Differential deposition of basement membrane components during formation of the caudal neural tube in the mouse embryo

The distribution of basement membrane and extracellular matrix components laminin, fibronectin, type IV collagen and heparan sulphate proteoglycan was examined during posterior neuropore closure and secondary neurulation in the mouse embryo. During posterior neuropore closure, these components were densely deposited in basement membranes of neuroepithelium, blood vessels, gut and notochord; although deposition was sparse in the midline of the regressing primitive streak. During secondary neurulation, mesenchymal cells formed an initial aggregate near the dorsal surface, which canalized and merged with the anterior neuroepithelium. With aggregation, fibronectin and heparan sulphate proteoglycan were first detected at the base of a 3- to 4-layer zone of radially organized cells. With formation of a lumen within the aggregate, laminin and type IV collagen were also deposited in the forming basement membrane. During both posterior neuropore closure and secondary neurulation, fibronectin and heparan sulphate proteoglycan were associated with the most caudal portion of the neuroepithelium, the region where newly formed epithelium merges with the consolidated neuroepithelium. In regions of neural crest migration, the deposition of basement membrane components was altered, lacking laminin and type IV collagen, with increased deposition of fibronectin and heparan sulphate proteoglycan.     

A cell-type-specific abnormality of cell proliferation in mutant (curly tail) mouse embryos developing spinal neural tube defects

The mouse mutant curly tail (ct) provides a model system for studies of neurulation mechanisms. 60% of ct/ct embryos develop spinal neural tube defects (NTD) as a result of delayed neurulation at the posterior neuropore whereas the remaining 40% of embryos develop normally. In order to investigate the role of cell proliferation during mouse neurulation, cell cycle parameters were studied in curly tail embryos developing spinal NTD and in their normally developing litter-mates. Measurements were made of mitotic index, median length of S-phase and percent reduction of labelling index during a [3H]thymidine pulse-chase experiment. These independent measures of cell proliferation rate indicate a reduced rate of proliferation of gut endoderm and notochord cells in the neuropore region of embryos developing spinal NTD compared with normally developing controls. The incidence of cell death and the relative frequency of mitotic spindle orientations does not differ consistently between normal and abnormal embryos. These results suggest a mechanism of spinal NTD pathogenesis in curly tail embryos based on failure of normal cell proliferation in gut endoderm and notochord.     

Accumulation of basement membrane-associated hyaluronate is reduced in the posterior neuropore region of mutant (curly tail) mouse embryos developing spinal neural tube defects

We investigated the accumulation of newly synthesized glycoconjugates during spinal neurulation in mutant curly tail mouse embryos, a proportion of which develop lower spinal neural-tube defects (NTD). Embryos undergoing closure of the posterior neuropore (27- to 29-somite stage) were labeled in vitro with [3H]glucosamine, and [3H]glycoconjugates were analyzed by ion-exchange chromatography. Mutant embryos undergoing normal spinal neurulation exhibited a pattern of glycoconjugate accumulation closely similar to that observed for nonmutant embryos (Copp and Bernfield, 1988, Dev. Biol. 130, 573-582). Mutant embryos developing spinal NTD accumulated reduced amounts of [3H]hyaluronate specifically in the posterior neuropore region. Other embryonic regions and other glycoconjugates appeared unaffected by the developmental abnormality. Autoradiographic analysis of labeled curly tail embryos confirmed that [3H]hyaluronate accumulates in reduced amounts in the posterior neuropore region and indicated that this reduction is mainly localized to the site of developing basement membranes, beneath the neuroepithelium and around the notochord. Accumulation of [3H]hyaluronate in the interstitial mesenchymal matrix of the posterior neuropore region is not consistently affected in embryos developing spinal NTD. These results provide support for a role for basement-membrane hyaluronate in lower spinal neurulation.     

