Role 1 integrins in epidermal developments and homeostasis

Hutter, Caroline

January 2002

No description available.

611

Tissue morphogenesis

Regulation of the versican gene : implications for vascular health and disease

Rahmani, Maziar

05 1900

Versican, a chondroitin sulfate proteoglycan, is one of the main components of the extracellular matrix and hence plays a central role in tissue morphogenesis and a number of pathologic processes. My main goal has been to investigate the mechanisms of versican gene regulation, focusing on the signal transduction pathways, promoter regions, cis-acting elements, and trans- factors. This thesis puts forth new knowledge regarding transcriptional regulation of the human versican gene. In chapter III, I present the cloning of a 752-bp fragment of the human versican promoter (- 634/+118 bp) and nine stepwise 5' deletion fragments in the PGL3-luciferase reporter plasmid. Furthermore, I identify three potential enhancer and two repressor regions in this promoter. I also demonstrate that both cAMP and C/EBPβ enhanced and repressed versican transcription in HeLa cells and rat aortic smooth muscle cells (SMC), respectively, suggesting that versican transcription is differentially regulated by the respective mediator and transcription factor in epithelial cells and SMC. In chapter IV, I reveal the role of PI3K/PKB/GSK-3β signaling pathway in regulating versican promoter activity and transcription. Furthermore, I identify that the β-catenin/TCF-4 transcription factor complex, one of the downstream targets of GSK-3β, mediates versican promoter activity and transcription. In chapter V, I identify that variations in C-terminal regions of TCF family members determine their repressor or enhancer properties on Wnt target genes. Furthermore, I show that curcumin is a strong inhibitor of the β-catenin/TCF-p300 mediated gene expression. In chapter VI, I demonstrate that the androgen receptor trans-activates versican transcription in prostate cancer cells. Furthermore, I show cross-talk between the androgen receptor and β-catenin in regulating versican transcription in prostate stromal fibroblasts. Overall, this study charts previously uncharacterized promoter elements, transcription factors, and signal transduction pathways involved in regulation of the versican gene.

Versican

Genetics

Tissue morphogenesis

Regulation of the versican gene : implications for vascular health and disease

Rahmani, Maziar

05 1900

Versican, a chondroitin sulfate proteoglycan, is one of the main components of the extracellular matrix and hence plays a central role in tissue morphogenesis and a number of pathologic processes. My main goal has been to investigate the mechanisms of versican gene regulation, focusing on the signal transduction pathways, promoter regions, cis-acting elements, and trans- factors. This thesis puts forth new knowledge regarding transcriptional regulation of the human versican gene. In chapter III, I present the cloning of a 752-bp fragment of the human versican promoter (- 634/+118 bp) and nine stepwise 5' deletion fragments in the PGL3-luciferase reporter plasmid. Furthermore, I identify three potential enhancer and two repressor regions in this promoter. I also demonstrate that both cAMP and C/EBPβ enhanced and repressed versican transcription in HeLa cells and rat aortic smooth muscle cells (SMC), respectively, suggesting that versican transcription is differentially regulated by the respective mediator and transcription factor in epithelial cells and SMC. In chapter IV, I reveal the role of PI3K/PKB/GSK-3β signaling pathway in regulating versican promoter activity and transcription. Furthermore, I identify that the β-catenin/TCF-4 transcription factor complex, one of the downstream targets of GSK-3β, mediates versican promoter activity and transcription. In chapter V, I identify that variations in C-terminal regions of TCF family members determine their repressor or enhancer properties on Wnt target genes. Furthermore, I show that curcumin is a strong inhibitor of the β-catenin/TCF-p300 mediated gene expression. In chapter VI, I demonstrate that the androgen receptor trans-activates versican transcription in prostate cancer cells. Furthermore, I show cross-talk between the androgen receptor and β-catenin in regulating versican transcription in prostate stromal fibroblasts. Overall, this study charts previously uncharacterized promoter elements, transcription factors, and signal transduction pathways involved in regulation of the versican gene.

