The Role of Pax3 in Neuronal Differentiation of the Ophthalmic (OpV) Trigeminal Placode and Neural Tube during Chicken Embryonic Development

Bradshaw, James R.

16 March 2006

Pax3 has been used as a valuable marker in research aimed at understanding tissue interactions involved in trigeminal ophthalmic (opV) placode development. While Pax3 expression coincides with opV neuron specification, the function of Pax3 in these cells has not previously been investigated. Splotch mutant mice (which lack Pax3) have a reduced trigeminal ganglion; however it is not clear whether this reduction is due to neural crest or placode cells. We have used electroporation in the chick model system to block or ectopically express Pax3 at key times in opV placode development. Using several markers of placode cell differentiation, we have determined the experimental effects manipulating Pax3. Blocking placodal Pax3 with gene specific morpholinos resulted in a loss of migratory placode cells, and a downregulation of all opV placode markers in targeted cells. Ectopic expression of Pax3, either within the placode domain or in adjacent cranial ectoderm, resulted in the upregulation of some but not all placode markers. We conclude that opV placodal Pax3 expression is required for normal placode cell development, and hypothesize that its expression must be tightly regulated in order for placode cells to fully differentiate. The precise role of Pax3 and Pax7 in the restriction and differentiation of dorsal interneuron progenitors has been difficult to assess due to the many additional factors involved in specification and patterning of the neural tube. We have used electroporation in the chick model system to ectopically express Pax3 and Pax7 unilaterally in the neural tube. Using several markers for differentiation of ventral and dorsal neuronal progenitors, we have experimentally determined the effects of Pax3 and Pax7 ventrally and dorsally. Ectopic expression of these transcription factors in the ventral neural tube resulted in the loss of motorneurons. Though mis-expression did not qualitatively affect commissural neurons as assayed by neurofilament staining, ectopic expression of Pax3 and Pax7 in the dorsal neural tube stopped dorsal interneuron progenitors from differentiating. We conclude that Pax3 and Pax7 expression is sufficient to restrict ventral neuron identity. We also hypothesize that downregulation of these transcription factors in the dorsal neural tube is required for normal dorsal interneuron differentiation.

Ophthalmic Placode

Neural Tube

Pax3

Sensory Neuron

Dorsal Interneuron

Cell and Developmental Biology

Physiology

A Model for Sensory Neuron Development by FGF and Notch: A Multifactorial Approach

Voelkel, Jacob Eugene

28 June 2013

The ophthalmic trigeminal placode (opV) exclusively gives rise to sensory neurons. A number of signaling pathways including Wnt, PDGF, FGF, and Notch are all involved in the progression of an undifferentiated cell in the opV placode to a proneural cell in the condensing opV ganglion. However, the regulatory relationships between these signal transduction pathways are still unknown. To determine if FGF activation acts to modulate Notch signaling in the sensory neurogenesis pathway, a novel multifactorial approach was employed: FGF signaling was inhibited in individual cells and globally with simultaneous inactivation of Notch signaling in chick embryos to investigate if FGF activation downregulates Notch thereby driving neurogenesis. These experiments resulted in few differentiating opV cells in the mesenchymal region of future ganglion formation suggesting an alternate regulatory relationship between FGF and Notch where either reduced Notch activity allows for FGFR4 expression (leading to FGF signaling and neurogenesis), or a parallel relationship where FGF and Notch act independently of one another to induce neurogenesis. To distinguish between these two possibilities Notch signaling was inhibited with DAPT, a gamma-secretase inhibitor, and assayed for FGFR4 mRNA expression. These results indicated FGFR4 is not upregulated by reduced Notch activity, suggesting that FGF and Notch act in parallel to promote neurogenesis. During these experiments it was observed that Notch inhibition resulted in an undefined ectoderm in the opV placode region. To investigate this, FGF and Notch were inhibited by SU5402, an FGF antagonist, and DAPT, and later sectioned and stained for Laminin. In DAPT treated embryos the basement membrane became highly fragmented, a remarkable observation not yet reported. From these data a proposed mechanism was established where activation of FGF with parallel downregulation of Notch leads to disruption of extracellular matrix proteins in the basement membrane resulting in fragmentation and subsequent delamination of differentiating opV placode cells.

sensory neurogenesis

trigeminal ophthalmic placode

FGF signaling

Notch signaling

multifactorial

Cell and Developmental Biology

Physiology

O papel do compexo PAR durante a embriogênese do placóide do cristalino. / The role of PAR complex during lens placode embryogenesis.

