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

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.

Characterization of invading glioma cells using molecular analysis of leading-edge tissue

OBJECTIVE

We have introduced a method of characterization of invading glioma cells by using molecular analysis of marginal invading tumor cells and molecular profiles of glioma tumor margin.

METHODS

Each of tumor core and marginal tissues was obtained in 22 glioma patients. Tumor core cells and marginal cells from each glial tumor were collected by laser capture microdissection or intraoperative microdissection under the operating microscope. Expression of MMP-2, MMP-9, CD44 and RHAMM mRNA by invading glioma cells compared with tumor core was confirmed by realtime-PCR of twenty-four glioma specimens. Clinical data also were reviewed for invasion and recurrence pattern of the gliomas radiologically and invasive rim pattern microscopically.

RESULTS

Overall results of the molecular analysis showed that relative overexpression of MMP-2, MMP-9 and RHAMM were noted at the invasive edge of human glioma specimens comparing to the tumor core but CD44 was highly expressed in the tumor core comparing to the margin. High marginal expression of MMP-2 and MMP-9 were noted in poorly ill-defined margin on the pathological finding. High marginal expression of CD44 and MMP-2 were demonstrated in the midline cross group on the radiological review, and that of RHAMM and MMP-2 were showed in the aggressive recurrence group. High expression of MMP-2 seems to be involved in the various invasion-related phenomenons.

CONCLUSION

Up-regulation of MMP-2, MMP-9, CD44 and RHAMM was noted in invasive edge of gliomas according to the various clinical situations.

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.

Hyaluronan: RHAMM mediated cell locomotion and signaling in tumorigenesis

Extracellular matrix molecules and their receptors are important regulators of cell movement, adhesion and cytoskeletal organization. Adhesion molecules can also serve to mediate signal transduction and can influence, and sometimes direct, the events required for tumorigenesis. The extracellular matrix molecule, hyaluronan and its receptors have been implicated in transformation and metastasis, in particular the processes of tumor cell motility and invasion. RHAMM (receptor for hyaluronan mediated motility) is required for the cell locomotion of ras-transformed fibrosarcoma cells, cytokine stimulated fibrobasts and T lymphocytes, malignant B cells, and breast carcinoma cells. HA:RHAMM interactions promote cell locomotion via a protein tyrosine kinase signal transduction pathway that targets focal adhesions. The tyrosine kinase pp60c-src is associated with RHAMM in cells and is required for RHAMM mediated cell motility. It is possible that a RHAMM/src pathway induces focal adhesions to signal the cytoskeletal changes required for elevated cell motility seen in tumor progression, invasion and metastasis.

Hyaluronan and the hyaluronan receptor RHAMM promote focal adhesion turnover and transient tyrosine kinase activity

The molecular mechanisms whereby hyaluronan (HA) stimulates cell motility was investigated in a C-H-ras transformed 10T 1/2 fibroblast cell line (C3). A significant (p < 0.001) stimulation of C3 cell motility with HA (10 ng/ml) was accompanied by an increase in protein tyrosine phosphorylation as detected by anti-phosphotyrosine antibodies using immunoblot analysis and immunofluorescence staining of cells. Tyrosine phosphorylation of several proteins was found to be both rapid and transient with phosphorylation occurring within 1 min of HA addition and dissipating below control levels 10-15 min later. These responses were also elicited by an antibody generated against a peptide sequence within the HA receptor RHAMM. Treatment of cells with tyrosine kinase inhibitors (genistein, 10 micrograms/ml or herbimycin A, 0.5 micrograms/ml) or microinjection of anti-phosphotyrosine antibodies inhibited the transient protein tyrosine phosphorylation in response to HA as well as prevented HA stimulation of cell motility. To determine a link between HA-stimulated tyrosine phosphorylation and the resulting cell locomotion, cytoskeletal reorganization was examined in C3 cells plated on fibronectin and treated with HA or anti-RHAMM antibody. These agents caused a rapid assembly and disassembly of focal adhesions as revealed by immunofluorescent localization of vinculin. The time course with which HA and antibody induced focal adhesion turnover exactly paralleled the induction of transient protein tyrosine phosphorylation. In addition, phosphotyrosine staining colocalized with vinculin within structures in the lamellapodia of these cells. Notably, the focal adhesion kinase, pp125FAK, was rapidly phosphorylated and dephosphorylated after HA stimulation. These results suggest that HA stimulates locomotion via a rapid and transient protein tyrosine kinase signaling event mediated by RHAMM. They also provide a possible molecular basis for focal adhesion turnover, a process that is critical for cell locomotion.

