Cadhérine atypique MUCDHL et maladies inflammatoires chroniques intestinales : implication dans leur pathogénie, l'évolution cancéreuse et la réponse au traitement par les dérivés 5-aminosalicylés / Atypical cadherin MUCDHL and inflammatory bowel diseases : involvement in pathogeny, evolution and response to treatment

Bersuder, Émilie

09 September 2019

Les causes des Maladies Inflammatoire Chroniques Intestinales (MICI) restent mal comprises et il n’existe aucun traitement curatif. L’une des complications possibles des MICI est l’augmentation du risque de cancer colorectal (CCR). La cadhérine atypique MUCDHL pourrait être impliquée dans les MICI. Nous avons étudié le rôle de MUCDHL dans la pathogénie des MICI, ainsi que les mécanismes moléculaires qui restaurent son expression. Nous avons montré que l’expression de MUCDHL est diminuée dans la muqueuse intestinale inflammatoire. De plus, les 5-aminosalicylés, utilisés pour traiter les MICI et prévenir le CCR associé, augmentent son expression en stimulant celle de PPAR-γ et de CDX2 ou en inhibant celle de la β-caténine. Chez les souris Mucdhl -/-, l’absence de MUCDHL accélère et amplifie l’inflammation colique induite par le Dextran Sulfate de Sodium et retarde la réparation muqueuse. Nos données montrent l’implication de MUCDHL dans la physiopathologie des MICI et suggèrent qu’il pourrait constituer une cible thérapeutique d’intérêt. / The pathogenesis of Inflammatory Bowel Diseases (IBD) remains poorly understood and there is currently no curative treatment. In addition, patients with colonic IBD are at increased risk of colorectal cancer (CRC). The atypical cadherin MUCDHL could be involved in IBD. We studied the role of MUCDHL in the pathogenesis of IBD, as well as the molecular mechanisms that restore its expression. We have shown that MUCDHL expression is decreased in the inflammatory intestinal mucosa. In addition, 5-aminosalicylates, used to treat IBD and prevent associated CRC, increase its expression by stimulating PPAR-γ and CDX2 or by inhibiting β-catenin. In Mucdhl -/- mice, the absence of MUCDHL accelerates and amplifies colonic inflammation induced by Dextran Sodium Sulfate and delays mucosal repair. Our data show MUCDHL's involvement in the pathophysiology of IBD and suggest that it could be a therapeutic target of interest.

Cadhérine

MUCDHL

Inflammation

Dérivés 5-aminosalycilés

Cadherin

MUCDHL

Inflammatory Bowel Diseases

Inflammation

5-aminosalicylate derivatives

571.96

616.3

615.7

Rôle de l’organisation du cytosquelette d’actine branché et des adhésions N-cadhérine dans la dynamique des épines dendritiques / Role of branched actin network organization and N-cadherin in dendritic in dendritic spine dynamics