Melo, Maraysa de Oliveira

08 August 2014

O cristalino se origina de um epitélio simples e cuboidal que recobre a vesícula óptica. Neste estádio, os filamentos de actina são distribuídos ao longo do eixo apicobasal. As células do ectoderma pré- placodal, em contato com a vesícula óptica, formam um epitélio pseudoestratificado, chamado de placóide do cristalino, com acúmulo de actina no domínio apical. Nós propusemos estudar o papel da proteína PAR3 e sua fosforilação no estabelecimento de actina apical. A superexpressão de PAR3 no placóide forma pontos ectópicos de PAR3 na membrana baso-lateral e induz o recrutamento de actina ectópica para esses pontos. O recrutamento de actina e aPKC ectópicos é independente do estado de fosforilação da treonina 833, resíduo localizado no domínio de ligação do PAR3 ao aPKC. Além disso, no ectoderma peri-placoidal, onde a actina localiza-se baso-lateralmente, PAR3 induz o recrutamento ectópico de actina apical e esse recrutamento é independente da fosforilação da treonina 833. Esses dados nos sugerem que PAR3 é suficiente para recrutar actina no placóide do cristalino. / The lens originates from a simple cuboidal epithelium that overlies the optic vesicle. At this stage, the actin filaments are distributed along its apical-basal sides. The pre-placodal ectoderm, in contact with the optic vesicle, forms a pseudostratified tissue, the lens placode, with accumulation of actin network at the apical domain. Here, we focused on the role of the polarity protein PAR3 and its phosphorylation in the establishment of this apical actin network. Overexpression of PAR3 in the lens placode, induced formation of ectopic actin clusters in the basolateral membrane of the lens placode. The formation of these actin clusters, as well as recruitment of aPKC was independent of Threonine 833 phosphorylation at the PAR3 aPKC-binding site. In addition, PAR3 induced ectopic actin networks in the apical membrane of the periplacodal ectoderm independent of the Threonine 833 phosphorylation. Taken together, these data suggest that PAR3 is sufficient for actin recruitment in the lens placode.

Actin

Actina

Cell polarization

Chicken embryo

Embrião de galinha

Lens placode

PAR proteins

Placoide do cristalino

Polarização celular

Proteínas PAR

Décrypter la formation de l'épithélium olfactif : de la diversité cellulaire à la morphogenèse / Deciphering olfactory epithelium development : from cell type diversity to morphogenesis

Aguillon, Raphaël

15 December 2017

La formation d'un organe repose sur la coordination spatio-temporelle du positionnement et de la différenciation de progéniteurs. La finalité de ces évènements permet la constitution structurelle de l'organe et la production de la diversité cellulaire nécessaire pour assurer ses fonctions. L'épithélium olfactif de l'embryon de poisson-zèbre est issu de la migration de progéniteurs qui vont générer entre autres les neurones olfactifs. Au cours de ma thèse je me suis intéressé aux bases génétiques et moléculaires de la coordination de la morphogenèse et de la neurogenèse de cet épithélium tout en étudiant l'origine de la diversité des types cellulaires olfactifs. L'imagerie en temps réel m'a permis de caractériser la migration de ces progéniteurs en générant une carte morphométrique de leur déplacement. Mon travail de thèse révèle que le proneural Neurog1 régule directement l'expression de cxcr4b, un récepteur au chimiokine, dans les progéniteurs olfactifs assurant leur positionnement. Ainsi, Neurog1 coordonnerait la position et l'identité des progéniteurs olfactifs via ses cibles transcriptionnelles. Au sein de l'épithélium olfactif dans l'embryon, deux populations cellulaires (neurones à GnRH et neurones à microvillosités) ont été décrites comme provenant des crêtes neurales céphaliques (CNC). J'ai pu montrer que l'expression de marqueurs spécifiques de ces populations n'est pas affectée dans un contexte d'absence de différenciation des CNCs (sox10-/-) suggérant que ces types cellulaires ne dérivent pas de ce territoire. Afin d'identifier leur territoire d'origine, j'ai développé une méthode d'imagerie en temps réel, le backtracking, qui m'a permis de déterminer que la région de la placode olfactive, et non les crêtes neurales, génère ces deux types cellulaires. Ainsi j'ai pu définir la source de ces deux populations neuronales tout en minimisant la contribution des crêtes neurales. En conclusion mes résultats suggèrent que la diversité des neurones olfactifs serait produite localement et ceci conjointement à la morphogenèse de l'épithélium. / The correct development of sensory organs relies on the coordination between changes in progenitor positioning over time and the differentiation/specification of different neural subtypes. The outcome of this coordination is proper organ shape and cell diversity, which are required for functionality. The zebrafish embryonic olfactory epithelium arises from progenitor migration and differentiation. During my PhD, I studied the genetic and molecular basis of morphogenesis in this tissue, and how this is coordinated with neurogenesis, as well as revisiting the origin of olfactory cell type diversity.First, I generated a morphometric map of olfactory progenitors through the characterization of their migration in live embryos. Next, I showed that the proneural transcription factor Neurog1 directly regulates cxcr4b expression, a chemokine receptor that has already been shown to govern olfactory progenitor positioning. Thus, Neurog1 orchestrates olfactory progenitor position and the generation of olfactory neurons via distinct transcriptional targets. Secondly, I addressed the origin of olfactory neuron diversity. Within the embryonic olfactory epithelium, two cell populations (GnRH neurons and microvillous neurons) have been described as cephalic neural crest (CNC) derivatives. I found, however, that the expression of specific markers of both populations is unaffected in a genetic context blocking CNC differentiation. To revisit the lineage assignment of these cell types, I developed a backtracking approach through time-lapse live imaging. I found that both populations are derived from classical olfactory placode progenitor and not the CNC. In conclusion, my results indicate that heterogeneity of olfactory cell-types is locally generated, and concomitant with morphogenesis of the placode.

