Investigation on the Mechanisms of Hepatoma-Derived Growth Factor-Mediated Cell Migration and Epithelial-Mesenchymal Transition

Kung, Mei-Lang

04 August 2012

In this study, we investigated the mechanisms of HDGF on cell migration in non-transformed NIH/3T3 cells. HDGF promoted the migration and the formation of dorsal ruffles and podosome rosettes. Besides, HDGF supply increased the PI3K expression, Akt phosphorylation and PTEN phosphorylation as well as stimulated the RhoA, Rac1, and Cdc42 activities. Furthermore, Adenoviral gene transfer of PTEN attenuated migration and PI3K/Akt/Rho GTPases signaling in HDGF-overexpressing transfectants. Pharmaceutical intervention using the PI3K inhibitor, LY294002, potently reversed HDGF-stimulated cell migration, dorsal ruffles formation and podosome formation as well as the RhoA, Rac1, and Cdc42 activities. Thus, HDGF elicits the activation of PI3K/Akt /Rho GTPases signaling cascade and promotes cytoskeleton remodeling to stimulate cellular migration. Moreover, we investigate the expression profile of HDGF during breast carcinogenesis. Immunohistochemical studies revealed elevated HDGF expression in human breast cancer. Nuclear HDGF labelling index was positively correlated with tumour grade, stage and proliferation index, but negatively correlated with survival rate in breast cancer patients. Our data also showed that HDGF over-expression was associated with lymph node metastasis and represented an independent prognostic factor for tumor recurrence. Furthermore, Immunoblot study revealed that elevated HDGF expression significantly higher in breast cancer cells (MDA-MB-231 cells) than that in non-transformed breast cells (MCF-7 cells). Consistently, higher invasive potency and colony formation also observed in MDA-MB-231 cells than in MCF-7 cells. Adenovirus-mediated HDGF over-expression and exogenous HDGF treatment stimulated the invasiveness and colony formation as well as E-cadherin down-regulation and Vimentin up-regulation. Conversely, either HDGF knockdown by RNA interference, HDGF antibody neutralization or BITC-induced EMT suppression in MDA-MB-231 cells attenuated the malignant behavior and elicited EMT reversal by enhancing E-cadherin expression while depleting Vimentin expression. In summary, HDGF elicits the activation of PI3K/Akt/Rho GTPases signaling cascade, thereby promoting cytoskeleton remodeling to stimulate cellular migration. Moreover, the formation of podosome rosettes is correlated with cell invasion, the podosome-stimulating capability of HDGF is consistent with HDGF regulates the metastasis of breast cancer through modulating of epithelial-mesenchymal transition. Therefore, our results provide not only novel insights into the role of the HDGF in cell migration and tumor metastasis, but also validate a novel prognostic indicator for breast cancer. Key words: Hepatoma-derived growth factor, PI3K, Akt, epithelal-mesenchemal transition, E-cadherin, Vimentin

E-cadherin

PI3K

Vimentin

Akt

Hepatoma-derived growth factor

epithelal-mesenchemal transition

Evanescent wave and video microscopy methods for directly measuring interactions between surface-immobilized biomolecules

Everett, William Neil

15 May 2009

Spatial and temporal tracking of passively diffusing functionalized colloids continues to be an improving and auspicious approach to measuring weak specific and non-specific biomolecular interactions. Evidence of this is given by the recent increase in published studies involving the development and implementation of these methods. The primary aim of the work presented in this dissertation was to modify and optimize video microscopy (VM) and total internal reflection microscopy (TIRM) methods to permit the collection of equilibrium binding and sampling data from interaction of surface-immobilized biomolecules. Supported lipid bilayers were utilized as model systems for functionalizing colloid and wall surfaces. Preliminary results measuring calcium-specific protein-protein interactions between surface immobilized cadherin fragments demonstrate the potential utility of this experimental system and these methods. Additionally, quantum dot-modified colloids were synthesized and evanescent wave-excited luminescence from these particles was used to construct potential energy profiles. Results from this work demonstrate that colloids can be used as ultra-sensitive probes of equilibrium interactions between biomolecules, and specialized probes, such as those modified with quantum dots, could be used in a spectral multiplexing mode to simultaneously monitor multiple interactions.