Hyaluronate degradation affects ventricular function of the early postlooped embryonic rat heart in situ

Hyaluronic acid is the major glycosaminoglycan of the early cardiac extracellular matrix or "cardiac jelly," yet little is known about its role in the ontogeny of early ventricular performance. To investigate the in situ effect of hyaluronate degradation on ventricular function, whole rat embryos were cultured in rat serum alone (control embryos) or rat serum plus 20 TRU/mL of Streptomyces hyaluronidase (treatment embryos) from gestational day 9.5 (before formation of the heart tube) through initial looping of the heart. Cardiac function was measured before looping (24 hours in culture) and immediately after looping (36 hours in culture) by video motion analysis of the external wall motion of the bulbus cordis and primitive ventricle. Degradation of hyaluronic acid in the treated embryos was confirmed by Alcian blue staining at pH 2.5. Significant increases in heart rate, circumferential shortening fraction, maximum velocity of circumferential contraction, and maximum velocity of circumferential relaxation were observed with looping in both control and treatment embryos. Although there was minimal difference in ventricular performance between control and treatment embryos before looping, there was a significant increase in all parameters of ventricular performance in the hyaluronidase-treated embryos immediately after looping of the heart. Endocardial cushions were absent in hyaluronidase-treated embryos, and an additional group of embryos cultured in the presence of Streptomyces hyaluronidase for 48 to 72 hours failed to develop endocardial cushions. These experiments are the first to (1) document a quantifiable increase in ventricular performance during early cardiac looping and (2) demonstrate that hyaluronate degradation results in abnormal endocardial cushion formation and altered ventricular performance of the postlooped heart.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of neural tube defects in a mouse mutant using whole embryo culture

The method of whole embryo culture permits a variety of experimental manipulations to be performed on the mammalian embryo. When used in conjunction with mouse mutants, this technique can provide information on the pathogenetic mechanisms underlying the development of birth defects. To illustrate this approach, we review in vitro studies on the development of embryos homozygous for the mutation curly tail (ct). These studies have involved making repeated observations on individual embryos, performing surgical manipulations, applying environmental influences and metabolic labelling. As a result of this work, we have now partially elucidated the developmental sequence of events that precedes the appearance of spina bifida in the ct mutant.

Restricted expression of the hyaluronan receptor, CD44, during postimplantation mouse embryogenesis suggests key roles in tissue formation and patterning

CD44 is a multifunctional adhesion protein that acts as a major receptor for the hygroscopic extracellular matrix component, hyaluronan. This receptor-ligand binding directly mediates at least some of the cell-cell and cell-matrix interactions ascribed to CD44. Other interactions involving CD44 may be modulated indirectly by its ability to bind growth factors and thereby to promote cell attachment. During vertebrate development, multiple cases of hyaluronan involvement in cell proliferation, cell migration and histogenesis have been documented. In addition, there is evidence suggesting a central role for cell surface glycoproteins and proteoglycans in mediating the action of polypeptide growth factors involved in tissue patterning. In view of this, we undertook to investigate expression of the CD44 protein during postimplantation mouse embryogenesis. Between 9.5 and 12.5 days of embryonic development, the predominant form of CD44 protein corresponds to the hyaluronan-binding CD44H form. However, species with a higher M(r) were also detected, implying that CD44 isoforms generated by alternative splicing of CD44 RNA are employed in normal development. Further, we used mouse embryos to perform whole-mount immunohistochemistry and examine the temporal and spatial distribution of this glycoprotein. CD44 is expressed at high levels in the heart, somites and condensing limb-bud mesenchyme at critical stages of morphogenesis. These sites correlate with regions where hyaluronan has been demonstrated to regulate morphogenetic events. Of novel interest, however, is the high expression of CD44 in regions that do not correlate with sites of known hyaluronan-mediated developmental events. These include instructive epithelia participating in epithelial-mesenchymal cell interactions such as the apical ectodermal ridge of the developing limb bud and the odontogenic placodes of the presumptive upper and lower jaws.

Identification of hyaluronan binding proteins using a biotinylated hyaluronan probe

A method for detecting hyaluronan (HA)-binding proteins in transblot assays using biotinylated HA (BHA) is described. Some of the binding characteristics of a novel HA receptor termed RHAMM (Receptor for HA-Mediated Motility) are characterized using this assay. The method is also used to detect other HA-binding proteins in tissue homogenates. This method is semiquantitative, rapid, reproducible, sensitive and therefore of potential use in identifying the levels of HA-binding proteins in different cells and tissues.

