Glypican4 modulates lateral line collective cell migration non cell-autonomously.

Collective cell migration is an essential process during embryonic development and diseases such as cancer, and still much remains to be learned about how cell intrinsic and environmental cues are coordinated to guide cells to their targets. The migration-dependent development of the zebrafish sensory lateral line proves to be an excellent model to study how proteoglycans control collective cell migration in a vertebrate. Proteoglycans are extracellular matrix glycoproteins essential for the control of several signaling pathways including Wnt/ß-catenin, Fgf, BMP and Hh. In the lateral line primordium the modified sugar chains on proteoglycans are important regulators of cell polarity, ligand distribution and Fgf signaling. At least five proteoglycans show distinct expression patterns in the primordium; however, their individual functions have not been studied. Here, we describe the function of glypican4 during zebrafish lateral line development. glypican4 is expressed in neuromasts, interneuromast cells and muscle cells underlying the lateral line. knypekfr6/glypican4 mutants show severe primordium migration defects and the primordium often U-turns and migrates back toward the head. Our analysis shows that Glypican4 regulates the feedback loop between Wnt/ß-catenin/Fgf signaling in the primordium redundantly with other Heparan Sulfate Proteoglycans. In addition, the primordium migration defect is caused non-cell autonomously by the loss of cxcl12a-expressing muscle precursors along the myoseptum via downregulation of Hh. Our results show that glypican4 has distinct functions in primordium cells and cells in the environment and that both of these functions are essential for collective cell migration.

Defining progressive stages in the commitment process leading to embryonic lens formation.

The commitment of regions of the embryo to form particular tissues or organs is a central concept in development, but the mechanisms controlling this process remain elusive. The well-studied model of lens induction is ideal for dissecting key phases of the commitment process. We find in Xenopus tropicalis, at the time of specification of the lens, i.e., when presumptive lens ectoderm (PLE) can be isolated, cultured, and will differentiate into a lens that the PLE is not yet irreversibly committed, or determined, to form a lens. When transplanted into the posterior of a host embryo lens development is prevented at this stage, while ~ 3 h later, using the same assay, determination is complete. Interestingly, we find that specified lens ectoderm, when cultured, acquires the ability to become determined without further tissue interactions. Furthermore, we show that specified PLE has a different gene expression pattern than determined PLE, and that determined PLE can maintain expression of essential regulatory genes (e.g., foxe3, mafB) in an ectopic environment, while specified PLE cannot. These observations set the stage for a detailed mechanistic study of the genes and signals controlling tissue commitment.

Unique organization of the frontonasal ectodermal zone in birds and mammals.

The faces of birds and mammals exhibit remarkable morphologic diversity, but how variation arises is not well-understood. We have previously demonstrated that a region of facial ectoderm, which we named the frontonasal ectodermal zone (FEZ), regulates proximo-distal extension and dorso-ventral polarity of the upper jaw in birds. In this work, we examined the equivalent ectoderm in murine embryos and determined that the FEZ is conserved in mice. However, our results revealed that fundamental differences in the organization and constituents of the FEZ in mice and chicks may underlie the distinct growth characteristics that distinguish mammalian and avian embryos during the earliest stages of development. Finally, current models suggest that neural crest cells regulate size and shape of the upper jaw, and that signaling by Bone morphogenetic proteins (Bmps) within avian neural crest helps direct this process. Here we show that Bmp expression patterns in neural crest cells are regulated in part by signals from the FEZ. The results of our work reconcile how a conserved signaling center that patterns growth of developing face may generate morphologic diversity among different animals. Subtle changes in the organization of gene expression patterns in the FEZ could underlie morphologic variation observed among and within species, and at extremes, variation could produce disease phenotypes.

Modification of the zone of polarizing activity signal by trypsin.

Patterning of the developing vertebrate limb along the anterior-posterior axis is controlled by the zone of polarizing activity (ZPA) via the expression of Sonic hedgehog (Shh) and along the proximal-distal axis by the apical ectodermal ridge (AER) through the production of fibroblast growth factors (FGFs). ZPA grafting, as well as ectopic application of SHH to the anterior chick limb bud, demonstrate that digit patterning is largely influenced by these secreted factors. Although signal transduction pathways have been well characterized for SHH and for FGFs, little is known of how these signals are regulated extracellularly in the limb. The present study shows that alteration of the extracellular environment through trypsin treatment can have profound effects on digit patterning. These effects appear to be mediated by the induction of Shh in host tissues and by ectopic AER formation, implicating the extracellular matrix in regulating the signaling activities of key patterning genes in the limb.