colloidal interactions

biomolecular forces

cadherin

cell-cell adhesion

total internal reflection microscopy

The beneficial Effects of Neural Crest Stem Cells on Pancreatic      β–cells

Ngamjariyawat, Anongnad

January 2014

Patients with type-1 diabetes lose their β-cells after autoimmune attack. Islet transplantation is a co-option for curing this disease, but survival of transplanted islets is poor. Thus, methods to enhance β-cell viability and function as well as methods to expand β-cell mass are required. The work presented in this thesis aimed to study the roles of neural crest stem cells or their derivatives in supporting β-cell proliferation, function, and survival. In co-culture when mouse boundary cap neural crest stem cells (bNCSCs) and pancreatic islets were in direct contact, differentiating bNCSCs strongly induced β-cell proliferation, and these proliferating β-cells were glucose responsive in terms of insulin secretion. Moreover, co-culture of murine bNCSCs with β-cell lines RIN5AH and β-TC6 showed partial protection of β-cells against cytokine-induced β-cell death. Direct contacts between bNCSCs and β-cells increased β-cell viability, and led to cadherin and β-catenin accumulations at the bNCSC/β-cell junctions. We proposed that cadherin junctions supported signals which promoted β-cell survival. We further revealed that murine neural crest stem cells harvested from hair follicles were unable to induce β-cell proliferation, and did not form cadherin junctions when cultured with pancreatic islets. Finally, we discovered that the presence of bNCSCs in co-culture counteracted cytokine-mediated insulin-producing human EndoC-βH1 cell death. Furthermore, these two cell types formed N-cadherin, but not E-cadherin, junctions when they were in direct contact. In conclusion, the results of these studies illustrate how neural crest stem cells influence β-cell proliferation, function, and survival which may improve islet transplantation outcome.

Neural Crest Stem Cells

Pancreatic Islets

β-cell proliferation

β-cell survival

Cadherin

The Role of c-Src in E-Cadherin Activity

Robert Mclachlan

Unknown Date

Cadherin-based cell-cell contacts are prominent sites for phosphotyrosine signalling, being enriched in tyrosine-phosphorylated proteins, tyrosine kinases and phosphatases. The functional interplay between cadherin adhesion and tyrosine kinase signalling, however, is complex and incompletely understood. In my thesis I have tested the hypothesis that c-Src contributes positively to cadherin biology by functioning as part of an adhesion activated cell-signalling pathway. I found that c-Src is active at both established and reforming cell-cell contacts, and c-Src can be activated by homophilic ligation of the adhesion receptor. However, c-Src has a biphasic impact on cadherin function, exerting a positive supportive role at lower signal strengths, but inhibiting function at high signal strengths. Inhibiting c-Src under circumstances when it is activated by cadherin adhesion decreased several measures of cadherin function. This suggests that the cadherin-activated c-Src signalling pathway serves positively to support cadherin function, while quantitative changes in signal strength may result in qualitative differences in functional outcome. Finally, my data implicated PI3-kinase signalling and cortactin as potential targets for cadherin-activated c-Src signalling. By inhibiting protein tyrosine phosphatases with pervanadate, I found that tyrosine phosphatase activity and not just protein binding was required to stimulate Src activity in response to cadherin ligation. I identified the tyrosine phosphatase RPTPα as a possible regulator of cadherin-activated Src signalling. RPTPα localises to cell-cell adhesions and it is found in a complex with E-cadherin and c-Src. Furthermore, knockdown of RPTPα disrupted the integrity of cadherin-based contacts and the activity of Src at these cell-cell contacts. This suggests that in response to cadherin-homophilic ligation PTP activity is required to stimulate Src signalling. Finally, I identified a novel pathway by which aberrant growth factor signalling could be downregulating cadherin function and promoting the invasion of epithelial cells. Stimulating cells with high levels of EGF revealed that aberrant epidermal growth factor signalling could disrupt cadherin-activated cell signalling. The integrity of cadherin-based contacts and the activity of Src at the cell-cell contacts were both disrupted in the presence of high levels of EGF. Analysis of E-cadherin and RPTPα immunoprecipitates suggested that activation of cadherin-bound EGFR might disrupt Src activation by displacing E-cadherin-RPTPα binding. Finally, analysing the subcellular distribution of these proteins revealed that, in response to high levels of EGF, E-cadherin, β-catenin, EGFR and pEGFR are internalised together in phospho-cortactin-rich endosomal-like structures. Therefore I propose that E-cadherin adhesion activates a cell-signalling pathway involving c-Src that functions to dynamically regulate the actin cytoskeleton and to maintain the adhesive strength of cell-cell adhesions. Perturbation of cadherin-activated Src signalling downregulates cadherin function and promotes the disassembly of cell-cell adhesive contacts. The concept of a cadherin-activated Src signalling pathway provides a new way to think about cadherin biology. Instead of merely functioning as passive glue holding two cells together, E-cadherin functions as an adhesion-activated signalling receptor. Dysregulation of E-cadherin-activated Src signalling and downregulation of cell-cell adhesions could be a mechanism promoting the invasion and metastasis of epithelial tumours.

