Glucose metabolism impacts the spatiotemporal onset and magnitude of HSC induction in vivo.

Many pathways regulating blood formation have been elucidated, yet how each coordinates with embryonic biophysiology to modulate the spatiotemporal production of hematopoietic stem cells (HSCs) is currently unresolved. Here, we report that glucose metabolism impacts the onset and magnitude of HSC induction in vivo. In zebrafish, transient elevations in physiological glucose levels elicited dose-dependent effects on HSC development, including enhanced runx1 expression and hematopoietic cluster formation in the aorta-gonad-mesonephros region; embryonic-to-adult transplantation studies confirmed glucose increased functional HSCs. Glucose uptake was required to mediate the enhancement in HSC development; likewise, metabolic inhibitors diminished nascent HSC production and reversed glucose-mediated effects on HSCs. Increased glucose metabolism preferentially impacted hematopoietic and vascular targets, as determined by gene expression analysis, through mitochondrial-derived reactive oxygen species (ROS)-mediated stimulation of hypoxia-inducible factor 1α (hif1α). Epistasis assays demonstrated that hif1α regulates HSC formation in vivo and mediates the dose-dependent effects of glucose metabolism on the timing and magnitude of HSC production. We propose that this fundamental metabolic-sensing mechanism enables the embryo to respond to changes in environmental energy input and adjust hematopoietic output to maintain embryonic growth and ensure viability.

Leukaemia inhibitory factor inhibits cardiomyogenesis of mouse embryonic stem cells via STAT3 activation.

The leukaemia inhibitory factor is a cytokine that exhibits pleiotropic activities in a wide range of cell types. There are evidences that leukaemia inhibitory factor-regulated signalling pathways are involved in cardiomyogesis and maintenance of cardiomyocytes. In the present work we studied the effect of leukaemia inhibitory factor on cardiomyogenesis of embryonic stem cells together with the role of serum-born factors. We showed that leukaemia inhibitory factor had an inhibitory effect during both the induction and progression phases of cardiomyogenesis of embryonic stem cells. The leukaemia inhibitory factor-mediated inhibition of cardiomyogenesis was abolished by inhibitors of STAT3 activity. These results suggest that leukaemia inhibitory factor- activated STAT3 is responsible for the inhibition of cardiomyogenesis in embryonic stem cells.

BMP4 induction of trophoblast from mouse embryonic stem cells in defined culture conditions on laminin.

Because mouse embryonic stem cells (mESCs) do not contribute to the formation of extraembryonic placenta when they are injected into blastocysts, it is believed that mESCs do not differentiate into trophoblast whereas human embryonic stem cells (hESCs) can express trophoblast markers when exposed to bone morphogenetic protein 4 (BMP4) in vitro. To test whether mESCs have the potential to differentiate into trophoblast, we assessed the effect of BMP4 on mESCs in a defined monolayer culture condition. The expression of trophoblast-specific transcription factors such as Cdx2, Dlx3, Esx1, Gata3, Hand1, Mash2, and Plx1 was specifically upregulated in the BMP4-treated differentiated cells, and these cells expressed trophoblast markers. These results suggest that BMP4 treatment in defined culture conditions enabled mESCs to differentiate into trophoblast. This differentiation was inhibited by serum or leukemia inhibitory factor, which are generally used for mESC culture. In addition, we studied the mechanism underlying BMP4-directed mESC differentiation into trophoblast. Our results showed that BMP4 activates the Smad pathway in mESCs inducing Cdx2 expression, which plays a crucial role in trophoblast differentiation, through the binding of Smad protein to the Cdx2 genomic enhancer sequence. Our findings imply that there is a common molecular mechanism underlying hESC and mESC differentiation into trophoblast.

Pharmacological properties of purinergic receptors and their effects on proliferation and induction of neuronal differentiation of P19 embryonal carcinoma cells.