Specification of the zebrafish nervous system by nonaxial signals.

The organizer of the amphibian gastrula provides the neurectoderm with both neuralizing and posteriorizing (transforming) signals. In zebrafish, transplantations show that a spatially distinct transformer signal emanates from tissues other than the organizer. Cells of the germring (nonaxial mesendoderm) posteriorized forebrain progenitors when grafted nearby, resulting in an ectopic hindbrain-like structure; in contrast, cells of the organizer (axial mesendoderm) caused no posterior transformation. Local application of basic fibroblast growth factor, a candidate transformer in Xenopus, caused malformation but not hindbrain transformation in the forebrain. Thus, the zebrafish gastrula may integrate spatially distinct signals from the organizer and the germring to pattern the neural axis.

Prion protein devoid of the octapeptide repeat region restores susceptibility to scrapie in PrP knockout mice.

Mice devoid of PrP are resistant to scrapie and fail to replicate the agent. Introduction of transgenes expressing PrP into such mice restores susceptibility to scrapie. We find that truncated PrP devoid of the five copper binding octarepeats still sustains scrapie infection; however, incubation times are longer and prion titers and protease-resistant PrP are about 30-fold lower than in wild-type mice. Surprisingly, brains of terminally ill animals show no histopathology typical for scrapie. However, in the spinal cord, infectivity, gliosis, and motor neuron loss are as in scrapie-infected wild-type controls. Thus, while the region comprising the octarepeats is not essential for mediating pathogenesis and prion replication, it modulates the extent of these events and of disease presentation.

Regionalised signalling within the extraembryonic ectoderm regulates anterior visceral endoderm positioning in the mouse embryo.

The development of the anterior-posterior (AP) axis in the mammalian embryo is controlled by interactions between embryonic and extraembryonic tissues. It is well established that one of these extraembryonic tissues, the anterior visceral endoderm (AVE), can repress posterior cell fate and that signalling from the other, the extraembryonic ectoderm (ExE), is required for posterior patterning. Here, we show that signals from the prospective posterior ExE repress AVE gene expression and affect the distribution of the AVE cells. Surgical ablation of the prospective posterior, but not the anterior, extraembryonic region at 5.5 days of development (E5.5) perturbs the characteristic distal-to-anterior distribution of AVE cells and leads to a dramatic expansion of the AVE domain. Time-lapse imaging studies show that this increase is due to the ectopic expression of an AVE marker, which results in a symmetrical positioning of the AVE. Surgical ablation of this same ExE region after the distal-to-anterior migration has already commenced, at E5.75, does not affect the localisation of the AVE, indicating that this effect takes place within a short time window. Conversely, transplanting the prospective posterior, but not the anterior, extraembryonic region onto isolated E5.5 embryonic explants drastically reduces the AVE domain. Further, transplantation experiments demonstrate that the signalling regulating AVE gene expression originates from the posterior ExE, rather than its surrounding VE. Together, our results show that signals emanating from the future posterior ExE within a temporal window both restrict the AVE domain and promote its specific positioning. This indicates for the first time that the ExE is already regionalised a day before the onset of gastrulation in order to correctly set the orientation of the AP axis of the mouse embryo. We propose a reciprocal function of the posterior ExE and the AVE in establishing a balance between the antagonistic activities of these two tissues, essential for AP patterning.

Improvement of peripheral nerve regeneration by a tissue-engineered nerve filled with ectomesenchymal stem cells.

Ectomesenchymal stem cells (EMSCs) originate from the cranial neural crest. They are a potential source of neuronal and Schwann cells (SCs) of the peripheral nervous system (PNS) during embryonic development. The third passage of EMSCs enzymatically isolated from the mandibular processes of Sprague-Dawley rats were cultured in forskolin and bovine pituitary extract for 6 days to generate functional Schwann cell phenotypes. Next, 10-mm defects in the sciatic nerves were bridged with an autograft, tissue-engineered nerve filled with differentiated cells in collagen, or a PLGA conduit alone in 18 rats, and the nerve defects of another four rats were left untreated. The regenerated nerves were evaluated by the sciatic functional index (SFI) monthly and by histological analysis 4 months after grafting. The recovery index of the sciatic nerve improved significantly in the autograft and tissue-engineered nerve groups, both of which were superior to the PLGA group. In animals transplanted with the EMSCs, there was greater regeneration than with conduit alone during the same period of implantation. These results show that when EMSCs are transplanted to a peripheral nerve defect they differentiate into supportive cells that contribute to the promotion of axonal regeneration.

