La protéine kinase D1, PKD1, un acteur essentiel de la physiologie du mélanome et une cible de perturbateurs endocriniens dans les tumeurs du sein / The Protein Kinase D1, PKD1, is an Essential Actor of Melanoma Physiology and a Target of Endocrine Disruptors in Breast Tumors

Merzoug, Messaouda

22 February 2017

La protéine kinase D1, PKD1, est une sérine/thréonine kinase activée par de nombreux facteurs mitogènes. Les études, menées jusqu’à présent sur les fonctions de PKD1, ont montré qu’elle semble jouer un rôle dans la régulation de plusieurs processus biologiques fondamentaux impliqués dans le développement des tumeurs. Cependant, le rôle précis et les cibles de PKD1 restent largement méconnus. Au cours de ce travail, nous avons tout d’abord démontré que l’inhibition de PKD1 dans les cellules de mélanome inhibe la croissance et la motilité cellulaire, induit l’expression de la E-cadhérine et une diminution de la N-cadhérine. D’autre part, nous nous sommes intéressés au rôle des perturbateurs endocriniens dans les cellules tumorales mammaires et avons démontré que PKD1 est une cible des perturbateurs endocriniens (PE). Les PE, tels que le bisphénol A (BPA) et les phtalates, sont des produits chimiques ubiquitaires de notre environnement. Leur rôle dans la croissance tumorale mammaire est bien documenté. Néanmoins, les mécanismes moléculaires précis par lesquels ces molécules agissent demeurent encore inconnus. Au cours de notre travail, nous avons démontré que ces PE induisent de façon dose-dépendante la prolifération des cellules MCF-7 (cellules d’adénocarcinome mammaire) et que ce processus biologique est dépendant de l’expression de PKD1. Ainsi, l’ensemble de ce travail fait apparaître, d’une part, que PKD1 pourrait être une nouvelle cible thérapeutique anti-tumorale potentielle dans le mélanome et que, d'autre part, PKD1est une cible moléculaire de certains PE dans le cancer du sein. / Protein kinase D1, PKD1, is a serine/threonine kinase which can be activated by mitogens and that regulates various functions involved in the development of tumors. However, its precise role and targets are still unclear. Our study demonstrates that PKD1 inhibition in melanoma cells decreased cell growth and motility, and reversed the E- to N-cadherin switch. On the other hand, we examined the role of endocrine disruptors (EDs) in breast cancer cells and identified PKD1 as a target of these compounds. EDs, such as bisphenol A (BPA) and phthalates, have been found molecular mechanisms are still ubiquitously throughout our environment. Their role in breast tumor growth has been well documented. However, their precisemolecular mechanisms are still unknown. Our study demonstrates that EDs induce dose-dependently MCF-7 cell growth and that this biological process is dependent upon PKD1expression. Thus, this work may define PKD1 as a novel potential anti-tumor therapeutic target in melanoma and identifies PKD1 as a new molecular target of some EDs in breast cancer cells.

Cancer du sein

Mélanome

Pkd1

Perturbateurs endocriniens

Cadhérine

Breast cancer

Mélanoma

Pkd1

Endocrine disruptors

Cadherin

Systemic Leptin Modulates the Expression of E-cadherin, β-catenin in the Ovary of Dietary-Induced Obese Infertile Rats

Sokan, Olufunke A

01 August 2013

One of the numerous complications of obesity is infertility. Leptin has been shown to reverse infertility; however, exact mechanism is poorly understood. Recent evidence indicates Ecadherin/ β-catenin complex, which is a structural constituent of adherens junction, is expressed in the rat ovary during folliculogenesis. We hypothesized that systemic leptin modulates the expression of E-cadherin and β-catenin in dietary-induced obese infertile rats to reverse infertility. Female Sprague-Dawley rats were fed either regular chow diet (RCD) (n=6) or high fat diet (HFD) (n=14). Oestrus cycles were monitored daily until their cycles became irregular. 100 ug/ml of leptin was given intraperitoneally to HFD-fed rats (n=5) with irregular cycles. The control rats HFD (n=9) and RCD received saline. Leptin treatment restored regular estrous cycle and increased the expression of E-cadherin and β-catenin in all the 5 rats (HFD+Leptin). This could represent the mechanism by which leptin reverses infertility in obese infertile rats.

Leptin

Reproduction

E-cadherin

β-catenin

infertility

obesity

Medical Education

Medical Sciences

Other Medicine and Health Sciences

Quantitative analysis of coordinated epithelial rotation on a two-dimensional discoidal pattern / 二次元円盤状パターンを用いた上皮細胞集団の回転運動についての定量解析

LUO, Shuangyu

23 May 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24822号 / 生博第502号 / 新制||生||67(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 上村 匡, 教授 見学 美根子, 教授 鈴木 淳 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DGAM

collective cell migration

cell-cell adhesion

E-cadherin

MDCK II

rotation

460

Topobiology of human pigmentation: P-cadherin selectively stimulates hair follicle melanogenesis

Samuelov, L., Sprecher, E., Sugawara, K., Singh, Suman K., Tobin, Desmond J., Tsuruta, D., Bíró, T., Kloepper, J.E., Paus, R.