We have used P19 embryonal carcinoma cells as in vitro model for early neurogenesis to study ionotropic P2X and metabotropic P2Y receptor-induced Ca(2+) transients and their participation in induction of proliferation and differentiation. In embryonic P19 cells, P2Y(1), P2Y(2) and P2X(4) receptors or P2X-heteromultimers with similar P2X(4) pharmacology were responsible for ATP and ATP analogue-induced Ca(2+) transients. In neuronal-differentiated cells, P2Y(2,) P2Y(6), P2X(2) and possibly P2X(2)/P2X(6) heteromeric receptors were the major mediators of the elevations in intracellular free calcium concentration [Ca(2+)](i). We have collected evidence for the involvement of metabotropic purinergic receptors in proliferation induction of undifferentiated and neural progenitor cells by using a BrdU-incorporation assay. ATP-, UTP-, ADP-, 2-MeS-ATP- and ADP-betaS-induced proliferation in P19 cells was mediated by P2Y(1) and P2Y(2) receptors as judged from pharmacological profiles of receptor responses. ATP-provoked acceleration of neuronal differentiation, determined by analysis of nestin and neuron-specific enolase gene and protein expression, also resulted from P2Y(1) and P2Y(2) receptor activation. Proliferation- and differentiation-induction involved the activation of inositol-trisphosphate sensitive intracellular Ca(2+) stores.

Stage-specific effects of retinoic acid on gene expression during forebrain development.

Treatment of early gastrula- and neurula-staged Xenopus embryos with all-trans retinoic acid (RA) results in truncation of the anterior structures of the forebrain and head. The extent of truncation is dependent upon both the stage of immersion and the RA concentration used. As a method to investigate genes important during early forebrain regionalization, late gastrula and neurula embryos were immersed for 2h within low (1x10(-9)M to 5x10(-8)M) concentrations of RA. Embryos were allowed to develop to tadpole stages and forebrain marker genes were assessed for any alteration in patterns of expression. Comparisons of controls to experimental groups indicated that the greatest sensitivity to low levels of RA occurred just before the initial expression of the forebrain-specific markers investigated. We concluded that forebrain regionalization and gene expression occurred in the following order: Xotx2-->Xsix3-->Xrx (&Xfez1)-->Xbf1-->Xemx1. Xsix3 seems to be very important for the initial parcellation of telencephalon, retinal and diencephalon areas.

Ciliogenesis, ciliary function, and selective isolation.

In addition to their classic role in cell motility, certain cilia have sensory or signaling functions. In sea urchin embryos, short motile cilia randomly propel the early embryo, while a group of long, immotile cilia appear later, coincident with directional swimming and localized within a region that gives rise to the larval nervous system. Motile cilia can be selectively removed by treatment with a novel derivative of dillapiol, leaving the putative sensory cilia for comparative investigation and a gently deciliated embryo ready for studies of regeneration signaling.

Activin alters the kinetics of endoderm induction in embryonic stem cells cultured on collagen gels.

Embryonic stem cell-derived endoderm is critical for the development of cellular therapies for the treatment of disease such as diabetes, liver cirrhosis, or pulmonary emphysema. Here, we describe a novel approach to induce endoderm from mouse embryonic stem (mES) cells using fibronectin-coated collagen gels. This technique results in a homogeneous endoderm-like cell population, demonstrating endoderm-specific gene and protein expression, which remains committed following in vivo transplantation. In this system, activin, normally an endoderm inducer, caused an 80% decrease in the Foxa2-positive endoderm fraction, whereas follistatin increased the Foxa2-positive endoderm fraction to 78%. Our work suggests that activin delays the induction of endoderm through its transient precursors, the epiblast and mesendoderm. Long-term differentiation displays a twofold reduction in hepatic gene expression and threefold reduction in hepatic protein expression of activin-treated cells compared with follistatin-treated cells. Moreover, subcutaneous transplantation of activin-treated cells in a syngeneic mouse generated a heterogeneous teratoma-like mass, suggesting that these were a more primitive population. In contrast, follistatin-treated cells resulted in an encapsulated epithelial-like mass, suggesting that these cells remained committed to the endoderm lineage. In conclusion, we demonstrate a novel technique to induce the direct differentiation of endoderm from mES cells without cell sorting. In addition, our work suggests a new role for activin in induction of the precursors to endoderm and a new endoderm-enrichment technique using follistatin.

The Xenopus POU class V transcription factor XOct-25 inhibits ectodermal competence to respond to bone morphogenetic protein-mediated embryonic induction.