Glycosaminoglycans vary in accumulation along the neuraxis during spinal neurulation in the mouse embryo

We have utilized the method of whole embryo culture for metabolic labeling of mouse embryos with [3H]glucosamine during closure of neural folds at the posterior neuropore (27- to 29-somite stage). Accumulations of newly synthesized glycopeptides, lactosaminoglycans, hyaluronate, and sulfated glycosaminoglycans (GAG) were assessed by ion-exchange chromatography of glycoconjugates isolated from labeled embryos. Accumulation of hyaluronate and sulfated GAG was greatest in the posterior neuropore and decreased progressively toward the hindbrain where neurulation was already complete. Hyaluronate comprised a progressively smaller proportion of total newly synthesized glycoconjugate from the posterior neuropore toward the cranial region and glycopeptides showed the opposite trend. Sulfated GAG and lactosaminoglycans showed no consistent differences in relative abundance along the neuraxis. Autoradiographic analysis of newly synthesized glycoconjugates revealed especially heavy incorporation into developing basement membranes, beneath the neuroepithelium and around the notochord, in the posterior neuropore and recently closed neural tube regions, but not at more cranial levels of the neuraxis. Predigestion of sections with a specific hyaluronidase showed a significant quantity of this glycoconjugate to be hyaluronate. These results are consistent with a role for neuroepithelial and notochordal basement membrane hyaluronate in spinal neurulation.     

Prevention of spinal neural tube defects in the mouse embryo by growth retardation during neurulation

Homozygous mutant curly tail mouse embryos developing spinal neural tube defects (NTD) exhibit a cell-type-specific abnormality of cell proliferation that affects the gut endoderm and notochord but not the neuroepithelium. We suggested that spinal NTD in these embryos may result from the imbalance of cell proliferation rates between affected and unaffected cell types. In order to test this hypothesis, curly tail embryos were subjected to influences that retard growth in vivo and in vitro. The expectation was that growth of unaffected rapidly growing cell types would be reduced to a greater extent than affected slowly growing cell types, thus counteracting the genetically determined imbalance of cell proliferation rates and leading to normalization of spinal neurulation. Food deprivation of pregnant females for 48 h prior to the stage of posterior neuropore closure reduced the overall incidence of spinal NTD and almost completely prevented open spina bifida, the most severe form of spinal NTD in curly tail mice. Analysis of embryos earlier in gestation showed that growth retardation acts by reducing the incidence of delayed neuropore closure. Culture of embryos at 40.5 degrees C for 15-23 h from day 10 of gestation, like food deprivation in vivo, also produced growth retardation and led to normalization of posterior neuropore closure. Labelling of embryos in vitro with [3H]thymidine for 1 h at the end of the culture period showed that the labelling index is reduced to a greater extent in the neuroepithelium than in other cell types in growth-retarded embryos compared with controls cultured at 38 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sonic hedgehog and the molecular regulation of mouse neural tube closure

Neural tube closure is a fundamental embryonic event whose molecular regulation is poorly understood. As mouse neurulation progresses along the spinal axis, there is a shift from midline neural plate bending to dorsolateral bending. Here, we show that midline bending is not essential for spinal closure since, in its absence, the neural tube can close by a 'default' mechanism involving dorsolateral bending, even at upper spinal levels. Midline and dorsolateral bending are regulated by mutually antagonistic signals from the notochord and surface ectoderm. Notochordal signaling induces midline bending and simultaneously inhibits dorsolateral bending. Sonic hedgehog is both necessary and sufficient to inhibit dorsolateral bending, but is neither necessary nor sufficient to induce midline bending, which seems likely to be regulated by another notochordal factor. Attachment of surface ectoderm cells to the neural plate is required for dorsolateral bending, which ensures neural tube closure in the absence of sonic hedgehog signaling.     

Curvature of the caudal region is responsible for failure of neural tube closure in the curly tail (ct) mouse embryo.

