The Role of the X-chromosomal Porcupine Homolog Gene in Mouse Development

Biechele, Steffen

20 June 2014

WNT ligands are secreted proteins that act as signals between cells. WNTs activate several interconnected signaling pathways that are required for embryonic development as well as tissue homeostasis in adults. The X-chromosomal Porcn gene encodes a membrane-bound O-acyl transferase that is required for the acylation of all 19 WNT ligands encoded in the mammalian genome. Non-acylated WNTs fail to be secreted from the producing cell and thus do not activate downstream signaling targets. In my thesis research, I have investigated the function of Porcn in mouse embryonic development. In vitro, I have shown that Porcn is required for canonical WNT signaling in ES cells and further, for their differentiation into endodermal and mesodermal derivatives. Taking advantage of a mouse line carrying a conditional (floxed) Porcn allele that I have generated, I have focused my studies on the early embryonic roles of Porcn using Cre recombinase-mediated and X chromosome inactivation-based ablation of Porcn function in vivo. I have found that the earliest requirement for Porcn in mouse development is the induction of gastrulation. In contrast to findings from in vitro studies, I have provided evidence that Porcn is not required for pre-implantation development in vivo. Dissecting embryonic and extra- embryonic roles of Porcn, I have been able to show that Porcn is required in the extra-embryonic chorion in order to mediate chorio-allantoic fusion, whereas ablation in the extra-embryonic visceral endoderm had no apparent effects. The extra-embryonic requirement for Porcn results in a parent-of-origin effect in Porcn heterozygous females due to X chromosome inactivation. In contrast to the placentation defect causing embryonic lethality of maternal allele mutants, deletion of the paternal allele caused variable fetal defects resulting in perinatal lethality with only rare survivors to adulthood. Both fetuses and adults represent a mouse model for Focal Dermal Hypoplasia (FDH), the syndrome caused by mutations in the human PORCN gene. My studies highlight the importance of PORCN-mediated WNT signaling for gastrulation, placentation, and fetal development, but suggest that endogenous WNT secretion does not play an essential role in either implantation or blastocyst lineage specification.

Porcn

Wnt

Mouse

Embryogenesis

Gastrulation

Pre-implantation

0369

0379

0472

The Role of the X-chromosomal Porcupine Homolog Gene in Mouse Development

Biechele, Steffen

20 June 2014

WNT ligands are secreted proteins that act as signals between cells. WNTs activate several interconnected signaling pathways that are required for embryonic development as well as tissue homeostasis in adults. The X-chromosomal Porcn gene encodes a membrane-bound O-acyl transferase that is required for the acylation of all 19 WNT ligands encoded in the mammalian genome. Non-acylated WNTs fail to be secreted from the producing cell and thus do not activate downstream signaling targets. In my thesis research, I have investigated the function of Porcn in mouse embryonic development. In vitro, I have shown that Porcn is required for canonical WNT signaling in ES cells and further, for their differentiation into endodermal and mesodermal derivatives. Taking advantage of a mouse line carrying a conditional (floxed) Porcn allele that I have generated, I have focused my studies on the early embryonic roles of Porcn using Cre recombinase-mediated and X chromosome inactivation-based ablation of Porcn function in vivo. I have found that the earliest requirement for Porcn in mouse development is the induction of gastrulation. In contrast to findings from in vitro studies, I have provided evidence that Porcn is not required for pre-implantation development in vivo. Dissecting embryonic and extra- embryonic roles of Porcn, I have been able to show that Porcn is required in the extra-embryonic chorion in order to mediate chorio-allantoic fusion, whereas ablation in the extra-embryonic visceral endoderm had no apparent effects. The extra-embryonic requirement for Porcn results in a parent-of-origin effect in Porcn heterozygous females due to X chromosome inactivation. In contrast to the placentation defect causing embryonic lethality of maternal allele mutants, deletion of the paternal allele caused variable fetal defects resulting in perinatal lethality with only rare survivors to adulthood. Both fetuses and adults represent a mouse model for Focal Dermal Hypoplasia (FDH), the syndrome caused by mutations in the human PORCN gene. My studies highlight the importance of PORCN-mediated WNT signaling for gastrulation, placentation, and fetal development, but suggest that endogenous WNT secretion does not play an essential role in either implantation or blastocyst lineage specification.