E-cadherin

Src

Cell-Cell Adhesion

Protein Tyrosine Phosphatase

EGFR

RPTPα

Receptor Crosstalk

Untersuchung des Connexin 43 und N-Cadherin bei Patienten mit Fallot’scher Tetralogie und Double Outlet Right Ventricle vom Fallot-Typ

Haunschild, Josephina

04 January 2016

In der vorliegenden Arbeit wurden Myokardproben des rechtsventrikulären Ausflusstraktes von Patienten mit Fallot’scher Tetralogie sowie Double Outlet Right Ventricle vom Fallot - Typ untersucht. Hintergrund der Studie waren Untersuchungen anderer Autoren an Cx43 - knock - out Mäusen, die dort Veränderungen des kardialen Phänotyps beschrieben, die sie als Fallot - artig interpretierten. Daraus wurde die Hypothese entwickelt, dass Änderungen auf der Ebene des Connexin 43 ursächlich mit der Fallot’schen Tetralogie verbunden sein könnten. Es erfolgte eine histologische Analyse von 25 Patientenproben im Hinblick auf die Lokalisation von Connexin 43 sowie N - Cadherin. Es zeigte sich eine altersabhängige Verteilung von Connexin 43 und N - Cadherin. Insbesondere Patienten der Gruppe 1 (jünger als zwei Jahre) zeigten eine Verteilung sowohl an der lateralen Zellseite, als auch am Pol der Kardiomyozyten. Mit zunehmendem Alter beschränkten sich sowohl Connexin 43 als auch N - Cadherin auf die Disci intercalares zwischen den Kardiomyozyten und befanden sich dort in enger Nachbarschaft zueinander. Des Weiteren erfolgte eine Analyse der codierenden Region des Connexin 43 Gens mittels High Resolution Melting - PCR und sich daran anschließender Sequenzierung. Es zeigten sich sowohl bei den Kontrollen als auch den Patienten bereits bekannte Single Nucleotide Polymorphismen sowie bis dato unbekannte Sequenzvariationen. Allerdings wurden keine homozygoten Veränderungen der DNA festgestellt. Auch fand sich keine der heterozygoten Veränderungen in allen untersuchten Patienten. Somit ist es unwahrscheinlich, dass ein einzelner Basenaustausch zum komplexen Krankheitsbild der Fallot’schen Tetralogie beziehungsweise zum Double Outlet Right Ventricle vom Fallot - Typ führt.

Fallot Tetralogie

Connexin 43

N-Cadherin

tetralogy of fallot

connexin 43

ddc:610

Etude du rôle de la P-cadhérine dans la migration cellulaire collective / The rôle of P-cadherin in collective cell migration