Development of teratomas from the ectoderm of mouse egg cylinders.

We studied the developmental capacities of the primary ectoderm and endoderm of 6-day embryos of hybrids between strains 129/Sv-SIJ C P and A/He mice by grafting these germ layers into the testes of adult mice for 30 days. Grafts of embryonic ectoderm gave rise to teratocarcinomas composed of undifferentiated embryonal cells and derivatives of all three germ layers including respiratory and alimentary epithelium. Grafts of extraembryonic ectoderm gave rise to invasive trophoblastic giant cells. Grafts of endoderm did not develop.

Xmeis1, a protooncogene involved in specifying neural crest cell fate in Xenopus embryos.

Meis1 (Myeloid Ecotropic viral Integration Site 1) is a homeobox gene that was originally isolated as a common site of viral integration in myeloid tumors of the BXH-2 recombinant inbred mice strain. We previously isolated a Xenopus homolog of Meis1 (Xmeis1). Here we show that Xmeis1 may play a significant role in neural crest development. In developing Xenopus embryos, Xmeis1 displays a broad expression pattern, but strong expression is observed in tissue of neural cell fate, such as midbrain, hindbrain, the dorsal portion of the neural tube, and neural crest derived branchial arches. In animal cap explants, overexpression of Xmeis1b, an alternatively spliced form of Xmeis1, induces expression of neural crest marker genes in the absence of mesoderm. Moreover, Xmeis1b induces XGli-3 and XZic3, pre-pattern genes involved at the earliest stages of neural crest development, and like these two genes, can induce ectopic pigmented cell masses when overexpressed in developing embryos. Misexpression of Xmeis1b also induces ectopic expression of neural crest markers along the antero-posterior axis of the neural tube in developing Xenopus embryos. In contrast, Xmeis1a, another splice variant, is much less effective at inducing these effects. These data suggest that Xmeis1b is involved in neural crest cell fate specification during embryogenesis, and can functionally intersect with the Gli/Zic signal transduction pathway.

The acquisition of neural fate in the chick.

Neural development in the chick embryo is now understood in great detail on a cellular and a molecular level. It begins already before gastrulation, when a separation of neural and epidermal cell fates occurs under the control of FGF and BMP/Wnt signalling, respectively. This early specification becomes further refined around the tip of the primitive streak, until finally the anterior-posterior level of the neuroectoderm becomes established through progressive caudalization. In this review we focus on processes in the chick embryo and put classical and more recent molecular data into a coherent scenario.

Disrupting the establishment of polarizing activity by teratogen exposure.

Between days 9.5 and 10, the forelimb buds of developing murine embryos progress from stage 1 which are just beginning to express shh and whose posterior mesoderm has only weak polarizing activity to stage 2 limbs with a distinguishable shh expression domain and full polarizing activity. We find that exposure on day 9.5 to teratogens that induce the loss of posterior skeletal elements disrupts the polarizing activity of the stage 2 postaxial mesoderm and polarizing activity is not subsequently restored. The ontogeny of expression of the mesodermal markers shh, ptc, bmp2, and hoxd-12 and 13, as well as the ectodermal markers wnt7a, fgf4, fgf8, cx43, and p21 occurred normally in day 9.5 teratogen-exposed limb buds. At stage 3, the treated limb apical ectodermal ridge usually possessed no detectable abnormalities, but with continued outgrowth postaxial deficiencies became evident. Recombining control, stage matched limb bud ectoderm with treated mesoderm prior to ZPA grafting restored the duplicating activity of treated ZPA tissue. We conclude that in addition to shh an early ectoderm-dependent signal is required for the establishment of the mouse ZPA and that this factor is dependent on the posterior ectoderm.

Studies on the use of NE-4C embryonic neuroectodermal stem cells for targeting brain tumour.

Neural stem cells were suggested to migrate to and invade intracranial gliomas. In the presented studies, interactions of NE-4C embryonic neural stem cells were investigated with C6 and Gl261, LL and U87, glioblastoma cells or with primary astrocytes. Glioma-derived humoral factors did not influence the proliferation of stem cells. NE-4C-derived humoral factors did not alter the proliferation of Gl261 and U87 cells, but increased the mitotic activity of C6 cells and that of astrocytes. In chimera-aggregates, all types of glioma cells co-aggregated with astrocytes, but most of them segregated from stem cells. Complete intercalation of stem and tumour cells was detected only in chimera-aggregates of Gl261 glioma and NE-4C cells. If mixed suspensions of NE-4C and Gl261 cells were injected into the brain, stem cells survived and grew inside the tumour mass. NE-4C stem cells, however, did not migrate towards the tumour, if implanted near to Gl261 tumours established in the adult mouse forebrain. The observations indicate that not all types of stem cells could be used for targeting all sorts of brain tumours.