Delayed closure of the posterior neuropore (PNP) occurs to a variable extent in homozygous mutant curly tail (ct) mouse embryos, and results in the development of spinal neural tube defects (NTD) in 60% of embryos. Previous studies have suggested that curvature of the body axis may delay neural tube closure in the cranial region of the mouse embryo. In order to investigate the relationship between curvature and delayed PNP closure, we measured the extent of ventral curvature of the neuropore region in ct/ct embryos with normal or delayed PNP closure. The results show significantly greater curvature in ct/ct embryos with delayed PNP closure in vivo than in their normal littermates. Reopening of the posterior neuropore in non-mutant mouse embryos, to delay neuropore closure experimentally, did not increase ventral curvature, suggesting that increased curvature in ct/ct embryos is not likely to be a secondary effect of delayed PNP closure. Experimental prevention of ventral curvature in ct/ct embryos, brought about by implantation of an eyelash tip longitudinally into the hindgut lumen, ameliorated the delay in PNP closure. We propose, therefore, that increased ventral curvature of the neuropore region of ct/ct embryos imposes a mechanical stress, which opposes neurulation and thus delays closure of the PNP. Increased ventral curvature may arise as a result of a cell proliferation imbalance, which we demonstrated previously in affected ct/ct embryos.     

Cerebellar proteoglycans regulate sonic hedgehog responses during development

Sonic hedgehog promotes proliferation of developing cerebellar granule cells. As sonic hedgehog is expressed in the cerebellum throughout life it is not clear why proliferation occurs only in the early postnatal period and only in the external granule cell layer. We asked whether heparan sulfate proteoglycans might regulate sonic hedgehog-induced proliferation and thereby contribute to the specialized proliferative environment of the external granule cell layer. We identified a conserved sequence within sonic hedgehog that is essential for binding to heparan sulfate proteoglycans, but not for binding to the receptor patched. Sonic hedgehog interactions with heparan sulfate proteoglycans promote maximal proliferation of postnatal day 6 granule cells. By contrast, proliferation of less mature granule cells is not affected by sonic hedgehog-proteoglycan interactions. The importance of proteoglycans for proliferation increases during development in parallel with increasing expression of the glycosyltransferase genes, exostosin 1 and exostosin 2. These data suggest that heparan sulfate proteoglycans, synthesized by exostosins, may be critical determinants of granule cell proliferation.     

Discontinuity of primary and secondary neural tube in spina bifida induced by retinoic acid in mice

This report shows by light microscopy the appearance of secondary neurulation separated from primary neurulation and its developmental fate in the spinal cord of mice exposed to retinoic acid in utero. The embryos and fetuses were derived from pregnant mice (ICR strain) given 60, 40, or 0 mg/kg of retinoic acid in olive oil on day 8 of gestation orally and killed 1, 2, or 10 days later. Separation of the primary neural fold from the secondary neural tube was seen in 9- and 10-day-old embryos: the caudal part of the neuroepithelium of the primary neural fold was disarranged with non-closed posterior neuropore, and underneath it the secondary neural tissue extended caudally with abnormal notochord. At term, fetuses showed spina bifida, including myeloschisis, myelocele, and diplomyelia (diastematomyelia) with abnormal distribution of ganglionic cells. These cord lesions were located between the third lumbar and second coccygeal levels. The former two cord anomalies were associated with diplomyelia and split the dorsal and ventral portions of the spinal cord with an overlapping zone between the third lumbar and third sacral levels. These findings suggest that the separation from primary neurulation is due to the lesions in both primary neural folds and notochord induced by retinoic acid and that the spinal cord caudal to the third lumbar level originates from both neuroectoderm and mesenchyme-like cells while that caudal to the third sacral level originates from mesenchyme-like cells only.     

Binding of heparan sulphate and heparin to control and virus-transformed cells

A cloned embryonic mouse cell line contained specific cell-surface receptors for heparin and both the number and affinity appeared to be unchanged in a simian-virus-40-transformed subclone. In competitive binding assays heparan sulphate from the control clone was bound preferentially compared to that from the transformed subclone, indicating that the altered sulphation of heparan sulphate from transformed cells results in a lowered affinity for cell-surface receptors. Evidence was obtained suggesting that endogenous proteoglycans were not held at the cell surface by binding to these receptors alone. However the possibility that proteoglycans embedded in the plasma membrane may interact with the receptor has not been ruled out.     

Notch activates sonic hedgehog and both are involved in the specification of dorsal midline cell-fates in Xenopus

We analysed the role of Notch signalling during the specification of the dorsal midline in Xenopus embryos. By activating or blocking the pathway we found that Notch expands the floor plate domain of sonic hedgehog and pintallavis and represses the notochordal markers chordin and brachyury, with a concomitant reduction of the notochord size. We propose that within a population of the early organiser with equivalent potential to develop either as notochord or floor plate, Notch activation favours floor plate development at the expense of the notochord, preferentially before mid gastrula. We present evidence that sonic hedgehog down-regulates chordin, suggesting that secreted Sonic hedgehog may be involved or reinforcing the cell-fate switch executed by Notch. We also show that Notch signalling requires Presenilin to modulate this switch.     