January 2013

no / P-cadherin serves as a major topobiological cue in mammalian epithelium. In human hair follicles (HFs), it is prominently expressed in the inner hair matrix that harbors the HF pigmentary unit. However, the role of P-cadherin in normal human pigmentation remains unknown. As patients with mutations in the gene that encodes P-cadherin show hypotrichosis and fair hair, we explored the hypothesis that P-cadherin may control HF pigmentation. When P-cadherin was silenced in melanogenically active organ-cultured human scalp HFs, this significantly reduced HF melanogenesis and tyrosinase activity as well as gene and/or protein expression of gp100, stem cell factor, c-Kit, and microphthalmia-associated transcription factor (MITF), both in situ and in isolated human HF melanocytes. Instead, epidermal pigmentation was unaffected by P-cadherin knockdown in organ-cultured human skin. In hair matrix keratinocytes, P-cadherin silencing reduced plasma membrane β-catenin, whereas glycogen synthase kinase 3 beta (GSK3β) and phospho-β-catenin expression were significantly upregulated. This suggests that P-cadherin-GSK3β/Wnt signaling is required for maintaining the expression of MITF to sustain intrafollicular melanogenesis. Thus, P-cadherin-mediated signaling is a melanocyte subtype-specific topobiological regulator of normal human pigmentation, possibly via GSK3β-mediated canonical Wnt signaling.

Beyond cell Adhesion: Exploring the Role of Cadherin-11 Extracellular Processing by ADAM Metalloproteases in Cranial Neural Crest Migration

McCusker, Catherine D.

01 February 2010

The migration of the cranial neural crest is an essential part of cranio-facial development in every vertebrate embryo. The cranial neural crest (CNC) is a transient population of cells that forms the lateral border of the anterior neural plate. In the tailbud stage Xenopus embryo, the neural crest cells delaminate from the neural tube, and undergo a large-scale migration from the dorsal to ventral region of the embryo. The CNC travels along distinct pathways, and populates specific regions of the embryos face. Once the CNC ceases migrating, it differentiates into a variety of tissues that are essential for cranio-facial structure and function. Some of these tissues include bones, muscle, cartilage, and ganglia. The CNC receives a concert of signals from neighboring tissues during and after CNC migration as well as signals transmitted among CNC cells, which act together to determine the fate of each CNC cell. Therefore, the proper migration of the CNC is an essential part of cranio-facial development. What molecules are important for the process of CNC migration? As one might imagine, a milieu of different molecules and interactions are essential for this complicated embryological process to occur. The work presented in this dissertation will focus on the role of a cell adhesion molecule that is important for Xenopus CNC migration. Typically, the amount of cell adhesion decreases within tissues undergoing migration. This behavior is essential to allow fluidity within the tissue as it moves. However, cell adhesions are fundamental for cell migration to occur because the moving cells need a platform on which to mechanically propel themselves. These interactions can occur between the migrating cell and extracellular matrix molecules (ECM), or can happen between cells. The cranial neural crest utilizes both cell-ECM and cell-cell interactions during the process of migration. The amount of cell adhesion mediated by either of these mechanisms will depend on where the cell is located within the CNC. Cells located at the periphery of the CNC tissue, which is surrounded by a matrix of ECM, will have more cell-ECM interactions. Cells located deeper in the CNC tissue, where there is little ECM, will rely more on cell-cell interactions. The work presented in this thesis focuses on a cell-cell adhesion molecule that is part of the cadherin superfamily of molecules. With this in mind, these studies should be descriptive of the environment within the CNC, and to a less degree the environment between the CNC and the surrounding tissues. The work presented in this dissertation will focus on cadherin-11, which is a classical cadherin that is specifically expressed in the cranial neural crest during its migration. How does cadherin-11 function in the CNC during this process? The work presented here suggests that the main role of cadherin-11 in the CNC is to perform as a cell adhesion molecule. However, too much cell adhesion is inhibitory to migration. In this respect, many of the studies described in this work indicate that cadherin-11 mediated cell adhesion is tightly regulated during CNC migration. Here I show that cadherin-11 is extracellularly processed by ADAM metalloproteases, ADAM9 and ADAM13, which removes the adhesive domain of cadherin-11. This extracellular cleavage event occurs throughout CNC migration, and is likely the main mechanism that regulates cadherin-11 mediated cell adhesion. Cleavage of cadherin-11 by ADAMs does not seem to affect its ability to interact with cytoplasmic binding partners, â-catenin and p120-catenin. This observation supports the idea that the “purpose” of cadherin-11 cleavage is to regulate cell adhesion, and not to induce (cell autonomous) signaling events. Additionally, the secreted extracellular domain of cadherin-11 (EC1-3) retains biological activity. This fragment can bind to a number of cell surface molecules in tissue culture including full-length cadherin-11 and specific members of the ADAM family. This observation suggests that EC1-3 may interact with full-length cadherin-11 molecules in vivo, and inhibit cadherin-11 mediated cell adhesion during CNC migration. EC1-3 can rescue CNC migration in embryos that overexpress cadherin-11, further supporting this hypothesis. Many of the above observations have been published in my first-author paper entitled “Extracellular processing of cadherin-11 by ADAM metalloproteases is essential for Xenopus cranial neural crest migration” published in the journal Molecular Biology of the Cell in 2009. Some of the unpublished work in this dissertation further focuses on how EC1-3 effects CNC migration in an ex vivo environment. During these studies, the observation was made that overexpression of EC1-3 in a cranial neural crest explant produces abnormal directional movement. In these experiments, it appeared as though certain regions of the CNC explant were “attracting” other regions of the explant. The preliminary studies described in chapter IV are aimed at answering the question; does EC1-3 attract migrating CNC cells? Here, we generated a Matlab program in order to effectively quantify the amount of directional movement of CNC explants presented with a source of EC1-3. In addition to quantifying cell directionality, this program can also decipher between cells moving with random or directed motion, and measure the velocity of cell migration within certain coordinates. Therefore, this program should be useful other ex vivo studies that require the observation of these features. To conclude, the work presented in this dissertation suggests that the role of cadherin-11 during cranial neural crest migration is predominately based on the adhesive function. In order for CNC migration to proceed, the amount of cadherin-11 mediated cell-cell adhesion is tightly regulated throughout this process. These cell-cell interactions are likely important for “sheet” and “branch” migration where CNC cells maintain a lot of cell-cell cohesion.