Bone morphogenetic proteins (BMPs) have been shown to play a key role in controlling ectodermal cell fates by inducing epidermis at the expense of neural tissue during gastrulation. Here, we present evidence that the Xenopus POU class V transcription factor XOct-25 regulates ectodermal cell fate decisions by inhibiting the competence of ectodermal cells to respond to BMP during Xenopus embryogenesis. When overexpressed in the ectoderm after the blastula stage, XOct-25 suppressed early BMP responses of ectodermal cells downstream of BMP receptor activation and promoted neural induction while suppressing epidermal differentiation. In contrast, inhibition of XOct-25 function in the prospective neuroectoderm resulted in expansion of epidermal ectoderm at the expense of neuroectoderm. The reduction of neural tissue by inhibition of XOct-25 function could be rescued by decreasing endogenous BMP signaling, suggesting that XOct-25 plays a role in the formation of neural tissue at least in part by inhibiting BMP-mediated epidermal induction (neural inhibition). This hypothesis is supported by the observation that ectodermal cells from XOct-25 morphants were more sensitive to BMP signaling than cells from controls in inducing both immediate early BMP target genes and epidermis at the expense of neural tissue, while cells overexpressing XOct-25 are less competent to respond to BMP-mediated induction. These results document an essential role for XOct-25 in commitment to neural or epidermal cell fates in the ectoderm and highlight the importance of a regulatory mechanism that limits competence to respond to BMP-mediated embryonic induction.

Monitoring of gene expression in differentiation of embryoid bodies from cynomolgus monkey embryonic stem cells in the presence of bisphenol A.

An embryonic stem (ES) cell differentiation model would facilitate analysis of developmental processes at the cellular level and the effects of embryotoxic and teratogenic factors in vitro. We explored the use of differentiation of embryoid bodies (EBs) from cynomolgus monkey ES cells for embryotoxicity testing. We determined the mRNA expression of various genes using real-time RT-PCR. Oct-3/4 expression was almost completely suppressed on day 14, suggesting that ES cells reached differentiated status in around 14 days. mRNA expression of E-cadherin, connexin 43, caveolin-1, and argininosuccinate synthetase was reproducibly suppressed during EB differentiation in 7-32% of ES cells in three separate experiments. Although these may not be "general stemness marker genes" such as Oct-3/4, they could play a role in readying stem cells for differentiation in response to deletion of signals from feeder cells. Next, we examined the effects of bisphenol A (BPA) on the mRNA expression of several differentiation marker genes for ES cells. That of PAX-6, an ectoderm marker, with 0, 0.1, and 10 microM BPA in 21-day EBs was 3,500%, 6,668%, and 8,394%, respectively, compared with ES cells. The difference between doses of 0 and 10 microM BPA in 21-day EBs was statistically significant (p=0.049). Pax-6 activation in the presence of BPA may interfere with the development of eyes, sensory organs, and certain neural and epidermal tissues usually derived from ectodermal tissues. Differentiation of EBs from cynomolgus monkey ES cells could be a useful model for detecting gene expression changes in response to chemical exposure.

A global view of gene expression in lithium and zinc treated sea urchin embryos: new components of gene regulatory networks.

BACKGROUND: The genome of the sea urchin Strongylocentrotus purpuratus has recently been sequenced because it is a major model system for the study of gene regulatory networks. Embryonic expression patterns for most genes are unknown, however. RESULTS: Using large-scale screens on arrays carrying 50% to 70% of all genes, we identified novel territory-specific markers. Our strategy was based on computational selection of genes that are differentially expressed in lithium-treated embryos, which form excess endomesoderm, and in zinc-treated embryos, in which endomesoderm specification is blocked. Whole-mount in situ hybridization (WISH) analysis of 700 genes indicates that the apical organ region is eliminated in lithium-treated embryos. Conversely, apical and specifically neural markers are expressed more broadly in zinc-treated embryos, whereas endomesoderm signaling is severely reduced. Strikingly, the number of serotonergic neurons is amplified by at least tenfold in zinc-treated embryos. WISH analysis further indicates that there is crosstalk between the Wnt (wingless int), Notch, and fibroblast growth factor signaling pathways in secondary mesoderm cell specification and differentiation, similar to signaling cascades that function during development of presomitic mesoderm in mouse embryogenesis. We provide differential expression data for more than 4,000 genes and WISH patterns of more than 250 genes, and more than 2,400 annotated WISH images. CONCLUSION: Our work provides tissue-specific expression patterns for a large fraction of the sea urchin genes that have not yet been included in existing regulatory networks and await functional integration. Furthermore, we noted neuron-inducing activity of zinc on embryonic development; this is the first observation of such activity in any organism.

Brain induction in ascidian embryos is dependent on juxtaposition of FGF9/16/20-producing and -receiving cells.