Plutoni, Cédric

21 October 2014

La migration cellulaire collective (MCC) est un processus fondamental qui intervient au cours du développement, de la réparation tissulaire, de l'invasion tumorale et de la formation de métastases. Les cellules qui migrent collectivement possèdent deux types d'interaction avec leur environnement : i) l'un avec leur substrat et ii) l'autre avec les cellules voisines en migration. Deux grandes familles de protéines permettent ces interactions ainsi que la génération de forces mécaniques: i) la famille des intégrines (les récepteurs de la matrice extracellulaire) et ii) la famille des cadhérines (formant les jonctions intercellulaires). Les cadhérines classiques sont impliquées dans la formation des jonctions intercellulaires et sont les principaux acteurs de la MCC au cours du développement normal et tumoral. La transmission de force entre les cellules en migration est nécessaire à leur cohésion et à la communication des cellules entre elles. Des études récentes montrent que les cadhérines sont nécessaires à la transmission des forces au substrat. Néanmoins, les processus par lesquels les cadhérines agissent sur ses forces dans le contexte d'une MCC restent inexplorés. Nous avons identifié l'expression de la P-cadhérine comme étant associée à l'agressivité du rhabdomyosarcome de type alvéolaire (ARMS), sous type ayant le plus mauvais pronostic car très invasif. Nos données, ainsi que de récentes études qui démontrent que la P-cadhérine est impliquée dans l'agressivité des tumeurs du sein, nous ont conduits à étudier le rôle de cette cadhérine dans la migration cellulaire, processus majeur dans le développement tumoral. Nous nous sommes intéressés à l'impact de l'expression de la P-cadhérine sur la migration des myoblastes murins normaux C2C12. Pour ce faire nous utilisons un test de migration in vitro en 2D proche du test de blessure qui consiste à retirer une barrière physique induisant la migration des cellules vers l'espace libre ainsi créé. Nous avons pu monter que l'expression de la P-cadhérine dans les myoblastes C2C12 augmente les paramètres caractéristiques d'une MCC in vitro : la vitesse, la polarité, la persistance et la directionalité de la migration des cellules du front et au sein du feuillet. De plus, à l'aide de techniques microscopiques de mesure des forces nous avons montré une augmentation des forces intercellulaires allant du front vers le feuillet cellulaire au cours de la migration des cellules exprimant la P-cadhérine. Cela suggère une augmentation de la cohésion cellulaire. L'ensemble de ces résultats démontrent clairement que l'expression de la P-cadhérine induit une MCC. Nous avons aussi mesuré et cartographié les forces de traction au substrat connues pour être le moteur de la migration cellulaire. Nos données indiquent que l'expression de la P-cadhérine augmente l'anisotropie de ces forces de traction ainsi que leur intensité, et ce, uniquement au front de migration. L'expression de la P-cadhérine remodèle et stimule la dynamique des plaques focales d'adhérence à cet endroit.Afin de mieux comprendre comment la P-cadhérine modifie la dynamique des adhésions focales et augmente les forces de traction, nous avons étudié l'activité spatiotemporelle des petites protéines G de la famille Rho. Nous montrons que l'expression de la P-cadhérine active Rac1 et Cdc42 au front de migration, entrainant ainsi le remodelage et l'organisation des plaques focales d'adhérence à cet endroit. L'inhibition de Rac1 et Cdc42 bloque la MCC induite par la P-cadhérine. Pour conclure, en combinant la mesure des paramètres de migration cellulaire avec la mesure des forces mécaniques intercellulaires et au substrat, nous avons démontré que la P-cadhérine induit un comportement collectif des cellules et ce dépendamment de l'activité de Rac1 et de Cdc42. De plus nous mettons en avant l'existence de propriétés mécano-transductrices de cette cadhérine au cours de la MCC. / Collective cell migration (CCM), the coordinated movement of multiple cells that are connected by cell-cell adhesion, is a fundamental process in development, tissue repair and tumor invasion and metastasis. Cells part of a moving collective have two different types of interactions, i) one with the substratum, and ii) one with surrounding moving cells. Two protein families allow these interactions and also the generation of mechanical forces: i) typically integrins on the underlying extracellular matrix (ECM) and ii) cadherins at intercellular adhesion sites. Classical cadherins are involved in cell-cell adhesion and are major drivers of collective cell migration in embryonic development and tumorigenesis.Mechanical coupling between migratory cells may result in the production of force-dependent signals by which the cells influence each other. Moreover, whereas recent data showed that cadherin-dependent cell-cell adhesions are important for the force transmission to the ECM, how intercellular adhesion impacts on cell-ECM forces in the context of collective cell migration is totally unexplored. We identified P-cadherin expression to be associated with alveolar rhabdomyosarcoma (ARMS) aggressiveness, tumors with a bad prognosis due to the propensity for early and wide dissemination. Our data and recent findings showing that P-cadherin is associated with breast tumor invasiveness and aggressiveness, led us to investigate the role of P-cadherin in cell migration. We analyzed cell migration of normal mouse C2C12 myoblasts that express P-cadherin using a “wound-healing like assay” in which migration is analyzed after removal of a physical barrier. We observed that P-cadherin expression in C2C12 myoblasts increased the speed, polarity, persistence and directionality of migration toward the free space of both cells at the border and cells into the sheet. Using monolayer stress microscopy we showed that P-cadherin increases inter-cellular stresses and force transmission across the cell sheet. According to those observations we concluded that P-cadherin induces CCM.Traction forces exerted by the cells on the substrate are important for cell migration. Using traction force microscopy, we demonstrated that P-cadherin expression increases the traction forces anisotropy specifically at the multicellular leading row. To better understand how these mechanical signals induce CCM, we studied both the organization of the focal adhesions and the spatio-temporal activity of Rho GTPase. We showed that P-cadherin expression activates Rac1 and Cdc42 which induces extensive focal adhesions remodeling at the leading edge of cells at the leading row. Rac1 and Cdc42 inhibition impaired P-cadherin-induced CCM, focal adhesion remodeling and forces generation. In conclusion, combining a detailed measurement of the parameters of cell migration with physical measure of the intercellular stresses and traction forces, we have shown that P-cadherin promotes collective behavior of cells during migration through Rac1 and Cd42 activity. Also, those results provide evidence for mechano-transmission properties of P-cadherin during collective cell migration.