Exogenous transferrin is taken up and localized by the neurulation-stage mouse embryo in vitro

We have screened neurulation-stage mouse embryos for regional differences in protein distribution, by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The screen has revealed an 83-kD protein (pI 6.8) that is present in embryo regions where neurulation is in progress but not in regions where neurulation is complete. The 83-kD protein is not synthesized in the neurulation-stage embryo or in the yolk sac, but is taken up from the culture serum in vitro and, probably, from the maternal serum in utero. The 83-kD protein has been identified as transferrin on the basis of its electrophoretic migration and recognition on Western blots by an antitransferrin antibody. Culture of embryos in serum containing 125I-transferrin, followed by autoradiography of embryo sections, shows that transferrin is taken up and localized in the gut beneath the closing neural folds at several levels of the body axis in 8.5- and 9.5-day embryos. In situ hybridization studies show that the transferrin receptor mRNA is expressed in all cells of the 9.5-day embryo, including the gut endoderm. These findings are consistent with a role for transferrin in development of the gut and perhaps, indirectly, in completion of neurulation during early mouse embryogenesis.

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)

Computer modelling of neural tube defects

Neurulation, the curling of the neuroepithelium to form the neural tube, is an essential component of the development of animal embryos. Defects of neural tube formation, which occur with an overall frequency of one in 500 human births, are the cause of severe and distressing congenital abnormalities. However, despite the fact that there is increasing information from animal experiments about the mechanisms which effect neural tube formation, much less is known about the fundamental causes of neural tube defects (NTD). The use of computer models provides one way of gaining clues about the ways in which neurulation may be compromised. Here we employ one computer model to examine the robustness of different cellular mechanisms which are thought to contribute to neurulation. The model, modified from that of Odell et al (Odell, G.M., Oster, G., Alberch, P. and Burnside, B., (1981)) mimics neurulation by laterally propagating a wave of apical contraction along an active zone within a ring of cells. We link the results to experimental evidence gained from studies of embryos in which neurulation has been perturbed. The results indicate that alteration of one of the properties of non-neural tissue can delay or inhibit neurulation, supporting the idea, gained from observation of embryos bearing genes which predispose to NTD, that the tissue underlying the neuroepithelium may contribute to the elevation of the neural folds. The results also show that reduction of the contractile properties of a small proportion of the neuroepithelial cell population may have a profound effect on overall tissue profiling. The results suggest that the elevation of the neural folds, and hence successful neurulation, may be vulnerable to relatively minor deficiencies in cell properties.

Hyaluronan and a cell-associated hyaluronan binding protein regulate the locomotion of ras-transformed cells

Hyaluronan (HA) and one of its cell binding sites, fibroblast hyaluronan binding protein (HABP), is shown to contribute to the regulation of 10T1/2 cell locomotion that contain an EJ-ras-metallothionein (MT-1) hybrid gene. Promotion of the ras-hybrid gene with zinc sulfate acutely stimulates, by 6-10-fold, cell locomotion. After 10 h, locomotion drops to two- to threefold above that of uninduced cells. Several observations indicate increased locomotion is partly regulated by HA. These include the ability of a peptide that specifically binds HA (HABR) to reduce locomotion, the ability of HA (0.001-0.1 micrograms/ml), added at 10-30 h after induction to stimulate locomotion back to the original, acute rate, and the ability of an mAb specific to a 56-kD fibroblast HABP to block locomotion. Further, both HA and HABP products are regulated by induction of the ras gene. The effect of exogenous HA is blocked by HABR, is dose-dependent and specific in that chondroitin sulfate or heparan have no significant effect. Stimulatory activity is retained by purified HA and lost upon digestion with Streptomyces hyaluronidase indicating that the activity of HA resides in its glycosaminoglycan chain. Uninduced cells are not affected by HA, HABR, or mAb and production of HA or HABP is not altered during the experimental period. These results suggest that ras-transformation activates an HA/HABP locomotory mechanism that forms part of an autocrine motility mechanism. Reliance of induced cells on HA/HABP for locomotion is transient and specific to the induced state.