Lens induction in axolotls: comparison with inductive signaling mechanisms in Xenopus laevis.

Amphibian lens induction is an embryonic process whose broad outlines are conserved between anurans and urodeles; however, it has been argued that some aspects of this process differ significantly between even closely related species. Classical embryologists concluded that in some species direct contact between the optic vesicle and ectoderm was both necessary and sufficient to induce the ectoderm to form a lens, while in other species tissues other than the optic vesicle induce lens formation. Recent studies of lens induction in Xenopus have argued that lens induction may be more conserved evolutionarily than was previously thought and that the different conclusions reached in the classical literature may be due more to experimental methodology than to actual differences in the process of lens induction. We have tested this hypothesis by examining the timing of lens induction in the axolotl and the ability of various tissues to induce lenses in explant cultures. We find that, despite the evolutionary divergence between Xenopus and Ambystoma, the mechanism of lens specification is substantially similar in the two species. These results support the hypothesis that the mechanism of lens induction is evolutionarily conserved among amphibians.

The final determination of Xenopus ectoderm depends on intrinsic and external positional information.

Traditionally the whole animal cap (ventral plus dorsal ectoderm) of amphibian blastula and gastrula stages was considered as a homogeneous cell mass, because both the isolated dorsal and ventral ectoderm without induction differentiated into ciliated (atypical) epidermis. Recent results suggest a predisposition of the dorsal and ventral ectoderm. We used a special experimental approach, i.e. injection of activin as inducer into the blastocoel of intact Xenopus blastulae before the isolation of animal caps and fluorescein-dextran-amine (FDA) as a lineage tracer. In recombinants of FDA-labeled and unlabeled ectoderm we showed that the cells of the dorsal ectoderm mainly differentiate into neural tissue and notochord when they remain at their original dorsal position. In contrast, when small pieces of dorsal ectoderm are transplanted to the ventral part of animal caps, most of the descendants form epidermis. However, when small pieces of the ventral ectoderm are transplanted to the dorsal side, they significantly contribute to neural tissue and notochord. These results suggest that the prepattern in Xenopus animal caps of the late blastula and early gastrula stages is labile and reversible. Still more important is the fact that the fate of individual cells depends on the site of their localization within the animal cap. This means that cells in the dorsal most or ventral most part of the animal cap, respectively, will not randomly differentiate into all cell types, but predominantly into dorsal or ventral derivatives, respectively.

Morphological and quantitative evaluation of olfactory bulb development in Xenopus after olfactory placode transplantation.

We found previously that the number of olfactory axons is correlated with the number of mitral/tufted cells (output neurons of the olfactory bulb) during normal larval development. To examine the significance of this quantitative relationship, we evaluated the effects of transplanting an extra olfactory placode on the development of the larval olfactory bulb. We found that the transplanted tissue retained the normal, pseudostratified, columnar appearance and had the same cell types as normal olfactory epithelium, and the olfactory bulbs had the same laminar organization as control bulbs. With gross examination of the olfactory bulb, the side innervated by the transplant appeared slightly larger than the contralateral side in animals analyzed at a young larval stage (stage 50) and in 2 of the 9 animals examined at late larval stages (57/58). Tissue sections and area measurements, however, revealed that the volume of the olfactory bulbs in animals with a transplant was not significantly different from control values. Our quantitative analysis also showed that in stage-50 animals with a transplant, the total number of olfactory axons (in nerves from the transplanted and host olfactory organs) appeared to be greater than in control animals, but not to a statistically significant level. The number of mitral/tufted cells was not different from controls. In animals examined at stage 57/58, there was no difference from controls in either the total number of olfactory axons, total number of mitral/tufted cells, or convergence ratio of olfactory axons onto mitral/tufted cells. Thus, in the late-stage larvae, the quantitative relationship between olfactory axons and mitral/tufted cells was not altered by the experimental manipulation. These results suggest that the olfactory bulb can regulate the number of afferent fibers.

Neuroectodermal origin of brain pericytes and vascular smooth muscle cells.