P-Cadhérine

Migration cellulaire collective

GTPases-Rho

P-Cadherin

Collective cell migration

Rho-GTPases

Approche mécanique de l'adhésion cellulaire, ouverture au diagnostic / A mechanical approach to cellular adhesions and its application to medical diagnostics

Milloud, Rachel

26 September 2014

La capacité des cellules à sentir les propriétés physiques de leur environnement est un facteur déterminant de l'homéostasie tissulaire. Ainsi, la rigidité de la matrice extracellulaire (forces exogènes) et les tensions du cytosquelette (forces endogènes) coopèrent de manière fonctionnelle modulant les transformations phénotypiques. Les cellules perçoivent et transmettent des forces en développant des structures d'adhérences appelées adhésions focales. Ces adhésions sont composées de protéines transmembranaires, les intégrines, qui font le lien entre le cytosquelette et la matrice extracellulaire.La partie centrale de mon projet de thèse aborde la question du couplage des intégrines b1 et b3 dans la mécanotransduction. Les données actuelles plaident fortement en faveur d'une relation bidirectionnelle entre l'adhésion intégrine-dépendante et les forces mécaniques générées dans ce processus. Les approches génétiques classiques ont souligné le rôle majeur des intégrines b1 et b3 dans mécanosensibilité cellulaire, sans préciser leur contribution relative. Par exemple, la manière dont la modulation de l'expression de l'intégrine b3 affecte la génération des forces de traction cellulaires et la distribution des adhésions intégrines-dépendantes reste à être explorées. Dans ce travail de thèse nous avons montré que les intégrines b1 ont un rôle essentiel dans la génération de forces cellulaires, que les intégrines b1 sont régulées négativement par les intégrines b3 en affectant la distribution spatiale des intégrines b1 à travers leur capacité à lier à la fois la taline et la kindline. Et enfin, nous avons montré que les intégrines b3 régulent temporellement l'activité contractile de la cellule.J'ai également participé à deux autres études dans le cadre de collaborations avec le Pr. Holmgren et le Dr. Debili, au cours desquelles j'ai utilisé la microscopie à traction de forces comme un outil diagnostique afin d'observer l'effet des forces contractiles dans la formation de la lumen aortique et de la formation des plaquettes sanguines. J'ai ainsi pu confirmer que la protéine amotL2, reliant les fibres contractiles aux VE-cadhérines, est impliquée dans la force intercellulaire nécessaire à la formation de la lumen aortique. Et lors d'une deuxième collaboration, j'ai pu montrer que la contractilité des mégacaryocytes, via leur système actomyosine, est nécessaire pour la formation des proplaquettes. / Cell ability to sense mechanical properties of their microenvironment is crucial for tissue homeostasis which means their capacity to maintain mechanical integrity as they are submitted to external forces.Integrins have been highlighted as mechanotransducers able to form micro-scale structures called focal adhesion sites which mechanically link cells to the extracellular matrix by recruiting various adaptors. Both b1 and b3 integrins have been identified as the principal actors of tensional homeostasis. However as the resulting mechanotransduction processes are intrinsically dynamic, the respective and cooperative roles b1 and b3 integrins need to be addressed over time and space.In the present work, coupling time-resolved traction force microscopy and genetics approaches, we investigated the respective role of b1 and b3 integrins in active force generation at the single cell level. Our findings show that b1 integrins has an essential role in generation of cellular traction forces, b1 integrin-generated force is negatively regulated by b3 integrins which impacts the redistribution of b1 integrin containing adhesion through its ability to bind to talin and kindlin, b3 integrin supports min-scale temporal regulation of cellular contractile activity generated by b1 integrin. Finally, cell mechanical equilibrium relies on the ability of cells to maintain a fixed contractile moment.I also participated in two others studies in the framework of collaborations in which I used the traction force microscopy as a diagnostic tool to observe the effect of contractile forces in the formation of the aortic lumen and the formation of proplatelets. I was able to confirm that the protein amotL2 connecting the contractile fibers to VE-cadherin, is involved in intercellular forces necessary for the formation of the aortic lumen. And in a second collaboration, where I found by using traction force microscopy that the contractility of megakaryocytes via its actomyosin system, is necessary for the formation proplatelets.