Porcn

Wnt

Mouse

Embryogenesis

Gastrulation

Pre-implantation

0369

0379

0472

Building gene regulatory networks in development deploying small GTPases /

Beane, Wendy Scott,

January 2007

Thesis (Ph. D.)--Duke University, 2007. / Includes bibliographical references.

Intercellular Signaling Pathways in the Initiation of Mammalian Forebrain Development

Yang, Yu-Ping,

January 2007

Thesis (Ph. D.)--Duke University, 2007. / Includes bibliographical references.

Gene expression profiling reveals novel attributes of the mouse definitive endoderm

McKnight, Kristen Dawn

05 1900

Gastrulation is one of the most critical events of embryogenesis, generating the three primary germ layers (definitive endoderm, mesoderm, and ectoderm) and establishing the embryonic body plan. The definitive endoderm, which generates the lungs, liver, pancreas, and digestive tract, has become a tissue of particular interest in recent years. Understanding definitive endoderm formation and patterning will greatly aid progress in the in vitro differentiation of embryonic stem cells to definitive endoderm for use in treatment of diseases such as diabetes and hepatitis as an alternative for whole organ replacement. Gene targeting studies have demonstrated a critical role for the Nodal signaling pathway and the forkhead transcription factors Foxh1 and Foxa2 in specification of a group of cells referred to as the anterior primitive streak (APS). However, the transcriptional targets of Foxh1 and/or Foxa2 other than Nodal that regulate specification of this group of cells are currently unknown. Fate mapping and lineage tracing experiments have shown the APS to be the source of the definitive endoderm. However, many questions regarding specification and patterning of the definitive endoderm remain. The study of this tissue has been hampered by the lack of genetic markers specific for the definitive endoderm as many of the current markers, including Cerl, Foxa2, and Sox17, are also expressed in the visceral endoderm, an extraembryonic tissue. To further investigate the role of Foxh1 in specification of the anterior primitive streak and to address the lack of genetic markers for the definitive endoderm we performed expression profiling on post-implantation mouse embryos using Affymetrix™ GeneChips®. From this analysis we identified and characterized a novel marker of the mouse definitive endoderm. Examination of this, and other, novel endoderm markers in Foxh1 and Foxa2 deficient mouse embryos revealed that contrary to current models of definitive endoderm formation, we find some definitive endoderm is formed in these mutants. Specifically, specification of the midgut and hindgut definitive endoderm is largely unaffected, while foregut formation is severely affected. These results suggest that the formation of the midgut and hindgut definitive endoderm populations is independent of the anterior primitive streak and separate from the foregut definitive endoderm. This represents a major insight into the mechanisms regulating endoderm formation and patterning. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Definitive endoderm

Gastrulation

Embryo patterning

Foxh1

Foxa2

Nodal

Investigating The Role Of LBH During Early Embryonic Development In Xenopus Laevis

Weir, Emma

29 October 2019

LBH is a highly conserved protein whose role during vertebrate development is relatively under-studied. In collaboration with the Albertson lab, our lab has previously shown that it is necessary for cranial neural crest cell migration in the zebrafish and in Xenopus laevis. The molecular mechanisms through which it acts are not well understood. In Xenopus, LBH is a maternally deposited protein. As such, studying its role in early development has not been feasible through the morpholino-mediated knockdown techniques that prevent translation of target genes. Recently, a technique for degrading endogenous proteins was developed, called Trim-Away. This was developed in mammalian systems and utilizes the E3 ubiquitin ligase Trim21 in conjunction with an antibody against a protein of interest in order to degrade the protein. In order to observe the effects of a knockdown of LBH during early embryonic development, we sought to modify the technique for use in Xenopus. We injected embryos with mRNA encoding the human form of trim21 along with a monoclonal antibody against LBH that our lab developed (2B8) and tracked degradation of the protein over time, monitoring embryos for any phenotypes arising during early development. Our results demonstrate that Trim-Away can be utilized in Xenopus. LBH depleted embryos display a variety of defects during gastrulation, the process by which the three germ layers are properly organized. These appear to be mainly due to defects in fibronectin fibrillogenesis and mesodermal migration.

LBH

Xenopus

gastrulation

Trim-Away

Biotechnology

Cell Biology

Developmental Biology

Twisted Gastrulation, a BMP Antagonist, Exacerbates Podocyte Injury / BMPアンタゴニストTwisted Gastrulationはpodocyte障害を増悪させる

Yamada, Sachiko

25 March 2019

京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13234号 / 論医博第2174号 / 新制||医||1036(附属図書館) / 京都大学大学院医学研究科内科系専攻 / (主査)教授 長船 健二, 教授 瀬原 淳子, 教授 小川 修 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Twisted Gastrulation

a BMP Antagonist

Exacerbates Podocyte Injury

490

An essential and highly conserved role for Zic3 in left-right patterning, gastrulation and convergent extension morphogenesis

Cast, Ashley E.

