not differ consistently from the mutant or the normal (+/+) embryos in CS-56 stain intensity.(ABSTRACT TRUNCATED AT 250 WORDS)

Alcian blue staining of glycosaminoglycans in embryonic material: effect of different fixatives

Glycosaminoglycans are important components of the extracellular matrix of developing embryos where they are found in the form of proteoglycans. Alcian Blue staining of tissue sections is the technique most commonly used for demonstrating their distribution. Glycosaminoglycans have a high solubility in water, and are easily lost from the tissue during processing, even if non-aqueous fixatives have been used. Formalin and Carnoy's fluid are the most frequently used fixatives, and the addition of cetyl pyridinium chloride has been recommended to reduce glycan solubility. Using sections of day-10 rat embryos containing developing head and heart (both known to be rich in glycosaminoglycans) the effects of ten fixatives have been investigated with and without cetyl pyridinium chloride on the preservation of Alcian Blue-stainable material (at pH 2.5) and tissue structure. The most useful fixatives were Karnovsky's and Sainte-Marie's. Both gave a strong and reproducible staining pattern of the extracellular polyanionic material. Sainte-Marie's gave better preservation of tissue structure, allowing the demonstration of cell-matrix interrelationships; Karnovsky's gave a better contrast between extracellular and intracellular staining, which is particularly useful at lower magnifications. Cetyl pyridinium chloride is a detergent. Transmission electron microscope observations showed that it causes cell membrane disruption and vesicle formation, which at the light microscopic level, would cause cell membrane-associated glycosaminoglycans to appear as stained strands wholly within the extracellular domain. Therefore the use of cetyl pyridinium chloride is inadvisable where a distinction between surface-related and extracellular glycosaminoglycans is desirable. It has the further disadvantage of enhancing cytoplasmic and nuclear polyanionic material, thus decreasing the differential staining intensity of intracellular and extracellular domains.