Intégrines

Forces de traction

Mécanotransduction

Actine

Cadhérine

Integrins

Traction forces

Mechanotransduction

Actin

Cadherin

530

A expressão das claudinas 1, 3, 4, 7 e E-caderina em uma série de tumores de mama triplo-negativos

Cadore, Ermani

January 2012

INTRODUÇÃO: O câncer de mama é uma importante causa de morbimortalidade, é conhecido por ser uma doença heterogênea. A caracterização clínica e molecular de seus subtipos é fundamental para nortear o prognóstico e o tratamento dessas pacientes. Novos estudos são necessários na melhor caracterização dos tumores triplo-negativos. O estudo da expressão das claudinas pode auxiliar na caracterização desses tumores. OBJETIVO: Investigar a associação da expressão das claudinas 1, 3, 4 e 7 e E-caderina com variáveis clínico-patológicas e fatores prognósticos, em uma série de tumores de mama triplo-negativos (RE-, RP- e HER2-). MÉTODOS: 80 tumores triplo-negativos foram analisados por imunoistoquímica automatizada para as claudinas 1, 3, 4, 7 e E-caderina. A expressão imunoistoquímica foi avaliada pelo escore H (intensidade multiplicada pela porcentagem de marcação). Foram avaliadas as associações entre características clínico-patólogicas e o escore H. Para a avaliação prognóstica das pacientes, curvas de Kaplan-Meier foram construídas a partir dos dados de seguimento das pacientes e do escore H. RESULTADOS: Foi encontrada associação significativa entre o alto escore H da CLDN-1 (HCLDN-1) e pacientes mais idosas e com a presença de necrose, alto escore H da E-caderina (HE-CAD) em pacientes mais jovens e baixo escore H da CLDN-7 (HCLDN-7) e Ki67 positivo. Além disso, pacientes com elevado HCLDN-1 tiveram menor sobrevida geral. Por outro lado, o elevado HCLDN-3 apresentou uma tendência à associação com maior sobrevida geral e sobrevida livre de doença. CONCLUSÕES: A expressão diferencial das claudinas e E-caderina podem auxiliar na caracterização clinico-patológica dos tumores triplo-negativos. Além disso, as claudinas 1 e 3 parecem ser fatores prognósticos para esses tumores. / INTRODUCTION: Breast cancer is a major cause of morbidity and mortality, is known to be a heterogeneous disease. The clinical and molecular characterization of its subtypes is critical to guide the prognosis and treatment of these patients. Further studies are needed for the best characterization of triple-negative tumors. The study of the expression of claudinas can aid in the characterization of these tumors. OBJECTIVE: To investigate the association of expression of claudinas 1, 3, 4 and 7 and E-cadherin with clinicopathological variables and prognosis in a series of triple-negative breast cancers (ER-, PR- and HER2-). METHODS: 80 triple negative tumors were analyzed by automated immunohistochemistry for the claudins 1, 3, 4, 7 and E-cadherin. The immunohistochemical expression was assessed by H-Score (intensity multiplied by the percentage of staining). We evaluated the associations between clinicopathological characteristics and H-Score. For the prognostic assessment of patients, Kaplan-Meier curves were constructed from the follow-up data of patients and H-Score. RESULTS: We found a significant association between high H-Score of CLDN-1 (HCLDN-1) and older patients and the presence of necrosis, high H-Score of E-cadherin (H-CAD) in younger patients and low H-Score CLDN-7-(7-HCLDN) and Ki67 positive. Furthermore, patients with high-HCLDN1 had a lower overall survival. On the other hand, the high HCLDN-3 showed a trend toward association with greater overall survival and disease-free survival. CONCLUSIONS: Differencial expression of claudins and E-cadherin can help in clinic-pathological characterization of triple-negative tumors. Futhermore, claudin 1 and 3 appear to be prognostic factor for these tumors.

Epidemiologia

Neoplasias da mama

Claudinas

Caderinas

Breast cancer

Immunohistochemical markers

Claudins

E-cadherin

Triple-negative

Expressão de glicanos e seu envolvimento com a perda da estabilidade das junções aderentes em células de câncer colo-retal / Glycans expression and their involvement with the loss of stability of adherens junctions in colorectal cancer cells