Coordinated regulation of inductive events, both spatially and temporally, during animal development ensures that tissues are induced at their specific positions within the embryo. The ascidian brain is induced in cells at the anterior edge of the animal hemisphere by fibroblast growth factor (FGF) signals secreted from vegetal cells. To clarify how this process is spatially regulated, we first identified the sources of the FGF signal by examining the expression of brain markers Hr-Otx and Hr-ETR-1 in embryos in which FGF signaling is locally inhibited by injecting individual blastomeres with morpholino oligonucleotide against Hr-FGF9/16/20, which encodes an endogenous brain inducer. The blastomeres identified as the inducing sources are A5.1 and A5.2 at the 16-cell stage and A6.2 and A6.4 at the 24-cell stage, which are juxtaposed with brain precursors at the anterior periphery of the embryo at the respective stages. We also showed that all the cells of the animal hemisphere are capable of expressing Hr-Otx in response to the FGF signal. These results suggest that the position of inducers, rather than competence, plays an important role in determining which animal cells are induced to become brain tissues during ascidian embryogenesis. This situation in brain induction contrasts with that in mesoderm induction, where the positions at which the notochord and mesenchyme are induced are determined mainly by intrinsic competence factors that are inherited by signal-receiving cells.

Tbx5 is dispensable for forelimb outgrowth.

Tbx5 is essential for initiation of the forelimb, and its deletion in mice results in the failure of forelimb formation. Misexpression of dominant-negative forms of Tbx5 results in limb truncations, suggesting Tbx5 is also required for forelimb outgrowth. Here we show that Tbx5 is expressed throughout the limb mesenchyme in progenitors of cartilage, tendon and muscle. Using a tamoxifeninducible Cre transgenic line, we map the time frame during which Tbx5 is required for limb development. We show that deletion of Tbx5 subsequent to limb initiation does not impair limb outgrowth. Furthermore, we distinguish two distinct phases of limb development: a Tbx5-dependent limb initiation phase, followed by a Tbx5-independent limb outgrowth phase. In humans, mutations in the T-box transcription factor TBX5 are associated with the dominant disorder Holt-Oram syndrome (HOS), which is characterised by malformations in the forelimb and heart. Our results demonstrate a short temporal requirement for Tbx5 during early limb development, and suggest that the defects found in HOS arise as a result of disrupted TBX5 function during this narrow time window.

Tbx4 is not required for hindlimb identity or post-bud hindlimb outgrowth.

Tbx4 is a crucial gene in the initiation of hindlimb development and has been reported as a determinant of hindlimb identity and a presumptive direct regulator of Fgf10 in the limb. Using a conditional allele of Tbx4, we have ablated Tbx4 function before and after limb initiation. Ablation of Tbx4 before expression in the hindlimb field confirms its requirement for limb bud outgrowth. However, ablation of Tbx4 shortly after onset of expression in the hindlimb field, during limb bud formation, alters neither limb outgrowth nor expression of Fgf10. Instead, post-limb-initiation loss of Tbx4 results in reduction of limb core tissue and hypoplasia of proximal skeletal elements. Loss of Tbx4 during later limb outgrowth produces no limb defects, revealing a brief developmental requirement for Tbx4 function. Despite evidence from ectopic expression studies, our work establishes that loss of Tbx4 has no effect on hindlimb identity as assessed by morphology or molecular markers.

Efficient cardiomyocyte differentiation of embryonic stem cells by bone morphogenetic protein-2 combined with visceral endoderm-like cells.

As the signals required for cardiomyocyte differentiation and functional regulation are complex and only partly understood, the mechanisms prompting the differentiation and specification of pluripotential embryonic stem (ES) cells into cardiomyocytes remain unclear. We hypothesized that a combined technology system, cocultured with a visceral endoderm (VE) - like cell line, END-2, and added cytokine BMP-2, would induce high percentage conversion of murine ES-D3 cell line into cardiomyocytes, and derived cardiomyocytes in this system would exhibit more mature characteristics. It was observed that 92% (P<0.01) ES cell-derived aggregates in this system exhibited rhythmic contractions, and the contractile areas were greater. By contrast, in ES cells cultured alone, on the feeder layer of END-2 cells, or with added BMP-2, the total percentage of beating aggregates was 19, 69 (P<0.01) and 44% (P<0.01), respectively. All the rhythmically contractile cells derived from ES cells expressed cardiac-specific proteins for troponin T. Among them, the combined system resulted in significantly increased cardiac-specific genes (NKx2.5, alpha-MHC). Transmission electron microscopy (TEM) revealed varying degrees of myofibrillar organization, and the combined system resulted in a more mature phenotype such as Z bands, nascent intercalated discs and gap junctions. Before shifting to the cardiomyocyte phenotype, this system could accelerate apoptosis of the cell population (P<0.01). The inductive efficacy of this system can provide an opportunity to facilitate cardiomyocyte differentiation of ES cells. The inducible effects of this system may depend on increasing cardiac-specific gene expression and the induction of apoptosis in cells that are not committed to cardiac differentiation.