Chazeau, Anael

04 December 2012

Les épines dendritiques sont de petites protrusions post-synaptiques présentant des changements morphologiques corrélés avec la plasticité synaptique. Elles ont pour origine les filopodes dendritiques qui s’élargissent lors du contact avec l’axone. Ces changements morphologiques impliquent une grande variété de molécules dont des protéines associées à l’actine et des protéines d’adhésion. Cependant, comment ces différentes protéines sont coordonnées dans le temps et l’espace est encore largement méconnu. De plus, les techniques de microscopie conventionnelle ne permettent pas d’étudier l’organisation et la dynamique de ces protéines dans les épines dont la taille est proche de la limite de resolution. L’objectif de ma thèse a donc été d’explorer le rôle des protéines associées à l’actine ainsi que celui des protéines d’adhésion N-cadhérines dans l’organisation et la dynamique du cytosquelette d’actine des épines dendritiques. Dans une première étude, nous avons suivi la motilité des filopodes et épines dendritiques de neurones en visualisant l’actine-GFP. Nous avons couplé cette approche avec : 1) une technique de piégeage optique de microsphères recouvertes de N-cadhérines ou des substrats micro-imprimés également recouverts de N-cadhérines afin de contrôler temporellement et spatialement les adhésions cadhérine-cadhérine, 2) la stimulation pharmacologique de la myosine II afin d’induire la contraction F-actine/myosine et 3) l’expression de mutants de N-cadhérine non adhésifs. Nous avons ainsi démontré que la stabilisation des filopodes en épines était dépendante de l’engagement d’un embrayage moléculaire entre les adhésions trans-synaptiques N-cadhérine et le flux rétrograde d’actine généré par les myosines II. Dans une deuxième étude, nous avons utilisé la microscopie super-résolutive (PALM et dSTORM) et le suivi de protéines individuelles (sptPALM) pour étudier l’organisation et la dynamique à l’échelle nanométrique des protéines à l’origine des réseaux d’actine branchés dans les épines. Ainsi, nous avons caractérisé la localisation et la dynamique de l’actine, du complexe Arp2/3, du complexe WAVE, d’IRSp53, de VASP et de Rac-1. Nous avons montré que, contrairement aux structures motiles classiques comme lamellipode, le réseau d’actine branché dans les épines n’ést pas formé aux extrémités protrusives puis incorporé dans un flux rétrograde d’actine. Ce réseau est initié à la PSD puis croît vers l’extérieur afin de générer les protrusions membranaires responsablent des changements morphologiques de l’épine. Nos résultats montrent également qu’un contrôle strict de l’activité de Rac-1 est nécessaire au maintien de la morphologie des épines dendritiques et de l’architecture du réseau d’actine branché. L’ensemble de mon travail souligne l’importance du rôle de l’organisation à l’échelle nanométrique du réseau d’actine branché et des adhésions N-cadhérine dans la dynamique et la formation des épines dendritiques. Ces résultats pourraient avoir un rôle important dans la compréhension des changements morphologiques lors de la plasticité synaptique. / Dendritic spines are tiny post-synaptic protrusions exhibiting changes in morphology correlated with synaptic plasticity. They originate from motile dendritic filopodia, which enlarge after contacting axons. These morphological changes involve a wide number of molecular actors, including actin-binding proteins, and adhesion molecules. However, how these various molecular components are coordinated temporally and spatially to tune changes in spine shape remains unclear. Furthermore, conventional photonic microscopy techniques could not achieved the spatial resolution required to study the dynamic nanoscale organization of these proteins within the micron size dendritic spines. The objective of my Ph.D. was to unravel how actin-binding proteins and N-cadherin adhesion regulate the organization and dynamics of F-actin network in dendritic spines. In a first study, we measured the motility of dendritic filopodia and spines by time lapse imaging of actin-GFP in primary hippocampal neurons. We combined those measurements with: 1) manipulation of N-cadherin coated beads with optical tweezers, or micropatterns to control the timing and location of nascent N-cadherin adhesions, 2) pharmacological stimulation of myosin II to trigger contraction of the F-actin/myosin network and 3) expression of non-adhesive N-cadherin mutants to compete for the interaction between N-cadherin adhesion and F-actin. Using these different approaches we demonstrated that the stabilization of dendritic filopodia into mature spines was dependent on the engagement of a molecular clutch between trans-synaptic N-cadherin adhesions and the myosin driven F-actin flow. In a second study, we used super resolution microscopy (PALM and dSTORM) and single protein tracking (sptPALM) to study the dynamic nanoscale organizations of branched actin networks within dendritic spines. Using these technics, we characterized within dendritic spines, the localization and dynamics of actin, Arp2/3 complex, WAVE complex, IRSp53, VASP and Rac-1. We established that, opposite to classical motile structures such as the lamellipodium, branched F-actin networks in dendritic spines are not formed at the tip of membrane protrusions and incorporated in a retrograde flow. On the contrary, they are growing outwards from the PSD generating membrane protrusions responsible for spine motility. We also show that a thigh control of Rac1 activity is required to maintain dendritic spine morphology and branched actin network organization. Altogether, these studies point out the role of the nanoscale functional organization of F-actin networks and its linkage to adhesion proteins in the regulation of dendritic spine formation and dynamics. These findings may have important implications in the understanding of spine morphology changes driven by synaptic activity.