Julio Cesar Madureira de Freitas Junior

19 February 2009

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A junção aderente (JA) é um dos principais componentes do complexo juncional apical. Esta juncão é um complexo multiprotéico em que a E-caderina, uma glicoproteína transmembrana, atua como principal mediadora da adesão célula-célula. Sua ancoragem ao citoesqueleto de actina ocorre via proteínas da família das cateninas. Modificações pós-traducionais da E-caderina, como fosforilação e glicosilação, podem modular a estabilidade e organização das JAs. Muitos estudos têm sugerido que no câncer a invasão e a metástase podem estar associadas a arranjos de glicanos na superfície celular. Em câncer colo-retal, o papel de alterações na expressão de glicanos sobre a estabilidade da adesão mediada por Ecaderina ainda não está claro. Neste estudo, investigamos a relação entre estas alterações e a estabilidade das JAs em células de câncer colo-retal. Nós utilizamos duas linhagens celulares com diferentes potenciais metastáticos, Caco-2 and HCT- 116, que constituem dois modelos de JAs: estáveis e instáveis, respectivamente. Ensaios de precipitação de lectinas e immunoblotting demonstraram que em HCT- 116, a linhagem mais invasiva, a E-caderina apresenta uma diminuição de glicanos reconhecidos pelas lectinas HPA e WGA, que reconhecem resíduos de Nacetilgalactosamina e, _-N-acetilhexosaminas e ácido siálico, respectivamente. Concomitantemente, em HCT-116 também foi observado um aumento de glicanos reconhecidos pelas lectinas L-PHA e E-PHA, que reconhecem respectivamente: acetilglicosamina_1,6-ligada formando N-glicanos tri- e tetraantenados e, Nacetilglicosamina bisectante _1,4-ligada formando N-glicanos biantenados. Ensaios de imunofluorescência mostraram que a presença desses glicanos reconhecidos por L-PHA, em HCT-116, é intensa na região de contato célula-célula quando comparada com células Caco-2, em que a marcação foi observada, predominantemente, na região apical. Além disso, a inibição completa da Nglicosilação por tunicamicina ou a inibição da síntese de N-glicanos complexos por swainsonina, aumentou a associação da E-caderina com o citoesquleto de actina em células HCT-116, mas não em Caco-2. Em células HCT-116, a inibição de Nglicosilação por tunicamicina produziu uma diminuição da atividade de ERK1/2 e a formação de adesão célula-célula foi mais evidente. Estes dados sugerem que alterações na expressão e localização subcelular de diferentes glicanos podem ser importantes eventos associados à perda da estabilidade das JAs em câncer coloretal. / The adherent junction (AJ) is one of the main components of the apical junctional complex. It is a multiprotein complex where E-cadherin, a transmembrane glycoprotein, acts as the main mediator of cell-cell adhesion in epithelium. This protein is anchored to the actin cytoskeleton via proteins of the catenin family. Posttranslational modifications of E-cadherin, such as phosphorylation and glycosylation, can modulate the assembly of AJs. Various studies have suggested that invasion and metastasis is associated to glycan patterns on the cell surface of tumor cells. In colorectal cancer the role of altered glycans expression and stability of E-cadherin-mediated adhesion is not clear. In this study we investigated the relation between changes of the glycans expression and AJs stability in colorectal cancer cells. We used two colon adenocarcinoma cell lines with different metastatic potential, Caco-2 and HCT-116, both models of stable and unstable AJs, respectively. Lectin binding assays demonstrated that in HCT-116, the more invasive cell line, E-cadherin presents a decrease of the glycans recognized by HPA and WGA lectins, which recognize N-acetylgalactosamine and, _-N-acetylhexosamines and sialic acid, respectively. Conversely, in HCT-116, there was an increase of glycans recognized by E-PHA and L-PHA lectins, which recognize bisecting _1,4- branched and _1,6-branched N-acetylglucosamine, respectively. Immunofluorescence assays showed a stronger L-PHA binding on cell-cell contact regions of HCT-116 cells when compared with Caco-2. Furthermore, in HCT-116 cells a complete inhibition of N-glycosylation by tunicamycin or inhibition of complex N-glycans synthesis by swainsonine increased the association of E-cadherin with the actin cytoskeleton. Finally, it was possible to observe that the inhibition of N-linked glycosylation by tunicamycin, leaded to a decreasing of ERK1/2 phosphorylation concomitantly with the formation of more intimate cell-cell contacts. These findings suggest that altered expression and subcellular localization of different glycans can be important events associated to loss of AJs stability in colorectal cancer.