Placode

Olfaction

Poisson zèbre

Développement

Identité cellulaire

Morphogenèse

Imagerie en temps réel

Zebrafish

Development

Cell identity

Morphogenesis

Time-lapse imaging

Etude de la fonction du facteur de transcription Dmrt5 dans le développement du système olfactif

Parlier, Damien

11 January 2013

\ / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Developmental neurobiology

Smell

Neurologie du développement

Odorat

Dmrt5

développement

système olfactif

génétique

placode

xénope

O papel do compexo PAR durante a embriogênese do placóide do cristalino. / The role of PAR complex during lens placode embryogenesis.

Maraysa de Oliveira Melo

08 August 2014

O cristalino se origina de um epitélio simples e cuboidal que recobre a vesícula óptica. Neste estádio, os filamentos de actina são distribuídos ao longo do eixo apicobasal. As células do ectoderma pré- placodal, em contato com a vesícula óptica, formam um epitélio pseudoestratificado, chamado de placóide do cristalino, com acúmulo de actina no domínio apical. Nós propusemos estudar o papel da proteína PAR3 e sua fosforilação no estabelecimento de actina apical. A superexpressão de PAR3 no placóide forma pontos ectópicos de PAR3 na membrana baso-lateral e induz o recrutamento de actina ectópica para esses pontos. O recrutamento de actina e aPKC ectópicos é independente do estado de fosforilação da treonina 833, resíduo localizado no domínio de ligação do PAR3 ao aPKC. Além disso, no ectoderma peri-placoidal, onde a actina localiza-se baso-lateralmente, PAR3 induz o recrutamento ectópico de actina apical e esse recrutamento é independente da fosforilação da treonina 833. Esses dados nos sugerem que PAR3 é suficiente para recrutar actina no placóide do cristalino. / The lens originates from a simple cuboidal epithelium that overlies the optic vesicle. At this stage, the actin filaments are distributed along its apical-basal sides. The pre-placodal ectoderm, in contact with the optic vesicle, forms a pseudostratified tissue, the lens placode, with accumulation of actin network at the apical domain. Here, we focused on the role of the polarity protein PAR3 and its phosphorylation in the establishment of this apical actin network. Overexpression of PAR3 in the lens placode, induced formation of ectopic actin clusters in the basolateral membrane of the lens placode. The formation of these actin clusters, as well as recruitment of aPKC was independent of Threonine 833 phosphorylation at the PAR3 aPKC-binding site. In addition, PAR3 induced ectopic actin networks in the apical membrane of the periplacodal ectoderm independent of the Threonine 833 phosphorylation. Taken together, these data suggest that PAR3 is sufficient for actin recruitment in the lens placode.

Actina

Embrião de galinha

Placoide do cristalino

Polarização celular

Proteínas PAR

Actin

Cell polarization

Chicken embryo

Lens placode

PAR proteins

Úloha transkripčního faktoru Tcf7l1 a signalizační dráhy Wnt/β-katenin během diferenciace hlavového ektodermu. / The role of transcriptional factor Tcf7l1 and Wnt/β-catenin signaling pathway during differentiation of the head ectoderm.