Induction of oligodendrocyte progenitors in dorsal forebrain by intraventricular microinjection of FGF-2.

During embryonic development, oligodendrocyte progenitors (OLPs) originate from the ventral forebrain under the regulation of Sonic hedgehog (Shh). Shh controls the expression of transcription factor Olig2, which is strongly implicated in OLP generation. Studies of mice deficient in Shh expression suggest, however, that an alternative pathway for OLP generation may exist. The generation of OLPs in dorsal forebrain has been suggested since treatment of dorsal-neural progenitor cells in culture with fibroblast growth factor (FGF-2) results in OLP induction. To ask if dorsal induction of OLPs in embryonic forebrain can occur in vivo and if FGF-2 could initiate an alternative pathway of regulation, we used in utero microinjection of FGF-2 into the lateral ventricles of mouse fetal forebrain. A single injection of FGF-2 at E13.5 resulted in the expression of the OLP markers Olig2 and PDGFRalpha mRNA in dorsal forebrain ventricular and intermediate zones. However, FGF-2 did not induce dorsal expression of Shh, Patched1 or Nkx2.1, and co-injection of FGF-2 and a Shh inhibitor did not attenuate the induction of Olig2 and PDGFRalpha, suggesting that Shh signaling was not involved in this FGF-2-mediated dorsal induction. These results demonstrate that the dorsal embryonic forebrain in vivo has the potential to generate OLPs in the presence of normal positional cues and that this can be driven by FGF-2 independent of Shh signaling.

One-step induction of neurons from mouse embryonic stem cells in serum-free media containing vitamin B12 and heparin.

We present a simple method for neural cell fate specification directly from mouse embryonic stem cells (ES cells) in serum-free conditions in the absence of embryoid body formation. Dissociated ES cells were cultured in serum-free media supplemented with vitamin B12 and heparin, but without any expensive cytokines. After 14 days in culture, beta-tubulin type III (TuJ1) and tyrosine hydroxylase (TH)-positive colonies were detected by immunocytochemical examinations. In addition, specific gene analyses by RT-PCR demonstrated expression of an early central nerve system, mature neuron, and midbrain dopaminergic neuron-specific molecules (i.e., nestin, middle molecular mass neurofilament protein, Nurr1, and TH, respectively). Dopamine was also detected in the culture media by reverse-phase HPLC analysis. These facts indicate that addition of vitamin B12/heparin to serum-free culture media induced neurons from ES cells, which included cells that released dopamine. Other supplements, such as putrescine, biotin, and Fe2+, could not induce neurons from ES cells by themselves, but produced synergistic effects with vitamin B12/heparin. The rate of TuJ1+/TH+ colony formation was increased threefold and the amounts of dopamine released increased 1.5-fold by the addition of a mixture of putrescine, biotin, and Fe2+ to vitamin B12/heparin culture media. Our method is a simple tool to differentiate ES cells to dopaminergic neurons for the preparation of dopamine-releasing cells for the cell transplantation therapy of Parkinson's disease. In addition, this method can facilitate the discovery of soluble factors and genes that can aid in the induction of the ES cell to its neural fate.

Comparison of induction during development between Xenopus tropicalis and Xenopus laevis.

Several in vitro systems exist for the induction of animal caps using growth factors such as activin. In this paper, we compared the competence of activin-treated animal cap cells dissected from the late blastulae of Xenopus tropicalis and Xenopus laevis. The resultant tissue explants from both species differentiated into mesodermal and endodermal tissues in a dose-dependent manner. In addition, RT-PCR analysis revealed that organizer and mesoderm markers were expressed in a similar temporal and dose-dependent manner in tissues from both organisms. These results indicate that animal cap cells from Xenopus tropicalis have the same competence in response to activin as those from Xenopus laevis.