Épines dendritiques

Protéines régulatrices de l’actine

N-cadherine

PSD

Microscopie super-résolutive

Suivi de protéines individuelles

Dendritic spine

Actin-binding proteins

N-cadherin

PSD

Super resolution microscopy

Single protein tracking

Characterization of p120-catenin, a novel RSK substrate in the Ras/MAPK signalling pathway

Gao, Beichen

04 1900

La voie de signalisation Ras/mitogen-activated protein kinase (Ras/MAPK) occupe un rôle central dans la régulation de différents processus biologiques tels que la croissance, la survie mais aussi la prolifération cellulaire. En réponse à des signaux extracellulaires, cette voie de signalisation mène à l’activation des protéines ERK1/2, impliquées dans l’activation de nombreux substrats cellulaires dont les protéines kinases RSK (p90 ribosomal S6 kinase). Ces protéines kinases sont, entre autres, impliquées dans l’invasion et la migration cellulaire mais les mécanismes responsables de ces phénomènes biologiques restent inconnus à ce jour. Dans mon mémoire, je développe tout d’abord les travaux précédemment réalisés dans notre laboratoire, et identifie la protéine p120-Catenin (p120ctn), un composant majeur des jonctions adhérentes (AJ), comme un nouveau substrat de la voie Ras/MAPK. En utilisant notamment un anticorps phospho-spécificique, nous avons pu démontrer que p120ctn est phosphorylée sur la sérine 320, un nouveau site de phosphorylation, d’une manière dépendante des kinases RSK. D’autre part, nous avons trouvé que la signalisation Ras/MAPK réduit l’interaction entre les protéines p120ctn et N-cadhérine. Ainsi, nos observations suggèrent que l’activation de la voie Ras/MAPK est impliquée dans la diminution de l’adhérence entre cellules par la déstabilisation des AJ. Compte tenu du rôle primordial de la voie de signalisation Ras/MAPK dans le cancer, ce mécanisme nouvellement décrit pourrait contribuer à l’avancement des connaissances sur le développement des cancers dépendents de cette voie de signalisation. / The Ras/MAPK (mitogen-activated protein kinase) signalling pathway is vital in regulating cell growth, survival and proliferation in response to extracellular signals. Positioned downstream in the pathway, the p90 ribosomal S6 kinase (RSK) family regulates cell invasion by weakening cell-cell adhesion, but the mechanisms involved remain elusive. In this thesis, I expand upon previous work performed in our lab and identify p120ctn, a major component of adherens junctions (AJ), as a new substrate of the Ras/MAPK pathway. Using a phospho-specific antibody, we demonstrate that p120ctn is phosphorylated on a new phosphorylation site on S320 upon activation of MAPK signalling in a RSK-dependent manner. Furthermore, we show that Ras/MAPK signaling reduces p120ctn binding to N-cadherin, suggesting a new mechanism by which MAPK activity decreases cell-cell adhesion by destabilizing AJs. Finally, we designed and optimized two individual assays to be used in future experiments examining the effects of Ras/MAPK signalling on AJ function. Taken together, our data identifies RSK as a regulator of p120ctn phosphorylation, and also implicates Ras/MAPK signalling in regulating cell-cell adhesion by destabilizing AJ through p120ctn. Given the role of Ras/MAPK signalling in cancer, this new mechanism may play a role in the development and progression of Ras-driven cancers.

MAPK

RSK

p120ctn

jonctions adhérentes

cadhérine

phosphorylation

adhérence cellule-cellule

adherens junction

cadherin

phosphorylation

cell-cell adhesion

Investigating spatial distribution and dynamics of membrane proteins in polymer-tethered lipid bilayer systems using single molecule-sensitive imaging techniques