Mašek, Jan

January 2016

Differentiation of the head ectoderm is crucial for the evolutionary diversification of vertebrates. Expression of the genes responsible for this process is orchestrated troughout complex gene regulatory networks that are induced and modulated by Wnt, FGF and BMP signaling pathways. In addition, Wnt/β-catenin signaling, in combination with expression of the Wnt antagonists from the rostral-most part of the head ectoderm, represent a key source of information for the regionalization of the tissue along the antero-posterior axis. This allows the differentiation of the anterior ectoderm that gives rise to the anterior neural fold (ANF) and anterior part of the presumptive placodal region (PPR), and more posterior ectoderm where higher levels of active Wnt/β-catenin signaling promote differentiation into the neural crest (NC) and posterior PPR. Although the requirement of Wnt/β-catenin signalling for ANF, PPR and NC development has been intensively studied in non-mammalian vertebrate model organisms, we lack a clear picture about the situation in mammals. Furthermore, current knowledge in mammals has been gathered via experiments on the level of β-catenin and very little is known about the individual roles of the Tcf/Lef transcription factors. Thereby, we decided to manipulate the Tcf7l1, member of the...

Function of the Notch/Delta Pathway in Ophthalmic Trigeminal Placode Development

Ball, Matthew K.

14 July 2009

The ophthalmic trigeminal placode (opV) is the birth place of one cell type of sensory neurons contributing to the trigeminal ganglion. Signals from the neural tube induce placodal identity within the surface ectoderm. Specified opV placode cells then up-regulate neuron differentiation markers and migrate to the ganglion. Several molecular pathways have been shown to act in opV placode cell development. Despite this, signals that specify individual neurons from within the opV placode remain unknown. However, it is known that components of the Notch signaling pathway are expressed in the opV placode. I tested the role of Notch signaling in opV placode development by separately inhibiting and over-activating the pathway. Using DAPT, an inhibitor of gamma-secretase, I inhibited Notch signaling in 13-15 somite stage chick embryo heads. Attenuated Notch signaling caused increased neuronal differentiation of opV cells at 13-15 somites. I also observed an increase in migratory opV placode (Pax3+) cells in the mesenchyme and expression of neuronal marker Islet1 in the ectoderm. Further, I activated Notch signaling by misexpressing the Notch intracellular domain (NICD) by in ovo electroporation of 10-12 somite stage chick embryos. This resulted in Pax3+ targeted cells failing to differentiate and remain instead in the ectoderm. Thus, Notch/Delta signaling plays an important role in selecting ophthalmic trigeminal cells to differentiate and migrate to the trigeminal ganglion.

ophthalmic

trigeminal

placode

Notch

Delta

Pax3

Islet1

DAPT

NICD

neuron

sensory

chick

opV

mmV

Cell and Developmental Biology

Physiology

Regulation of Sensory Neurogenesis in the Trigeminal Placode: Notch Pathway Genes, Pax3 Isoforms, and Wnt Ligands

Adams, Jason Samuel

02 November 2012

This dissertation is divided into three chapters, each discussing the study of different regulatory molecules involved in sensory neurogenesis occurring in the trigeminal placode. Chapter one is a spatiotemporal description of Notch pathway genes in chick opV placode by stage-specific expression analysis, showing expression of many Notch pathway genes and effectors in the opV placode. Notch pathway gene expression is primarily confined to the ectoderm with highest expression of these genes at the beginning stages of peak neuronal differentiation. This information preceded studies of the functional roles that Notch signaling has in the opV placode and how it may affect the transcription factor, Pax3. Chapter two is a study of the transcription factor Pax3 and its role in opV placode development and sensory neuron differentiation. Pax3 is known to activate or repress gene transcription, and its activity may be dependent on the splice variant or isoform present. We show through RT-PCR that alternative splice forms of Pax3 are present at stages of chick development corresponding to cellular competence, cellular differentiation and ingression, and cellular aggregation. We have named these splice forms, Pax3V1 and Pax3V2. Using quantitative RT-PCR we show that Pax3V2 is consistently expressed at lower levels compared to Pax3 during cellular competence and differentiation. In order to determine the function of the three splice forms, we misexpressed them in the opV placode and analyzed the effect on neurogenesis. We looked at markers for neuronal differentiation of targeted cells after in ovo electroporation of Pax3, Pax3V1, and Pax3V2, which showed a significant difference between the control and each construct, but not between the groups of constructs. To enhance the process of neurogenesis we exposed the electroporated embryos to DAPT, a Notch signaling inhibitor that enhances sensory neurogenesis. Using this method we found that misexpression of Pax3 and Pax3V1 resulted in cells failing to differentiate, while Pax3V2 misexpression more closely resembles the neuronal differentiation seen in controls. These results show that the Pax3V2 isoform allows for neuronal differentiation of opV placodal cells after misexpression, while the Pax3 isoform and the Pax3V1 isoform block neuronal differentiation. Chapter three is a study of the necessity of Wnt signaling originating from the neural tube to induce Pax3 expression in the opV placode. A double knockout of Wnt1 and Wnt3a was produced to determine the necessity of these genes in opV placode development. Pax3 expression in the opV placode at E8.5 and E9.5 was markedly reduced in the double mutants when compared to wild type mice. This study shows that Wnt1 and Wnt3a genes are necessary for normal Pax3 expression, but that other signals may contribute to its induction.