Characterization of glycosaminoglycans produced by primary astrocytes in vitro

Quantitative biosynthetic studies with cultures highly enriched for glial fibrillary acidic protein (GFAP+) cells of neonatal mammalian brain demonstrated production of four proteoglycans: hyaluronate (HA), heparan sulphate (HS), chondroitin sulphate (CS), and dermatan sulphate (DS). The glycosaminoglycans were present in cell conditioned medium and in the cellular compartment. There were qualitative differences in the subcellular disposition of the various proteoglycans. The ratio of HS to CS/DS in cell extracts was 1:1, while in medium this ratio was 1:6. All of the glycosaminoglycans were associated with core proteins that were integral to the cell membrane and associated with the cell surface by non-covalent interactions involving glycosaminoglycans. Less than 20% of the HS was non-covalently associated with the astrocyte cell surface reflecting in part the proportionately smaller amounts of this proteoglycan released to astrocyte conditioned medium. HS released to medium was undersulphated relative to that associated with cells. The astrocyte can contribute proteoglycans to the extracellular milieu and displays cell surface proteoglycans that have the potential to provide appropriate substrates for neuron adhesion, process extension, and other cell-cell interactions.

Expression of a new mutation (Axd) causing axial defects in mice correlates with maternal phenotype and age

A new autosomal mutation, Axd (axial defects), is described. Axd segregates in a simple Mendelian fashion, and it is dominant with incomplete penetrance and variable expressivity. The phenotype of Axd heterozygotes ranges from a variety of tail anomalies to visibly normal tails. Approximately 12% of neonates from curly-tail (CT) F1 (Axd/+) x F1 (Axd/+) matings exhibit open neural tube defects (NTD) in the lumbosacral region and 16% have curly tails. Mean litter sizes and resorption rates comparable to wild type indicate that homozygosity for Axd is not obligately lethal. Genetic background plays a major role in Axd expression. Strains such as BALB/cByJ allow the highest penetrance of the mutation in single dose (46%), whereas, in CF-1 mice Axd is recessive. The tail phenotype of heterozygous Axd/+ dams, in part reflective of their genetic background, correlates with the incidence of NTD in F2 offspring: CT mothers produce significantly more neonates with frank NTD than normal tail mothers. At the one embryonic period examined for this study (D13/D14 post-coitus), an 85% higher incidence of total axial defects is observed than among the F2 at birth. Unchanging litter size and the relative increase in phenotypically normal offspring by birth suggest that Axd acts by delaying posterior neural tube closure. One of the most significant findings in this study is that maternal age influences the survival of Axd embryos in utero. Axd/+ dams older than 8 months yield fewer mean implants, higher resorption rates, and fewer viable embryos with axial defects than do Axd/+ dams younger than 8 months. Axd is not allelic to nor linked to the Sp (splotch) gene which also affects neurulation.

Sulfated proteoglycans in astroglial barriers inhibit neurite outgrowth in vitro

In vivo studies of the roof plate of the spinal cord and midline optic tectum in rodent and the developing subplate in the telencephalon of the chick showed that two glycosaminoglycans, keratin sulfate and chondroitin sulfate, possibly in the proteoglycan form (KS-PG, CS-PG, or KS/CS-PG), were present at times when axons approach closely but do not invade these territories. To address the question of whether KS/CS-PG actively inhibits growth cone elongation and to determine which component(s) of the proteoglycan may be critical to this phenomenon, we used a technique employing nitrocellulose-coated petri dishes onto which stripes of various purified macromolecules were attached. Isolated E9 chick dorsal root ganglia were grown on lanes of KS/CS-PG in alteration with lanes of the growth-promoting molecule laminin (LN). Neurite outgrowth was abundant along stripes of LN. In contrast, upon encountering a stripe containing KS/CS-PG, neurites either stopped abruptly or turned and traveled along the KS/CS-PG stripe border. The effect was dependent upon the concentration of the proteoglycan with intermediate concentrations producing intermittent patterns of crossing. We mixed LN with the KS/CS-PG, where the LN was in concentrations which alone support outgrowth, and observed that the KS/CS-PG was still inhibitory when such a growth-promoting molecule was present. A 10-fold higher concentration of LN was able to overcome the inhibitory effect of the KS/CS-PG. These results suggest that the interaction of inhibitory and growth-promoting molecules can interact to produce a wide spectrum of neurite patterns ranging from complete inhibition to totally unimpeded outgrowth. Selective enzymatic removal of the KS or CS from the KS/CS-PG permitted various degrees of neurite outgrowth to occur across the previously inhibitory lanes, and digestion of both glycoaminoglycan moieties, leaving only the protein core of the molecule, resulted in a complete lack of inhibition. These assays demonstrated that KS/CS-PG is inhibitory to embryonic dorsal root ganglia neurites in vitro and that complete inhibition requires contributions from both KS and CS moieties.

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.