Ge, Yifan

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Plasma membranes are complex supramolecular assemblies comprised of lipids and membrane proteins. Both types of membrane constituents are organized in highly dynamic patches with profound impact on membrane functionality, illustrating the functional importance of plasma membrane fluidity. Exemplary, dynamic processes of membrane protein oligomerization and distribution are of physiological and pathological importance. However, due to the complexity of the plasma membrane, the underlying regulatory mechanisms of membrane protein organization and distribution remain elusive. To address this shortcoming, in this thesis work, different mechanisms of dynamic membrane protein assembly and distribution are examined in a polymer-tethered lipid bilayer system using comple-mentary confocal optical detection techniques, including 2D confocal imaging and single molecule-sensitive confocal fluorescence intensity analysis methods [fluorescence correlation spectroscopy (FCS) autocorrelation analysis and photon counting histogram (PCH) method]. Specifically, this complementary methodology was applied to investigate mechanisms of membrane protein assembly and distribution, which are of significance in the areas of membrane biophysics and cellular mechanics. From the membrane biophysics perspective, the role of lipid heterogeneities in the distribution and function of membrane proteins in the plasma membrane has been a long-standing problem. One of the most well-known membrane heterogeneities are known as lipid rafts, which are domains enriched in sphingolipids and cholesterol (CHOL). A hallmark of lipid rafts is that they are important regulators of membrane protein distribution and function in the plasma membrane. Unfortunately, progress in deciphering the mechanisms of raft-mediated regulation of membrane protein distribution has been sluggish, largely due to the small size and transient nature of raft domains in cellular membranes. To overcome this challenge, the current thesis explored the distribution and oligomerization of membrane proteins in raft-mimicking lipid mixtures, which form stable coexisting CHOL-enriched and CHOL-deficient lipid domains of micron-size, which can easily be visualized using optical microscopy techniques. In particular, model membrane experiments were designed, which provided insight into the role of membrane CHOL level versus binding of native ligands on the oligomerization state and distribution of GPI-anchored urokinase plasminogen activator receptor (uPAR) and the transmembrane protein αvβ3 integrin. Experiments on uPAR showed that receptor oligomerization and raft sequestration are predominantly influenced by the binding of natural ligands, but are largely independent of CHOL level changes. In contrast, through a presumably different mechanism, the sequestration of αvβ3 integrin in raft-mimicking lipid mixtures is dependent on both ligand binding and CHOL content changes without altering protein oligomerization state. In addition, the significance of membrane-embedded ligands as regulators of integrin sequestration in raft-mimicking lipid mixtures was explored. One set of experiments showed that ganglioside GM3 induces dimerization of α5β1 integrins in a CHOL-free lipid bilayer, while addition of CHOL suppresses such a dimerization process. Furthermore, GM3 was found to recruit α5β1 integrin into CHOL-enriched domains, illustrating the potential sig-nificance of GM3 as a membrane-associated ligand of α5β1 integrin. Similarly, uPAR was observed to form complexes with αvβ3 integrin in a CHOL dependent manner, thereby causing the translocation of the complex into CHOL-enriched domains. Moreover, using a newly developed dual color FCS and PCH assay, the composition of uPAR and integrin within complexes was determined for the first time. From the perspective of cell mechanics, the characterization of the dynamic assembly of membrane proteins during formation of cell adhesions represents an important scientific problem. Cell adhesions play an important role as force transducers of cellular contractile forces. They may be formed between cell and extracellular matrix, through integrin-based focal adhesions, as well as between different cells, through cadherin-based adherens junctions (AJs). Importantly, both types of cell adhesions act as sensitive force sensors, which change their size and shape in response to external mechanical signals. Traditionally, the correlation between adhesion linker assembly and external mechanical cues was investigated by employing polymeric substrates of adjustable substrate stiffness containing covalently attached linkers. Such systems are well suited to mimic the mechanosensitive assembly of focal adhesions (FAs), but fail to replicate the rich dynamics of cell-cell linkages, such as treadmilling of adherens junctions, during cellular force sensing. To overcome this limitation, the 2D confocal imaging methodology was applied to investigate the dynamic assembly of N-cadherin-chimera on the surface of a polymer-tethered lipid multi-bilayer in the presence of plated cells. Here, the N-cadherin chimera-functionalized polymer-tethered lipid bilayer acts as a cell surface-mimicking cell substrate, which: (i) allows the adjustment of substrate stiffness by changing the degree of bilayer stacking and (ii) enables the free assembly of N-cadherin chimera linkers into clusters underneath migrating cells, thereby forming highly dynamic cell-substrate linkages with remarkable parallels to adherens junctions. By applying the confocal methodology, the dynamic assembly of dye-labeled N-cadherin chimera into clusters was monitored underneath adhered cells. Moreover, the long-range mobility of N-cadherin chimera clusters was analyzed by tracking the cluster positions over time using a MATLAB-based multiple-particle tracking method. Disruption of the cytoskeleton organization of plated cells confirmed the disassembly of N-cadherin chimera clusters, emphasizing the important role of the cytoskeleton of migrating cells during formation of cadherin-based cell-substrate linkages. Size and dynamics of N-cadherin chimera clusters were also analyzed as a function of substrate stiffness.

membrane protein

membrane biophysics

polymer-tethered lipid bilayer

integrin

cadherin

urokinase plasminogen activator receptor

confocal microscope

single molecule detection

cell mechanosensation

Interleukin-6 as a Potential Mediator of Breast Cancer Progression and Non-Melanoma Skin Carcinogenesis

Sullivan, Nicholas James

11 September 2009

No description available.

