Activated leukocyte cell adhesion molecule (ALCAM) regulation of tumor cell behavior and neuronal targeting

Jannie, Karry Marie

01 May 2012

Numerous events during development require the tightly controlled and regulated interaction of cells - from gastrulation in the early embryo to axonal pathfinding and remodeling of synaptic networks. Each of these events is dependent upon signals generated by cell-cell interactions, which are in turn specified by a diverse number of cell adhesion molecules. Many families of cell adhesion molecules have been described, and these fall into the broad categories of cadherins, immunoglobulin superfamily (IgSF) members, selectins, and integrins. Activated Leukocyte Cell Adhesion Molecule (ALCAM) is a member of the IgSF, and controls numerous developmental processes, ranging from hematopoiesis to neuronal targeting. Furthermore, this protein has been implicated in the progression of numerous cancers of diverse origins. Despite the variety of developmental and pathological processes in which ALCAM has been implicated, little is known about how it signals in the cell - few extracellular binding partners have been isolated, and, as of this writing, no cytoplasmic interactors have been identified. The purpose of the work presented in this thesis was to elucidate the mechanisms by which ALCAM influences cell behavior, specifically in uveal melanoma cells, and to determine novel extra- and intracellular ligands. Here, I report the regulation of cadherin-based junctions by ALCAM in uveal melanoma cells, as well as provide evidence for a novel extracellular interaction with L1 cell adhesion molecule, and identify three novel intracellular binding partners.

adherens junction

ALCAM

catenin

L1

N-cadherin

uveal melanoma

Biology

Characterizing the function of the Fps/Fes tyrosine kinase in the mammary gland

Truesdell, Peter Francis

08 July 2008

The fps proto-oncogene encodes a 92 kDa cytoplasmic tyrosine kinase. Previous studies have shown that Fps expression in the mammary gland changes with development, and Fps has a suppressor function in mammary tumorigenesis. The aim of my thesis was to elucidate the role of the Fps tyrosine kinase in regulating mammary gland development and function. We have shown that the expression of the Fps kinase in the mammary gland increased during pregnancy and reached its maximum during lactation. The level of Fps tyrosine phosphorylation paralleled the expression pattern. Pups reared by fps-null females gained weight more slowly than those reared by wild-type females. Epithelial cells were the primary source of Fps expression. Milk protein and fat content were not affected by the absence of Fps. Similarly, no differences in mammary gland structure were observed with whole mount or histological analysis. Fps was shown to be in a multi-protein complex with E-cadherin, β-catenin and p120-catenin. A strong co-localization signal was observed for Fps and E-cadherin. Immunofluorescence analysis indicated that the localization of E-cadherin and β-catenin was disorganized and less concentrated at sites of cell-cell contacts in the fps-null glands. The interactions between the different adherens junction components were altered in the fps-null tissue. Specifically, less E-cadherin and β-catenin was associated with p120-catenin in the fps-null glands. Suprisingly, no phosphotyrosine differences were detected for the adherens junction components. Conditions were established to grow primary murine epithelial cell cultures that could be used to investigate the function of Fps. Fps expression was up-regulated in these cells in response to lactogenic hormones. A lentiviral system encoding a murine p53 shRNA sequence was used to increase the growth potential of the primary cells. Continual growth of the infected and uninfected primary epithelial cell mixture resulted in the establishment of an immortalized cell line. Immunofluorescent and immunoblot analyses revealed that the cells have undergone an epithelial-to-mesenchymal transition. With the transduction of a myc-epitope tagged Fps into the cells, we have generated cell lines with the appropriate genetic backgrounds to study the function of the Fps kinase in the mammary gland, specifically as it relates to tumorigenesis. / Thesis (Ph.D, Pathology & Molecular Medicine) -- Queen's University, 2008-07-03 11:53:01.135