Versican

Genetics

Tissue morphogenesis

Regulation of the versican gene : implications for vascular health and disease

Rahmani, Maziar

05 1900

Versican, a chondroitin sulfate proteoglycan, is one of the main components of the extracellular matrix and hence plays a central role in tissue morphogenesis and a number of pathologic processes. My main goal has been to investigate the mechanisms of versican gene regulation, focusing on the signal transduction pathways, promoter regions, cis-acting elements, and trans- factors. This thesis puts forth new knowledge regarding transcriptional regulation of the human versican gene. In chapter III, I present the cloning of a 752-bp fragment of the human versican promoter (- 634/+118 bp) and nine stepwise 5' deletion fragments in the PGL3-luciferase reporter plasmid. Furthermore, I identify three potential enhancer and two repressor regions in this promoter. I also demonstrate that both cAMP and C/EBPβ enhanced and repressed versican transcription in HeLa cells and rat aortic smooth muscle cells (SMC), respectively, suggesting that versican transcription is differentially regulated by the respective mediator and transcription factor in epithelial cells and SMC. In chapter IV, I reveal the role of PI3K/PKB/GSK-3β signaling pathway in regulating versican promoter activity and transcription. Furthermore, I identify that the β-catenin/TCF-4 transcription factor complex, one of the downstream targets of GSK-3β, mediates versican promoter activity and transcription. In chapter V, I identify that variations in C-terminal regions of TCF family members determine their repressor or enhancer properties on Wnt target genes. Furthermore, I show that curcumin is a strong inhibitor of the β-catenin/TCF-p300 mediated gene expression. In chapter VI, I demonstrate that the androgen receptor trans-activates versican transcription in prostate cancer cells. Furthermore, I show cross-talk between the androgen receptor and β-catenin in regulating versican transcription in prostate stromal fibroblasts. Overall, this study charts previously uncharacterized promoter elements, transcription factors, and signal transduction pathways involved in regulation of the versican gene. / Medicine, Faculty of / Pathology and Laboratory Medicine, Department of / Graduate

Versican

Genetics

Tissue morphogenesis

Multicellular Biomechanical Simulation of Tissue Morphogenesis / 組織の形態形成過程における多細胞バイオメカニクスシミュレーション

Okuda, Satoru

25 March 2013

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第17557号 / 工博第3716号 / 新制||工||1566(附属図書館) / 30323 / 京都大学大学院工学研究科マイクロエンジニアリング専攻 / (主査)教授 安達 泰治, 教授 楠見 明弘, 准教授 井上 康博, 教授 琵琶 志朗 / 学位規則第4条第1項該当

Multicellular dynamics

tissue morphogenesis

computational biomechanics

developmental biology

500

Multivariate analysis of leaf tissue morphogenesis

Samuel Belteton (3322188)

10 May 2020

Leaf size and shape are strongly influenced by the growth patterns of the epidermal tissue. Pavement cells are the prevalent cell type in the epidermis and during cell expansion they undergo a drastic shape change from a simple polyhedral cells to puzzled-shaped cell. The role of these cell protrusions, more commonly referred to as lobes, remains unknown but their formation has been proposed to help increase the structural integrity of the epidermal tissue. How the symmetry breaking event that initiates a lobe is controlled remains unknown, however pharmacological and genetic disruption of the microtubule system has been shown to interfere not only with lobe initiation but also with lobe expansion. Additionally, the role of microtubules in the pattering of microfibril deposition, the load-bearing structure of the cell wall, makes the microtubule system a good candidate to evaluate its dynamics as a function of shape change. Two main mechanical models for lobe initiation are evaluated here, one where microtubules serve as stable features suppressing local expansion and one where microtubules, similarly to the anisotropic expansion patterning in hypocotyl cells, pro-mote the local anisotropic expansion of the cell resulting in lobe formation. The main method to evaluate these models was through the use of long-term time-lapse image analysis using a plasma-membrane marker for accurate shape change quantification and a microtubule marker to quantify their location, persistence, and density as a function of cell shape change. Using the junctions where three cells come together,cells were sub-divided into segments and the shape of these segments were tracked using a new coordinate system that allowed the detection of new lobes as which can arise from ∼300 deflections. By mapping sub-cellular processes, such as microtubule persistence, to this coordinate system, correlations of microtubule organization and shape change was possible. Additionally, a subset of microtubules bundles that splay across the anticlinal and periclinal walls, perpendicular and parallel to the leaf surface respectively, were identified as marking the location and direction of lobe formation.Disrupting the cell boundary by partially digesting pectin, a main component in the middle lamella, revealed the cell-autonomous morphogenesis mechanism in pavementcells. Under pectinase treatment, cell invaginations were produced and similarly to lobes their initiation was microtubule and cellulose dependent. Lastly, stress prediction using finite-element models, based from live-cell images, co-localized regions of high cell wall stress with both microtubule persistence and shape shape locations in both lobing and invaginated segments. Together, a model of cellular shape change is presented where microtubules translate cell wall stresses to tissue morphogenesis.