Biomedical Research

Immunology

Molecular Biology

Oncology

interleukin-6

IL-6

breast cancer

epithelial-mesenchymal transition

EMT

E-cadherin

STAT3

non-melanoma skin cancer

UV

myeloid-derived suppressor cells

MDSC

Expression of Selected Cadherins in Adult Zebrafish Visual System and Regenerating Retina, and Microarray Analysis of Gene Expression in Protocadherin-17 Morphants

Marlowe, Alicja

28 July 2022

No description available.

Biology

Bioinformatics

Anatomy and Physiology

Developmental Biology

Molecular Biology

molecular biology

neurobiology

anatomy

gene expression

microarray

cadherin

protocadherin

transcription factor

zebrafish

visual system

retina

regeneration

CNS

development

computational biology

Cell Death Mechanisms at the Endoplasmic Reticulum

Geng, Fei

04 1900

<p>In the recent years considerable progress has been made to understand how the protein Bcl-2 regulates apoptosis at the mitochondria. By comparison, the cell death mechanisms at the endoplasmic reticulum remain unclear. In response to the agents that cause endoplasmic reticulum stress in breast cancer cells, the cell-cell adhesion molecule E-cadherin is modified by two independent modifications comprising pro-region retention and O-glycosylation. Both the modifications on E-cadherin inhibit its cell surface transport and the resultant loss of E-cadherin on the plasma membrane sensitizes cells to apoptosis. During this process binding of E-cadherin to type I gamma phosphatidylinositol phosphate kinase (PIPKIγ), a protein required for E-cadherin trafficking to the plasma membrane is prevented by O-glycosylation. E-cadherin deletion mutants that cannot be O-GlcNAcylated continue to bind PIPKIγ, traffick to the cell surface and delay apoptosis, confirming the biological significance of the modifications and PIPKIγ binding in the cell death regulation. These results also led me to determine whether there is a cell death pathway in which commitment to cell death is mediated by proteins primarily located at the endoplasmic reticulum. The studies show that the growth of estrogen receptor-positive breast cancer cells in charcoal stripped bovine serum leads to a form of programmed cell death which is protected by Bcl-2 exclusively localized at the endoplasmic reticulum instead of the mitochondria. Interestingly, the BH3 mimetic ABT-737 can abolish the protection mediated by Bcl-2 localized at the endoplasmic reticulum. Taken together, these studies suggest the novel role of the endoplasmic reticulum in programmed cell death through the identification and elucidation of the mechanisms that regulate the cell death pathway at this organelle.</p> / Doctor of Philosophy (PhD)

Endoplasmic reticulum

Cell death

Bcl-2

E-cadherin

Modification

O-glycosylation

Cancer Biology

Cell and Developmental Biology

Cell Biology

Life Sciences

Cancer Biology

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin

31 August 2006

The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.

Planar cell polarity

junctional remodeling

E-cadherin

hexagonal

epithelial packing

Drosophila

exocyst

Sec5

Flamingo

recycling

Dynamin

Rab11

wing hairs

Planare Polarität

hexagonal

E-cadherin

Drosophila

Exocyst

Sec5

Flamingo

Recycling

Dynamin

Rab11

Flügelhaare

ddc:570

rvk:WG 5900

Drosophila

Polarität

Recycling

Dynamin

Flügel&amp;lt;Zoologie&amp;gt;

Cadherine

Exocytose

Ephitelzelle

Molecular and cellular Mechanisms controlling Primordial Germ Cell Migration in Zebrafish / Molekulare und zelluläre Mechanismen, welche die Primordiale Keimzell-Migration im Zebrafisch kontrollieren.

Blaser, Heiko

24 May 2006

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

primoridale Keimzelle

Zebrafisch

sdf

cxcr4

EMT

Kalzium

Migration

Chemotaxis

E-cadherin

Transition

Myosin

Kinase

PGC

zebrafish

sdf

cxcr4

EMT

calcium

migration

chemotaxis

E-cadherin

transition

myosin

kinase

42.00

42.13

42.15

42.20

42.23

42.80

WF 200: Molekularbiologie

WF 400: Gentechnologie

WJL 000: Molekulargenetik {Biologie}

WK 000: Entwicklungsbiologie

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin

25 July 2006

The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.

info:eu-repo/classification/ddc/570

ddc:570