In vitro maturation and fertilization of porcine oocytes after a 48 h culture in roscovitine, an inhibitor of p34cdc2/cyclin B kinase.

Maintaining oocytes at the germinal vesicle (GV) stage in vitro may permit enhanced acquisition of the developmental competence. The objective of the current study was to evaluate the nuclear and cytoplasmic maturation in vitro of porcine oocytes after pretreatment with S-roscovitine (ROS). Cumulus oocyte complexes (COC) were treated with 50 microM ROS for 48 h and then matured for various lengths of time in a conventional step-wise in vitro maturation (IVM) system by using dibutyryl cyclic AMP. The COC that were matured in the same system for 44 h without pretreatment with ROS were used as the control group. At various periods after the start of IVM, oocytes were assessed for the meiotic stages and subjected to in vitro fertilization (IVF) with fresh spermatozoa. The ROS treatment inhibited GV breakdown of 94.4% oocytes, with the majority arrested at the GV-I stage (67.4%). Maximum maturation rate to the metaphase-II stage after ROS treatment was achieved by 44 h of IVM (92.1%) and no differences were observed with control oocytes (95.0%). Penetration rate was correlated to the maturation rate. The duration of IVM had no effects on polyspermy and male pronuclear (MPN) formation rates at 8 h post insemination (hpi), whereas both rates increased at 22 hpi. Direct comparison with controls assessed at 22 hpi confirmed a lesser MPN formation in ROS-treated oocytes (73.7% compared with 53.6%). Glutathione (GSH) concentrations were less in oocytes treated with ROS than in control oocytes (5 compared with 7.7 pmol/oocyte) as well as blastocyst rate (22.0% compared with 38.1%, respectively). These results demonstrate that cytoplasmic maturation in porcine oocytes pretreated with ROS for 48 h did not equal that of control oocytes in the current IVM system.

Parthenogenetic and nuclear transfer rabbit embryo development and apoptosis after activation treatments.

Previous studies mainly evaluated the effect of culture conditions on preimplantation embryo apoptosis. In order to inhibit apoptosis of nuclear transfer (NT) embryos, putative apoptosis inhibitors were used to treat donor cells. However, little is known about the effect of activation treatments on embryo apoptosis. We firstly investigated the effect of various parthenogenetic activation (PA) treatments on embryo development, blastocyst cell number, and apoptosis, and then one of these activation treatments proved to be most efficient was selected for activation rabbit NT embryos. The activation by electrical pulses and 30 min later, electroporation with 25 muM D-myoinositol 1,4,5-trisphosphate (IP3) in Ca(2+)- and Mg(2+)-free PBS, then exposure to 2.0 mM 6-dimethylaminopurine (6-DMAP) for 3 hr effectively activated rabbit oocytes, and resulted in significantly a higher blastocyst development rate (72.7%) and total cell number (175 +/- 14.1), and markedly lower apoptosis level of blastocyst (4.3 +/- 0.5) than all the other groups. When the same activation protocol was applied in NT embryo activation, we found that exposure of the embryos to 6-DMAP for 3 hr could decrease the apoptosis level of blastocyst and increase blastocyst rate and cell number. The results demonstrate that oocyte activation affects not only embryo development and quality but also embryo apoptosis.

Calcium transients and neural induction in vertebrates.

Evidence indicates that a variety of different types of Ca2+ transients (i.e., standing gradients, pulses and propagating waves) may be occurring both simultaneously and sequentially during neural induction in vertebrate embryos. Transients have been observed in the dorsal marginal zone and in the presumptive neural ectoderm, suggesting that they may be generated within two distinct germ layers at separate embryological locations. It has been proposed that the Ca2+ transients might have multiple roles during the period of neural induction, ranging from: activating the expression of early neural genes; contributing to the inhibition of BMP-4 signalling; generating secretion gradients of morphogens; regulating and co-ordinating convergent extension; and establishing and reinforcing dorsoventral axis specification. Both intra- and extracellular stores (either acting separately or in combination) have been shown to generate the neuralizing Ca2+ transients via well-established release mechanisms, and transients have been shown to propagate between connected cells, suggesting an intercellular signalling dimension. Thus, good evidence is accumulating to suggest that Ca2+ might be a key central regulator in the process of neural induction.