Botany

Leaf tissue morphogenesis

Probing Single Cell Gene Expression in Tissue Morphogenesis and Angiogenesis

Wang, Shue

January 2015

The fascinating capability of cellular self-organization during tissue development and repair is a central question in developmental biology and regenerative medicine. Understanding the dynamic morphogenic and regenerative processes of biological tissues will have important implications in biology and medicine. Nevertheless, the elucidation of the cellular self-organization processes is hindered by a lack of effective tools for monitoring the spatiotemporal gene expression distribution and a lack of ability to perturb the self-organization processes in living cells and tissues. Multimodal modularities that allow both single cell perturbation and gene detection are required to enable a new paradigm in the investigation of complex tissue morphogenic processes. To address this critical challenge in the field of developmental and regenerative medicine, we are developing a multimodal gold nanorod-locked nucleic acid (GNR-LNA) composite for single cell gene expression analysis in living cells and tissues at the transcriptional level. Using antisense RNA sequences, we design LNA probes for detecting specific molecular targets in living cells. The LNA probes bind to the GNR spontaneously due to the intrinsic affinity between the GNR and LNA. In close proximity, the fluorescent probes are effectively quenched by the GNR. Therefore, a fluorescent signal is only observed when the specific target thermodynamically displaces the LNA probe from the GNR. Furthermore, the GNR also serves as a transducer for photothermal ablation. Thus, we established a novel modularity for imaging the spatiotemporal gene expression distribution in living cells and tissues. The single cell analysis capability of our techniques enables us to adopt a unique approach to study the tissue regenerative processes during normal development and diseases, and this will have a profound impact on regenerative medicine and disease treatment in future. Moreover, we applied this GNR-LNA probe to explore the endothelial cell mRNA dynamics during capillary morphogenesis. Three different types of cells were identified due to their different roles during endothelial cell capillary-like formation process. Our findings indicated that the endothelial cell behavior is directly related to the Dll4 mRNA expression, and Dll4 expression in ECs determine the cell fate. Our GNR-LNA probe enable us to investigate the correlations between Dll4 mRNA expression and cell behavior during capillary morphogenesis. Experimental results indicated that: (1) When the endothelial cells aggregate, the cells migrate with certain displacement, the Dll4 mRNA expression decreases. (2) When the endothelial cells sprout, the cells migrate with small displacement but the cell shape changes to an ellipse shape, the Dll4 mRNA expression begin to increase. (3) When the endothelial cells elongate and form cell-cell contract with adjacent cells, the Dll4 expression decreased to a certain level and keep stable until the cell activity change to another stage. Furthermore, it has been demonstrated endothelial cells compete for the leader cell position during wound healing, collective cell migration, and tip cell formation during angiogenic process. It has been demonstrated that endothelial cells compete for the tip cell formation through Notch signaling pathway. However, how the mechanical force regulates tip cell formation is still unclear, and if mechanoregulation of tip cell formation through Notch pathway still unknown. Mechanical and chemical regulations of tissue morphogenesis and angiogenesis are being investigated in both in vitro capillary-like network formation assay and in vivo mice retina angiogenesis assay. Here, we investigated the mechanoregulation of mechanotransduction of tissue morphogenesis and angiogenesis using both in vitro endothelial cell tube formation model and in vivo mice retina blood vessel development model. Our results demonstrated that (1) Notch pathway negatively regulates tip cell formation: inhibition of Notch pathway (DAPT) enhances tip cell formation, induces Dll4 and Notch1 activity, activation of Notch pathway (Jag1 peptide) inhibits tip cell formation, suppresses Dll4 and Notch1 activity. (2) Mechanical force negatively regulate tip cell formation: (a) Decrease mechanical force via Rho kinase inhibitor Y-27632, myosin II inhibitor Blebbistatin, or laser ablation, enhances tip cell formation and induces Dll4 activity through mediation of Dll4-Notch1 lateral inhibition, (b) increase mechanical force via traction force inducer Nocodazole and Calyculin A, suppresses tip cell formation and inhibits Dll4 activity through activation of Notch pathway. (3) Mechanical force negatively regulates tip cell formation partially via mediation of Notch pathway. Mechanical force is necessary for tip cell formation and negatively regulate tip/stalk selection via Dll4-Notch1 lateral inhibition. Interruption of mechanical force enhance tip cell formation via suppression of Dll4-Notch1 lateral inhibition, thus resulting the increase of Dll4 expression. Enhance of mechanical force inhibits tip cell formation via activation of Dll4-Notch1 lateral inhibition, thus resulting the decreases of Dll4 expression. All these finding wills have great significance for various biomedical applications, such as tissue engineering, cancer, and drug screening.