Axial progenitors with extensive potency are localised to the mouse chordoneural hinge

Elongation of the mouse anteroposterior axis depends on a small population of progenitors initially located in the primitive streak and later in the tail bud. Gene expression and lineage tracing have shown that there are many features common to these progenitor tissues throughout axial elongation. However, the identity and location of the progenitors is unclear. We show by lineage tracing that the descendants of 8.5 d.p.c. node and anterior primitive streak which remain in the tail bud are located in distinct territories: (1) ventral node descendants are located in the widened posterior end of the notochord; and (2) descendants of anterior streak are located in both the tail bud mesoderm, and in the posterior end of the neurectoderm. We show that cells from the posterior neurectoderm are fated to give rise to mesoderm even after posterior neuropore closure. The posterior end of the notochord, together with the ventral neurectoderm above it, is thus topologically equivalent to the chordoneural hinge region defined in Xenopus and chick. A stem cell model has been proposed for progenitors of two of the axial tissues, the myotome and spinal cord. Because it was possible that labelled cells in the tail bud represented stem cells, tail bud mesoderm and chordoneural hinge were grafted to 8.5 d.p.c. primitive streak to compare their developmental potency. This revealed that cells from the bulk of the tail bud mesoderm are disadvantaged in such heterochronic grafts from incorporating into the axis and even when they do so, they tend to contribute to short stretches of somites suggesting that tail bud mesoderm is restricted in potency. By contrast, cells from the chordoneural hinge of up to 12.5 d.p.c. embryos contribute efficiently to regions of the axis formed after grafting to 8.5 d.p.c. embryos, and also repopulate the tail bud. These cells were additionally capable of serial passage through three successive generations of embryos in culture without apparent loss of potency. This potential for self-renewal in chordoneural hinge cells strongly suggests that stem cells are located in this region.     

Inactivation of unbound rat liver glucocorticoid receptor by N-alkylmaleimides at sub-zero temperatures

Biosynthetically radiolabelled heparan sulphate proteoglycans have been isolated from the growth medium and the cell lysate of a human neuroblastoma cell line (CHP100). Chromatography on Sepharose CL-4B identified two heparan sulphate proteoglycans in the medium (Kav 0.220 and 0.389), whereas in the cell lysate the major proteoglycan species were more heterogenous and of a smaller overall molecular size (Kav 0.407) than the medium-derived counterparts. Chromatography on Sepharose CL-6B of free heparan sulphate glycosaminoglycan chains showed that the majority of cell-layer-derived material heparan sulphate 2, Kav = 0.509) was smaller than medium heparan sulphates (heparan sulphate 1 and heparan sulphate 2, Kav 0.230 and 0.317). Analysis of the patterns of polymer sulphation by nitrous acid treatment, gel chromatography and high-voltage electrophoresis established that in each heparan sulphate fraction there was on average 1.1 sulphate residues per disaccharide with an N:O sulphate ratio of 1.1. Heparan sulphate in the medium had a high proportion of di-O-sulphated disaccharides in regions of the chain with repeat disaccharide sequences of structure GlcA-GlcNSO3, whereas cell-associated material was enriched in di-O-sulphated tetrasaccharides of alternating sequences GlcA-GlcNAc-GlcA-GlcNSO3. The identification of several populations of heparan sulphate proteoglycans differing in molecular size and glycosaminoglycan fine structure may reflect the functional diversity of this family of macromolecules in the nervous system.     

Conserved charge of glomerular and mesangial cell proteoglycans: possible role of amino acid-derived sulphate.