The origin of vascular pericytes (PCs) and smooth muscle cells (vSMCs) in the brain has hitherto remained an open question. In the present study, we used the quail-chick chimerization technique to elucidate the lineage of cranial PCs/vSMCs. We transplanted complete halves of brain anlagen, or dorsal (presumptive neural crest [NC]) or ventral cranial neural tube. Additional experiments included transplantations of neuroectoderm into limb mesenchyme, and of head mesoderm or limb mesenchyme into paraxial head mesoderm. After interspecific transplantation of quail brain rudiment, graft-derived vSMCs were found in the vessel walls of the grafted brain. Notably, transplanted ventral neural tube also gave rise to vSMCs. After grafting of quail head mesoderm, quail endothelial cells were found in the host brain, but no vSMCs of donor origin. Grafting of quail whole or ventral neural tube into the limb bud led to endowment of graft and host vessels with graft-derived vSMCs. Quail limb bud mesenchyme contributed to vSMCs in the ectopic neural graft, but, when transplanted into paraxial head mesenchyme, it did not form intraneural vSMCs. After orthotopic transplantation of cranial NC, graft-derived vSMCs were not only found in meninges and brain of the operated side, but also on the contralateral side. Our results show that 1) avian cranial neuroectoderm is able to differentiate into vSMCs of the brain; 2) this potential is not restricted to the prospective NC; and 3) neither cranial mesoderm nor cranially transplanted limb bud mesoderm can give rise to brain vSMC.

Neuroectodermal grafting: a new tool for the study of neurodegenerative diseases.

Transgenic and knockout mice have contributed much to our current understanding of the role played by single genes during development and in pathological processes of the CNS, such as neuro-degeneration. However, embryonic lethality resulting from the disruption of important genes has often hindered the interpretation of such experiments. Grafting of immature cells from genetically modified organisms into healthy recipients promises to efficiently bypass this problem. We have used neural transplantation techniques which allow us to keep CNS tissue of knockout and transgenic mice viable for a prolonged period of time in the brain or in the kidney capsule of healthy recipients. We have characterized biological parameters such as growth, proliferation and differentiation and also the formation of an intact blood-brain barrier (BBB) after grafting of wild-type telencephalic anlage in this system. We have also employed this technique to study the longterm properties of neuroepithelial tissue derived from knockout mice. The results of our studies are discussed in the context of neurodegenerative diseases.

Implantation of xenogeneic transgenic neural plate tissues into parkinsonian rat brain.

Xenografting must be considered as a means of establishing neural transplantation therapy and of securing fetal neural tissues as donor material. The early stage (embryonic day 8.5, E8.5) embryonic mesencephalic neural plate (NP) from transgenic mice was examined for possible application in effective xenografting therapy. As recipients, Parkinsonian rats treated with 6-hydroxydopamine were used, and as donors, GT4-2 mice into which a beta-galactosidase gene was introduced to allow brain tissue differentiation from the recipients by X-gal staining. Three microscopic pieces of E8.5 GT4-2 mice NP were injected into the striatum of the Parkinsonian rats. Some hosts were given immunosuppressants (cyclophosphamide and FK506) (IS group), others were not (non-IS group). Amphetamine-induced rotation was examined at days 11 and 21 after grafting (D11 and D21, respectively), and morphological investigations were performed using hematoxylin-eosin (H-E), X-gal, and thyrosine hydroxylase (TH) staining. The rotations were counted in 30 of the 38 transplanted rats before and after grafting. Histological data were obtained from 19 of these 30 rats. In 11 of them the grafts survived (survival group) and in the remaining 8, the grafts were unsuccessful (rejection group). In the survival group at D11, the mean number of rotations made by transplanted rats expressed as a percentage of the number before grafting (rotation percentage) decreased to 43.8% (n = 9), which, in comparison with the average of 125.9% (n = 6) in the rejection group, reveals significant behavioral recovery (p < 0.01). The rotation percentage at D21 was 23.8% in the survival group (n = 4) and 84.5% in the rejection group (n = 3). Behavioral recovery was thus seen to improve with time in the survival group. In the IS group (n = 19), the rotation percentages averaged 74.9% (D11, n = 15) and 51.1% (D21, n = 7), while the non-IS group averages were 136.7% (D11, n = 9) and 140.7% (D21, n = 9), indicating a tendency for better behavioral recovery in the IS group than in the non-IS group (p < 0.05). Fifteen IS group rats were studied histologically, 10 (sacrificed on D11, D21) from the survival group and 5 (sacrificed on D11, D21) from the rejection group, In the non-IS group (n = 4), there was a graft in only one rat sacrificed on D11. There were many X-gal positive and TH positive cells in the grafts, suggesting that mouse NP survived, and differentiated into TH positive neurons in the rat brain. Xenografted NP has the potential to cure central nervous system diseases.