January 2010

No description available.

Biology

Zic3

xenopus

convergent extension

gastrulation

left-right patterning

Identification and functional analysis of Zebrafish orthologs of genes

Challa, Anil Kumar

January 2003

No description available.

Zebrafish

Roundabout

Slit

Axon Guidance

Gastrulation

Cell motility

Regulation of Myosin-II activation and planar polarity during epithelial morphogenesis in Drosophila embryo / Etude des méchanismes de régulation de l'activation et de la popularité planaire de la myosin-II au cours de la morphogénèse épithéliale dans l'embryon de drosophile

Paduano, Vanessa

14 December 2015

Les épithéliums jouent le rôle de barrière physique et chimique chez les Métazoires. Les épithéliums subissent des remodelages pendant l’embryogénèse. La morphogénèse des tissus est dirigée par des déformations cellulaires coordonnées fonctionnant grâce à des réseaux contractiles intracellulaires constitués d’actine et de myosine. Ce réseau d’actomyosine peut être soit pulsatile, soit stable. Un exemple est l’élongation de l’ectoderme ventro-latéral par intercalation cellulaire, le long de l’axe antéro-postérieur (AP) de l’embryon de la Drosophile. Les jonctions parallèles à l’axe dorso-ventral (DV) rétrécissent et forment de manière irréversible de nouvelles jonctions parallèles à l’axe AP. Des pulsations de myosine-II (Myo-II) médio-apicale se déplacent de manière anisotrope vers les jonctions parallèles à l’axe DV. Ceci provoque le rétrécissement graduel des jonctions, rétrécissement stabilisé par une population de Myo-II polarisée dans le plan du tissu et enrichie au niveau de ces jonctions. Les mécanismes cellulaires qui régulent la pulsatilité, la stabilité et la polarité de la Myo-II restent à élucider. Lors de ma thèse, j’ai identifié de nouveaux effecteurs régulant l’activation et la polarité planaire de la voie Rho1-Rok-Myo-II aux niveaux des jonctions. J'ai d'abord caractérisé le rôle de la kinase Misshapen dans l’activation polarisée de la voie Rho1 au niveau des jonctions. Misshapen agit en aval de la signalisation GPCR afin de favoriser l’activation de Rho1 et contrôle la polarisation de cette activation en transmettant l’information des récepteurs Toll. Puis j'ai identifié Pebble comme la RhoGEF régulant Rho1 et l'accumulation de Myo-II aux jonctions. / Epithelial build up strong mechanical and chemical barriers in Metazoans. Epithelia can be dramatically remodeled during embryogenesis. Tissue morphogenesis is driven by coordinated cellular deformations which are powered by intracellular contractile networks constituting actin and Myosin. Actomyosin networks can either be pulsatile or stable. One example is the elongation of the ventral-lateral ectoderm by cell intercalation, along antero-posterior (AP) axis of Drosophila embryo. Junctions parallel to the dorso-ventral (DV) axis shrink and form new junctions along AP axis. Medial apical Myosin-II (Myo-II) pulses flow anisotropically towards junctions aligned in DV axis, resulting in steps of junction shrinkage which are stabilized by a planar-polarized pool of Myo-II enriched at these junctions. Sequential deformation and stabilization drive irreversible tissue deformations akin to a ratchet. The cellular mechanisms that regulate Myo-II pulsatility, stability and polarity remained to be unfurled. During my PhD, I identified new regulators for Rho1-Rok-Myo-II pathway at junctions, and Myo-II planar polarity. On the one hand, I characterized the function of Misshapen kinase in polarized activation of Rho1 pathway at junctions. Misshapen acts downstream GPCR signaling to enhance Rho1 activation, and controls the polarization of this activation by transducing information from Toll receptors. Also, I identified Pebble as RhoGEF regulating Rho1 at junctions and Myo-II accumulation.

Morphogénèse

Épithélium

Myosine-II

Contractilité

Polarité

Gastrulation

Drosophile

Morphogenesis

Epithelium

Myosin-II

Contractility

Polarity

Gastrulation

Drosophila

571