ADAM

Cadherin

Cell migration

Cell signaling

Cranial neural crest

Developmental biology/Embryology

Cell Biology

Discerning The Role Of Krüppel-Like Factor 4 In Breast Cancer

Yori, Jennifer L.

January 2011

No description available.

Biomedical Research

Cellular Biology

Pharmacology

KLF4

E-cadherin

Epithelial-to-Mesenchymal Transition

breast cancer

metastasis

Cadherin mediated F-actin assembly and the regulation of morphogenetic movements during Xenopus laevis development

Nandadasa, Sumeda A.

05 August 2010

No description available.

Cellular Biology

Cadherin

F-actin

Cytoskeleton

Xenopus

p120

G protein-coupled receptors

Characterization of a new role for plakoglobin in suppressing epithelial cell translocation

Marsh, Randall Glenn

11 October 2001

No description available.

cell motility

plakoglobin

cadherin

TCF/LEF signaling

cell movement

cell translocation

Role of DNA methyltransferase 3B in neuronal cell differentation

Bai, Shoumei

12 September 2005

No description available.

DNA methyltransferase 3b

PC12 cell

differentiation

NGF

Histone deacetylase 2

T-cadherin

Novel-male induced pregnancy failure in mice: effects on implantation, luminal area and e-cadherin

Rajabi, Nazanin

10 1900

<p>Adhesion of the blastocyst to the uterine wall is a highly sensitive phenomenon referred to as implantation. Novel-males are capable of disrupting the success of this process (the Bruce effect). A leading hypothesis invokes the transfer of estradiol from the male to the female via urine. This estradiol has direct effect on the uterus which may include morphology and molecular dynamics. Estradiol has been related to closure of the uterus around the blastocyst during implantation, which may assist in bringing the blastocyst close to the uterine wall for strong adhesion. E-cadherin, a cellular adhesion molecule, is found on both blastocyst and uterine surfaces and has been suggested to be involved in their interaction during implantation. Estradiol has been observed to reduce e-cadherin expression in hormonally sensitive tissues like the mammary glands, ovaries and uteri. Here, male-induced disruption of implantation was examined across days 2-8 of gestation. Luminal area was quantified in isolated and male-exposed females as a measure of extent of luminal closure. This area was larger in male-exposed animals. E-cadherin was found to have reduced expression on luminal epithelial cells. I suggest that the reduction in e-cadherin may lead to weaker attachment of the blastocyst to the uterine wall as well as reduced adhesion between opposing uterine walls leading to the “opening” of the uterus observed in male exposed animals. Together, these data may in part explain the blastocyst implantation failure observed in male-exposed animals during the Bruce effect.</p> / Master of Science (MSc)

Bruce Effect

E-Cadherin

Implantation Failure

Estrogen

Luminal Area

Cellular and Molecular Physiology

Endocrinology

Cellular and Molecular Physiology