sensory neurogenesis

Notch signaling

Pax3

splice forms

isoforms

alternative splicing

ophthalmic trigeminal placode

Wnt signaling

Cell and Developmental Biology

Physiology

The developmental and evolutionary roles of isoforms of regulator of G protein signalling 3 in neuronal differentiation

Fleenor, Stephen

January 2014

Fundamental to the complexity of the nervous system is the precise regulation in space and time of the production, maturation, and migration of neurons in the developing embryo. This is eloquently seen in the forming cranial sensory ganglia (CSG) of the peripheral nervous system. Placodes, which are transient pseudostratified neuroepithelia in the surface ectoderm of the embryo, are responsible for generating most of the neurons of the CSG. Placodal progenitors commit to the neuronal fate and delaminate from the epithelium as immature, multipolar neuroblasts. These neuroblasts reside in a staging area immediately outside the placode. Differentiation of the neuroblasts is intimately coupled to their adoption of a bipolar morphology and migration away from the staging area to the future site of the CSG. Thus the forming CSG is a highly tractable model to anatomically separate the three phases of a neuroblast’s lifetime: from neuroepithelial progenitor (in the placode), to immature neuroblast (in the staging area), to mature neuron (in the migratory stream). In this thesis, I used the forming CSG as a model to investigate the role of Regulator of G protein Signalling 3 (RGS3) in neuroblast commitment and differentiation. Promoters within introns of the RGS3 locus generate isoforms in which N-terminal sequences are sequentially truncated, but C-terminal sequences are preserved. Intriguingly, I found that expression of these isoforms in the forming CSG is temporally co-linear with their genomic orientation: longer isoforms are exclusively expressed in the progenitor placode; a medium isoform is expressed exclusively in the neuroblast staging area; and the shortest isoforms are expressed in the neuronal migratory stream. Furthermore, through loss- and gain-of-function experiments, I demonstrated that each of these isoforms plays a specific role in the differentiation state in which it is expressed: placode-expressed isoforms negatively regulate neurogenesis; the neuroblast-expressed isoform negatively regulates differentiation; and the neuron-expressed isoforms negatively regulate neuronal migration. The negative regulatory role which all isoforms play in different cell-biological contexts is intriguing in light of the fact that they all share a C-terminal RGS domain, which canonically negatively regulates G protein signalling. Through domain mutation and deletion, I showed that the RGS and N-terminal domains are important for the function of each isoform. Thus temporally co-linear expression within the RGS3 locus generates later-expressed isoforms which lack the regulatory N-terminal domains of the earlier-expressed isoforms, giving them new license to perform different biochemical functions. Lastly, I investigated the conservation and evolution of RGS3 and its isoforms. RGS3 was found to be present in all extant metazoans, and results from this thesis implicate it as the founding member of the R4 subfamily of RGS proteins. Furthermore, in the early vertebrate lineage, a critical domain was lost. This is intriguing in light of the fact that placodes in their stereotypic forms also emerged early in the vertebrate lineage. Ectopic overexpression of the full-length invertebrate RGS3 protein prevented pseudostratification of the vertebrate placode, suggesting that the domain loss in the early vertebrate lineage was important for the evolution of pseudostratified placodes and the expansion of the vertebrate nervous system. In summary, the work in this thesis has uncovered a previously unseen model of transcriptional regulation of a single locus: intragenic temporal co-linearity. Furthermore, the demonstrated functions of this regulation have profound implications on the generation and differentiation of vertebrate neurons, as well as the evolution of the vertebrate nervous system.

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