Sulphation of proteoglycans was studied in isolated glomeruli and cultured rat mesangial cells. Both preparations produced heparan, dermatan, and chondroitin sulphates, recoverable both from the tissue layers and the conditioned media. The proportion of heparan sulphate made by mesangial cells was independent of the age of the culture, but declined in later passage. These preparations differed from several other nontransformed cell types studied to date in that the degree of proteoglycan sulphation was independent of the concentration of inorganic sulphate provided. Even when no exogenous sulphate was added, sulphation-dependent charge density of newly synthesized proteoglycans was conserved. Both isolated glomeruli and cultured mesangial cells produced proteoglycans with 35S-labelled sulphate esters when [35S]methionine was provided as the sole source of labelled sulphate. Conversion of methionine to cysteine and subsequent oxidation of organic sulphate via the sulphinyl pyruvate pathway is the only mechanism known in eukaryotic cells that can account for this observation. We conclude that facile oxidation of sulphur-containing amino acids can contribute to sulphation of glomerular proteoglycans and may serve to sustain the charge density of these multifunctional molecules when the supply of inorganic sulphate is otherwise compromised.     

The genetic basis of mammalian neurulation

More than 80 mutant mouse genes disrupt neurulation and allow an in-depth analysis of the underlying developmental mechanisms. Although many of the genetic mutants have been studied in only rudimentary detail, several molecular pathways can already be identified as crucial for normal neurulation. These include the planar cell-polarity pathway, which is required for the initiation of neural tube closure, and the sonic hedgehog signalling pathway that regulates neural plate bending. Mutant mice also offer an opportunity to unravel the mechanisms by which folic acid prevents neural tube defects, and to develop new therapies for folate-resistant defects.     

Abnormalities of neural tube formation in pre-spina bifida splotch-delayed mouse embryos

The splotch-delayed homozygous mutant (Spd/Spd) develops spina bifida with or without exencephaly, has spinal ganglia abnormalities, and delays in posterior neuropore closure and neural crest cell emigration. The heterozygote (Spd/+) has a pigmentation defect, and occasionally neural tube defects. To investigate the underlying mechanisms, we compared the neuroepithelium in the posterior neuropore region of cytogenetically identified 15-18 somite pair Spd/Spd, Spd/+, and +/+ mouse embryos by transmission electron and light microscopy. The notochordal area and cell number in the non-fused neuroepithelium region of Spd/Spd and Spd/+ embryos were significantly reduced compared to those of normal (+/+) embryos, which suggests an abnormality in notochord elongation. In the mesoderm, the mean cell number and mean ratio of cell number to area in the non-fused region were significantly lower in the Spd/Spd compared with +/+ embryos. The distance of exposed neuroepithelium above the mesoderm in the just-fused region was significantly lower in the Spd/Spd versus +/+ embryos, which may indicate an insufficient force exerted by the mesoderm during neural tube closure. Within the neuroepithelium, significantly more intercellular space was found in Spd/Spd than in +/+ embryos indicating disorganization. The basal lamina was poorly organized and the formation delayed around the neural tube in Spd/Spd and Spd/+ embryos. All together, these results suggest an early abnormality in interactions among the neuroepithelium, mesoderm, and notochord, which may lead to the delay or inhibition of neural tube closure observed in Spd/Spd mutants.     

Neural plate morphogenesis during mouse neurulation is regulated by antagonism of Bmp signalling

Dorsolateral bending of the neural plate, an undifferentiated pseudostratified epithelium, is essential for neural tube closure in the mouse spinal region. If dorsolateral bending fails, spina bifida results. In the present study, we investigated the molecular signals that regulate the formation of dorsolateral hinge points (DLHPs). We show that Bmp2 expression correlates with upper spinal neurulation (in which DLHPs are absent); that Bmp2-null embryos exhibit premature, exaggerated DLHPs; and that the local release of Bmp2 inhibits neural fold bending. Therefore, Bmp signalling is necessary and sufficient to inhibit DLHPs. By contrast, the Bmp antagonist noggin is expressed dorsally in neural folds containing DLHPs, noggin-null embryos show markedly reduced dorsolateral bending and local release of noggin stimulates bending. Hence, Bmp antagonism is both necessary and sufficient to induce dorsolateral bending. The local release of Shh suppresses dorsal noggin expression, explaining the absence of DLHPs at high spinal levels, where notochordal expression of Shh is strong. DLHPs ;break through' at low spinal levels, where Shh expression is weaker. Zic2 mutant embryos fail to express Bmp antagonists dorsally and lack DLHPs, developing severe spina bifida. Our findings reveal a molecular mechanism based on antagonism of Bmp signalling that underlies the regulation of DLHP formation during mouse spinal neural tube closure.     