Câncer colo-retal

Junções Aderentes

Glicobiologia

E-caderina

Colorectal cancer

Adherent junctions

Glycobiology

E-cadherin

CITOLOGIA E BIOLOGIA CELULAR

Expressão de glicanos e seu envolvimento com a perda da estabilidade das junções aderentes em células de câncer colo-retal / Glycans expression and their involvement with the loss of stability of adherens junctions in colorectal cancer cells

Julio Cesar Madureira de Freitas Junior

19 February 2009

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A junção aderente (JA) é um dos principais componentes do complexo juncional apical. Esta juncão é um complexo multiprotéico em que a E-caderina, uma glicoproteína transmembrana, atua como principal mediadora da adesão célula-célula. Sua ancoragem ao citoesqueleto de actina ocorre via proteínas da família das cateninas. Modificações pós-traducionais da E-caderina, como fosforilação e glicosilação, podem modular a estabilidade e organização das JAs. Muitos estudos têm sugerido que no câncer a invasão e a metástase podem estar associadas a arranjos de glicanos na superfície celular. Em câncer colo-retal, o papel de alterações na expressão de glicanos sobre a estabilidade da adesão mediada por Ecaderina ainda não está claro. Neste estudo, investigamos a relação entre estas alterações e a estabilidade das JAs em células de câncer colo-retal. Nós utilizamos duas linhagens celulares com diferentes potenciais metastáticos, Caco-2 and HCT- 116, que constituem dois modelos de JAs: estáveis e instáveis, respectivamente. Ensaios de precipitação de lectinas e immunoblotting demonstraram que em HCT- 116, a linhagem mais invasiva, a E-caderina apresenta uma diminuição de glicanos reconhecidos pelas lectinas HPA e WGA, que reconhecem resíduos de Nacetilgalactosamina e, _-N-acetilhexosaminas e ácido siálico, respectivamente. Concomitantemente, em HCT-116 também foi observado um aumento de glicanos reconhecidos pelas lectinas L-PHA e E-PHA, que reconhecem respectivamente: acetilglicosamina_1,6-ligada formando N-glicanos tri- e tetraantenados e, Nacetilglicosamina bisectante _1,4-ligada formando N-glicanos biantenados. Ensaios de imunofluorescência mostraram que a presença desses glicanos reconhecidos por L-PHA, em HCT-116, é intensa na região de contato célula-célula quando comparada com células Caco-2, em que a marcação foi observada, predominantemente, na região apical. Além disso, a inibição completa da Nglicosilação por tunicamicina ou a inibição da síntese de N-glicanos complexos por swainsonina, aumentou a associação da E-caderina com o citoesquleto de actina em células HCT-116, mas não em Caco-2. Em células HCT-116, a inibição de Nglicosilação por tunicamicina produziu uma diminuição da atividade de ERK1/2 e a formação de adesão célula-célula foi mais evidente. Estes dados sugerem que alterações na expressão e localização subcelular de diferentes glicanos podem ser importantes eventos associados à perda da estabilidade das JAs em câncer coloretal. / The adherent junction (AJ) is one of the main components of the apical junctional complex. It is a multiprotein complex where E-cadherin, a transmembrane glycoprotein, acts as the main mediator of cell-cell adhesion in epithelium. This protein is anchored to the actin cytoskeleton via proteins of the catenin family. Posttranslational modifications of E-cadherin, such as phosphorylation and glycosylation, can modulate the assembly of AJs. Various studies have suggested that invasion and metastasis is associated to glycan patterns on the cell surface of tumor cells. In colorectal cancer the role of altered glycans expression and stability of E-cadherin-mediated adhesion is not clear. In this study we investigated the relation between changes of the glycans expression and AJs stability in colorectal cancer cells. We used two colon adenocarcinoma cell lines with different metastatic potential, Caco-2 and HCT-116, both models of stable and unstable AJs, respectively. Lectin binding assays demonstrated that in HCT-116, the more invasive cell line, E-cadherin presents a decrease of the glycans recognized by HPA and WGA lectins, which recognize N-acetylgalactosamine and, _-N-acetylhexosamines and sialic acid, respectively. Conversely, in HCT-116, there was an increase of glycans recognized by E-PHA and L-PHA lectins, which recognize bisecting _1,4- branched and _1,6-branched N-acetylglucosamine, respectively. Immunofluorescence assays showed a stronger L-PHA binding on cell-cell contact regions of HCT-116 cells when compared with Caco-2. Furthermore, in HCT-116 cells a complete inhibition of N-glycosylation by tunicamycin or inhibition of complex N-glycans synthesis by swainsonine increased the association of E-cadherin with the actin cytoskeleton. Finally, it was possible to observe that the inhibition of N-linked glycosylation by tunicamycin, leaded to a decreasing of ERK1/2 phosphorylation concomitantly with the formation of more intimate cell-cell contacts. These findings suggest that altered expression and subcellular localization of different glycans can be important events associated to loss of AJs stability in colorectal cancer.

Câncer colo-retal

Junções Aderentes

Glicobiologia

E-caderina

Colorectal cancer

Adherent junctions

Glycobiology

E-cadherin

CITOLOGIA E BIOLOGIA CELULAR