gene expression

gold nanoparticles

molecular probe

Single cell analysis

Tissue morphogenesis

Mechanical Engineering

Angiogenesis

Applying optical tweezers in vivo : A biophysical study of mechanical forces in Drosophila Melanogaster at the onset of gastrulation

Bambardekar, Kapil

20 January 2015

Nous avons développé un dispositif combinant pinces optiques et imagerie par feuillet de lumière. Nous montrons que les interfaces cellulaires de l'épithélium précoce de l'embryon de Drosophile peuvent être piégées et manipulées directement avec des pinces optiques. La manipulation optique est réalisée à la fin de la cellularisation, processus par lequel des membranes cellulaires séparent les noyaux pour donner naissance à un épithélium ; à ce stade, les mouvements cellulaires sont minimes et les cellules ont des formes hexagonales similaires. En imposant un mouvement sinusoïdal au piège perpendiculairement à une interface, nous étudions la déflection de l'interface en fonction de la puissance laser, de l'amplitude du mouvement du piège et de la fréquence d'oscillation. En outre, des expériences de déflection-relaxation par déplacement instantané puis arrêt du piégeage, ont été réalisées, fournissant une alternative à l'analyse fréquentielle pour étudier les propriétés viscoélastiques de l'interface. Un modèle de type solide linéaire standard rend compte des observations et permet d'extraire les paramètres viscoélastiques de l'interface. Nous mettons également en évidence que la déflection imposée à une interface se propage aux interfaces voisines en s'affaiblissant exponentiellement sur une distance d'une à deux cellules. Cette technique étant établie, nous l'utilisons pour mesurer les tensions durant l'extension de la bandelette germinale. Les tensions sont anisotropes, les jonctions parallèles à la direction dorsoventrale ayant une tension trois fois plus élevée que celles perpendiculaires. Ce travail fournit des mesures absolues des tensions intercellulaire. / Here, an optical tweezers setup was developed on a pre-existing single-plane illumination (SPIM) setup. The cell-cell interface in embryonic epithelia could be trapped and manipulated directly with optical tweezers. The interaction of the interface with the trap was initially characterized at the end of cellularization where the tissue has minimal movements and actomyosin turnover. With a sinusoidal trap excursion, the interface amplitude was found to increase linearly with applied laser power as well as trap amplitude and time period. Furthermore, push and pull experiments on the interface responding to a stationary trap, provided another way to address the viscoelastic properties of the interface. The interface kinetics in stationary experiments could fit adequately to a passive viscoelastic model. This model also explained well the linear response to trap amplitude and time period, and formed the basis of estimating interface tension from its amplitude. Moreover, the propagation of the sinusoidal movement to neighbouring interfaces decayed rapidly with minimal phase lag in both experiments and the model. Having established a suitable regime of trapping conditions, where interface deflection is small and linear, the mechanical anisotropy of the epithelium was at the onset of gastrulation. The interface tension increased by 2-3 fold, exhibiting both apico-basal and dorso-ventral polarization of tension, concomitant with polarized accumulation of myosin. The role of myosin was established further through ROCK-inhibition. Perturbation of actin also decreased the interface tension. My work provides a crucial insight into the mechanical behaviour of dynamic epithelia.