Expression of Panza, an alpha2-macroglobulin, in a restricted dorsal domain of the primitive gut in Xenopus laevis

Alpha2-macroglobulin is a major serum protein with diverse functions, including inhibition of protease activity and binding of growth factors, cytokines, and disease factors. We have cloned and characterized Panza, a new Xenopus laevis alpha2-macroglobulin. Panza has 56-60% amino acid similarity with previously identified Xenopus, mouse, rat and human alpha2-macroglobulins, indicating that Panza is a new member of the alpha2-macroglobulin family. Panza mRNA is first detected at the beginning of neurulation in the dorsal endoderm lining the primitive gut (archenteron roof). At the completion of neurulation and continuing through the late tadpole stage, Panza is restricted to a dorsal domain of the gut endoderm adjacent to the notochord and extending along the entire anterior-posterior axis. With outgrowth of the tailbud, Panza expression persists in the chordaneural hinge at the posterior end of the differentiating notochord and extends into the floor plate of the posterior neural tube. As gut coiling commences, Panza expression is initiated in the liver, and the dorsal domain of Panza expression becomes limited to the midgut and hindgut. With further gut coiling, strong Panza expression persists in the liver, but is lost from other regions of the gut. The expression of Panza in endodermal cells adjacent to the notochord points to a potential role for Panza in signal modulation and/or morphogenesis of the primitive gut.     

Heterogeneity of cell-associated and secretory heparan sulphate proteoglycans produced by cultured human neuroblastoma cells

Biosynthetically radiolabelled heparan sulphate proteoglycans have been isolated from the growth medium and the cell lysate of a human neuroblastoma cell line (CHP100). Chromatography on Sepharose CL-4B identified two heparan sulphate proteoglycans in the medium (K_av 0.220 and 0.3890, whereas in the cell lysate the major proteoglycan species were more heterogenous and of a smaller overall molecular size (K_av 0.407) than the medium-derived counterparts. Chromatography on Sepharose CL-6B of free heparan sulphate glycosaminoglycan chains showed that the majority of cell-layer-derived material heparan sulphate 2, K_av=0.509) was smaller than medium heparan sulphates (heparan sulphate 1 and heparan sulphate 2, K_av 0.230 and 0.317). Analysis of the patterns of polymer sulphation by nitrous acid treatment, gel chromatography and high-voltage electrophoresis established that in each heparan sulphate fraction there was on average 1.1 sulphate residues per disaccharide with an N:O sulphate ratio of 1.1 Heparan sulphate in the medium had a high proportion of di-O-sulphated disaccharides in regions of the chain with repeat disaccharide sequences of structure GlcA-GlcNSO₃, whereas cell-associated material was enriched in di-O-sulphated tetrasaccharides of alternating sequences GlcA-GlcNAc-GlcA-GlcNSO₃. The identification of several populations of heparan sulphate proteoglycans differing in molecular size and glycosaminoglycan fine structure may reflect the functional diversity of this family of macromolecules in the nervous system.     

In synergy with noggin and follistatin, Xenopus nodal-related gene induces sonic hedgehog on notochord and floor plate

In early development of vertebrates, sonic hedgehog functions in dorsal-ventral patterning of dorsal tissue (nervous system and somites). In Xenopus, sonic hedgehog (Xshh) is first expressed in the Spemann organizer/notochord and floor plate. We report here the mechanism governing Xshh mRNA induction in these regions. In animal cap assays, the antagonizing BMPs signal was not sufficient to induce Xshh mRNA expression; however, it could induce Xshh mRNA expression in the presence of Xnr-1. In whole embryos, when secondary axes were induced by coexpressing noggin and Xnr-1 or follistatin and Xnr-1, Xshh mRNA expression was observed in the notochord and floor plate within the induced axes. It seems apparent that spatially restricted Xshh mRNA expression is determined as intersection of the two signals.