35 research outputs found
Recent advances in neural development
A surprisingly small number of signalling pathways are used reiteratively during neural development, eliciting very different responses depending on the cellular context. Thus, the way a neural cell responds to a given signal is as important as the signal itself and this responsiveness, also called competence, changes with time. Here we describe recent advances in elucidating the signalling pathways that operate in brain development
Complex and dynamic patterns of Wnt pathway gene expression in the developing chick forebrain
<p>Abstract</p> <p>Background</p> <p>Wnt signalling regulates multiple aspects of brain development in vertebrate embryos. A large number of <it>Wnt</it>s are expressed in the embryonic forebrain; however, it is poorly understood which specific Wnt performs which function and how they interact. Wnts are able to activate different intracellular pathways, but which of these pathways become activated in different brain subdivisions also remains enigmatic.</p> <p>Results</p> <p>We have compiled the first comprehensive spatiotemporal atlas of Wnt pathway gene expression at critical stages of forebrain regionalisation in the chick embryo and found that most of these genes are expressed in strikingly dynamic and complex patterns. Several expression domains do not respect proposed compartment boundaries in the developing forebrain, suggesting that areal identities are more dynamic than previously thought. Using an <it>in ovo </it>electroporation approach, we show that <it>Wnt4 </it>expression in the thalamus is negatively regulated by Sonic hedgehog (Shh) signalling from the zona limitans intrathalamica (ZLI), a known organising centre of forebrain development.</p> <p>Conclusion</p> <p>The forebrain is exposed to a multitude of Wnts and Wnt inhibitors that are expressed in a highly dynamic and complex fashion, precluding simple correlative conclusions about their respective functions or signalling mechanisms. In various biological systems, Wnts are antagonised by Shh signalling. By demonstrating that <it>Wnt4 </it>expression in the thalamus is repressed by Shh from the ZLI we reveal an additional level of interaction between these two pathways and provide an example for the cross-regulation between patterning centres during forebrain regionalisation.</p
Tissue interactions in the developing chick diencephalon
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The emergence of mesencephalic trigeminal neurons
Background The cells of the mesencephalic trigeminal nucleus (MTN) are the
proprioceptive sensory neurons that innervate the jaw closing muscles. These
cells differentiate close to the two key signalling centres that influence the
dorsal midbrain, the isthmus, which mediates its effects via FGF and WNT
signalling and the roof plate, which is a major source of BMP signalling as
well as WNT signalling. Methods In this study, we have set out to analyse the
importance of FGF, WNT and BMP signalling for the development of the MTN. We
have employed pharmacological inhibitors of these pathways in explant cultures
as well as utilising the electroporation of inhibitory constructs in vivo in
the chick embryo. Results We find that interfering with either FGF or WNT
signalling has pronounced effects on MTN development whilst abrogation of BMP
signalling has no effect. We show that treatment of explants with either FGF
or WNT antagonists results in the generation of fewer MTN neurons and affects
MTN axon extension and that inhibition of both these pathways has an additive
effect. To complement these studies, we have used in vivo electroporation to
inhibit BMP, FGF and WNT signalling within dorsal midbrain cells prior to, and
during, their differentiation as MTN neurons. Again, we find that inhibition
of BMP signalling has no effect on the development of MTN neurons. We
additionally find that cells electroporated with inhibitory constructs for
either FGF or WNT signalling can differentiate as MTN neurons suggesting that
these pathways are not required cell intrinsically for the emergence of these
neurons. Indeed, we also show that explants of dorsal mesencephalon lacking
both the isthmus and roof plate can generate MTN neurons. However, we did find
that inhibiting FGF or WNT signalling had consequences for MTN
differentiation. Conclusions Our results suggest that the emergence of MTN
neurons is an intrinsic property of the dorsal mesencephalon of gnathostomes,
and that this population undergoes expansion, and maturation, along with the
rest of the dorsal midbrain under the influence of FGF and WNT signalling
The chick embryo as a model for the effects of prenatal exposure to alcohol on craniofacial development
Molecular specification of germ layers in vertebrate embryos
In order to generate the tissues and organs of a multicellular organism, different cell types have to be generated during embryonic development. The first step in this process of cellular diversification is the formation of the three germ layers: ectoderm, endoderm and mesoderm. The ectoderm gives rise to the nervous system, epidermis and various neural crest-derived tissues, the endoderm goes on to form the gastrointestinal, respiratory and urinary systems as well as many endocrine glands, and the mesoderm will form the notochord, axial skeleton, cartilage, connective tissue, trunk muscles, kidneys and blood. Classic experiments in amphibian embryos revealed the tissue interactions involved in germ layer formation and provided the groundwork for the identification of secreted and intracellular factors involved in this process. We will begin this review by summarising the key findings of those studies. We will then evaluate them in the light of more recent genetic studies that helped clarify which of the previously identified factors are required for germ layer formation in vivo, and to what extent the mechanisms identified in amphibians are conserved across other vertebrate species. Collectively, these studies have started to reveal the gene regulatory network (GRN) underlying vertebrate germ layer specification and we will conclude our review by providing examples how our understanding of this GRN can be employed to differentiate stem cells in a targeted fashion for therapeutic purposes