Biophysique

Optical pincers

Tissu morphogenese

La physique cellulaire

Biophysics

Optical tweezers

Tissue morphogenesis

Cell physics

530

Spatio-temporal and quantitative control of Rho1 activity by GPCR signaling during tissue morphogenesis / Contrôle spatio-temporel et quantitatif de l'activité Rho1 par une signalisation GPCR

Garcia De Las Bayonas, Alain

14 December 2018

La constriction apicale des cellules du mésoderme et l'intercalation des cellules de l'ectoderme sont contrôlées par des réseaux contractiles d'acto-myosine dans l'embryon de Drosophile. Le niveau d'activation et la polarisation du cytosquelette d'acto-myosine détermine la nature des déformations cellulaires observées. Nous montrons que le GPCR Smog et les protéines G (Gα,Gβγ) en aval, activent la signalisation Rho1 et donc la Myosine-II dans les deux tissus. Dans l'ectoderme, Gα12/13 active Rho1 à la membrane apicale (aussi appelé compartiment médio-apical) tandis que les sous-unités Gβ13F-Gγ1 activent Rho1 en médio-apical et aux jonctions cellulaires. Les mécanismes contrôlant l’activation polarisée de Rho1 dans ce tissu demeurent incompris. Nous montrons ici que deux RhoGEFs, RhoGEF2 et une nouvelle RhoGEF Wireless/p114RhoGEF, activent Rho1 sous le contrôle des protéines G dans l’ectoderme. RhoGEF2 stimule Rho1 en médio-apical sous la dépendance de Gα12/13 alors que Wireless/p114RhoGEF contrôle l’activité de Rho1 aux jonctions avec Gβ13F-Gγ1. RhoGEF2 est présente aux jonctions et en médio-apical tandis que Wireless/p114RhoGEF est uniquement jonctionnelle où elle est recrutée par Gβ13F-Gγ1. Pour finir, Wireless/p114RhoGEF est absente des jonctions dans les cellules du mésoderme. En résumé, des GPCRs contrôlent l’activité spatio-temporelle de Rho1 au moyen de deux modules régulatoires dans l’ectoderme. Les protéines G transduisent le signal en recrutant et en activant deux RhoGEFs complémentaires en médio-apical et aux jonctions. Une variation dans la nature des GPCRs, protéines G ou des RhoGEFs détermine le contrôle tissu-spécifique de Rho1 au cours de la morphogenèse. / Cell apical constriction in the mesoderm and cell intercalation in the ectoderm are controlled by contractile actomyosin networks in the developing Drosophila embryo. The extent of both actomyosin activation and polarization determines the nature of these cell deformations. We find that the GPCR Smog and the downstream G proteins (Gα,Gβγ) activate Rho1 signaling and thereby myosin-II in both tissues. In the ectoderm, Gα12/13 activates Rho1 at the apical membrane (also called medial-apical compartment) while Gβ13F-Gγ1 subunits promote Rho1 activity at the apical membrane and at cell junctions. How such a polarized activation of Rho1 is achieved remains unclear. Here, we show that two RhoGEFs, RhoGEF2 and a previously uncharacterized RhoGEF Wireless/p114RhoGEF, control Rho1 activity downstream of G proteins in the ectoderm. RhoGEF2 activates medial-apical Rho1 under control of Gα12/13 and Wireless/p114RhoGEF is required to mediate Gβ13F-Gγ1-dependent activation of Rho1 at junctions. RhoGEF2 is present both at junctions and at the apical membrane. In contrast, Wireless/p114RhoGEF only localizes at junctions together with Gβ13F-Gγ1 which recruit the GEF. Finally, we show that Wireless/p114RhoGEF is absent from junctions in the mesoderm. Collectively, GPCRs shape Rho1 activity through distinct biochemical modules in the ectoderm. Heterotrimeric G proteins transduce the signal by recruiting and activating two complementary RhoGEFs apically and at junctions. Variation in type of GPCRs, G proteins or RhoGEFs underlie the tissue-specific control of Rho1 signaling during morphogenesis.

Morphogenèse tissulaire

Gpcr

Signalisation Rho1

RhoGEF

Tissue morphogenesis

Gpcr

Rho1 signaling

RhoGEF

571

Regulation of a bio-mechanical network driving shape changes during tissue morphogenesis / Régulation d'un réseau biomécanique entraînant des changements de forme lors de morphogenese des tissus

Munjal, Akankshi

22 September 2015

Forces requises pour les changements de forme au cours de la morphogenèse des tissus sont générés par d’actine et de myosine. Durant ma thèse, je étudié le rôle de la réglementation MyoII par la voie Rho1-Rok durant l’élongation de l’ectoderme ventro-latéral par intercalation cellulaire. Les pulsations de MyoII médio-apicale se déplacent de manière anisotrope vers les jonctions parallèles avec l’axe dorso-ventral (ou jonctions verticales). Ceci provoque le rétrécissement graduel des jonctions qui sont stabilisées par une population de MyoII 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 myosine II restent à élucider. J’ai identifié deux propriétés cruciales de la dynamique de la myosine II régie par phospho- à savoir la cinétique d’échange gouvernée par les cycles de phosphorylation-déphosphorylation des chaines légères régulatrices de la MyoII (RLC) et l’advection due à la contraction des moteurs sur le réseau de F-actine. Contrôle spatial sur le chiffre d'affaires MyoII établit 2 régimes stables des taux élevés et faibles dissociation résultant dans MyoII polarité. Pulsatilité est un comportement auto-organisé qui émerge à taux de dissociation intermédiaires permettant d'advection MyoII et les régulateurs en amont. Dans la deuxième partie de ma thèse, je l'ai montré que la protéine GPCR- GRsmog et la brume, et la voie G-protéines en aval permettent l'activation progressive des MyoII, établissant pulsatilité et de la stabilité pour produire des déformations de forme polarisées cours de la morphogenèse. / Forces required to power shape changes during tissue morphogenesis are generated by non-muscle MyosinII (MyoII) pulling filamentous actin. During my PhD, I investigated the role of MyoII regulation through the conserved Rho1-Rok pathway during Drosophila germband extension. The morphogenetic process is powered by cell intercalation involving shrinkage of junctions in the dorsal-ventral axis (‘vertical junctions’) followed by junction extension in the anterior-posterior axis. Advances in light microscopy revealed that the actomyosin networks exhibit pulsed contractions to power junction shrinkage, and alternate with steps of stabilization by MyoII enriched on vertical junctions (planar-polarity) to result in irreversible shape changes. Although described in many different contexts, the underlying mechanisms of this ratchet-like behavior remained unclear. Using genetic and biophysical tools, quantitative imaging and subtle perturbations, I identified 2 critical properties underlying MyoII dynamics- turnover governed by phospho-cycling of the MyoII Regulatory Light Chain, and advection due to contraction of the motors on actin networks. Spatial control over MyoII turnover establishes 2 stable regimes of high and low dissociation rates resulting in MyoII planar polarity. Pulsatility is a self-organized behavior that emerges at intermediate dissociation rates enabling advection of MyoII and upstream regulators. In the second part of my thesis, I showed that G protein coupled receptors- GRsmog and Mist, and the downstream G-protein pathway allow step-wise activation of MyoII, establishing pulsatility and stability, to drive polarized shape deformations during morphogenesis.

Morphogenèse du tissu

Polarité

Gastrulation

Drosophile

Les réseaux de actomyosine

Gpcr

Tissue morphogenesis

Polarity

Gastrulation

Drosophila

Actomyosin networks

Gpcr

570