Fps/Fes tyrosine kinase

Adherens junction

Mammary gland

Lactation

Mechanotransduction through cytoskeleton and junctions in cardiomyopathies

Zhang, Kehan

19 May 2020

Cardiomyopathies represent a heterogeneous group of diseases of the heart muscle that often lead to progressive heart failure with high morbidity and mortality. In a significant and increasing percentage of the patient population, cardiomyopathies have been associated with hereditary mutations in genes encoding critical cellular components that make up the cytoarchitecture of cardiac muscle cells, or cardiomyocytes. While specific mutations have been linked to different classes of cardiomyopathies, it is however not well understood how these mutations cause cytostructural abnormalities that ultimately lead to dysfunction of cardiomyocytes. To gain insights into the pathogenesis of inherited cardiomyopathies, we focus in this thesis on a particular set of mutations in the cardiac cytoskeleton and desmosomes that are associated with dilated and arrhythmogenic cardiomyopathies, and probe their pathogenic mechanisms using cardiomyocytes derived from human induced pluripotent stem cells and bioengineered culture platforms. In part one, we describe the mechanical and molecular basis for the assembly of sarcomeres, the fundamental contractile units within cardiomyocytes, and reveal how mutations in titin (TTN) abolish this process by disrupting cell-matrix interaction and impairing diastolic force generation, a hallmark of dilated cardiomyopathy. In the second part of this thesis, we reveal that plakophilin-2 (PKP2) mutations that are associated with arrhythmogenic cardiomyopathy lead to impaired systolic function by destabilizing cell-cell junctions and in turn disrupting sarcomere stability and organization. Together, our studies establish a deeper understanding of how cell-matrix and cell-cell interactions contribute to the organization and function of cardiomyocytes and how disruption of these interactions by pathogenic mutations lead to cardiac dysfunction. / 2022-05-18T00:00:00Z

Biomedical engineering

Adherens junction

ARVD

Cardiac myosin

Contractility

Desmosome

Sarcomerogenesis

The Host Adherens Junction Molecule Nectin-1 Is Degraded by Chlamydial Protease-Like Activity Factor (CPAF) in Chlamydia Trachomatis-Infected Genital Epithelial Cells

Sun, Jingru, Schoborg, Robert V.

01 January 2009

Nectin-1 is an adhesion protein implicated in the organization of adherens junctions and tight junctions in epithelial cells. Previous studies in our laboratory demonstrated that nectin-1 accumulation was significantly decreased in Chlamydia trachomatis-infected HeLa cells. In the present study, Western blot analyses indicated that nectin-1 down-regulation was C. trachomatis concentration-dependent. The half-life of nectin-1 was also greatly diminished in C. trachomatis-infected cells compared to that observed in mock-infected cells, indicating that nectin-1 was likely down-regulated post-translationally. The chlamydia-secreted protease CPAF is known to degrade several important host proteins; CPAF expression within infected cells correlated with the time-dependent cleavage of nectin-1. Notably, CPAF proteolytic activity is inhibited by lactacystin but not by the proteosome inhibitor MG132. In vivo inhibition experiments demonstrated that nectin-1 down-regulation was blocked by lactacystin exposure. In contrast, MG132 had no effect. Finally, cell-free cleavage assays demonstrated that functional recombinant GST-CPAFwt protein degrades nectin-1. This degradation was blocked by lactacystin, as previously observed in vivo. Collectively, these results indicate that nectin-1 is degraded by CPAF in C. trachomatis-infected cells, a novel strategy that chlamydiae may use to aid their dissemination.

adherens junction

chlamydia trachomatis

CPAF

nectin-1

Biomedical Sciences

Dynamique de la jonction adhérente : rôle d'EPLIN dans la stabilité des contacts intercellulaires de l'endothélium vasculaire / Dynamic of adherens junction : role of EPLIN in intercellular contacts stability of vascular endothelium

Pétinot, Adeline

07 October 2011

L'endothelium vasculaire constitue la principale barrière entre le sang et les tissus régulant le passage de macromolécules et de cellules circulantes. Longtemps considéré comme une monocouche passive, l'endothélium joue d'importants rôles dans la régulation de la pression sanguine, de l'hémostase, des réponses immunitaires et inflammatoires. L'adhérence cellule/cellule est initiée dans l'endothélium vasculaire par des interactions homophiliques entre molécules de VE-cadhérine (= jonctions adhérentes). La dynamique de la jonction et du cytosquelette est importante pour le remodelage des jonctions intercellulaires qui a lieu au cours l'angiogenèse, de la vasculogenèse et lors de la réparation de l'endothélium. C'est pourquoi la détermination des mécanismes moléculaires sous-jacents est indispensable à la comprehension de phénomènes physiopathologiques (angiogenèse et progression tumorales, inflammation...). D'après la littérature, la protéine EPLIN intervient dans la formation du complexe E-cadhérine/alpha-caténine/EPLIN et stabilise l'actine corticale. Actuellement décrite comme spécifique des modèles épithéliaux, EPLIN peut-elle intervenir dans la liaison du complexe à base de VE-cadhérine au cytosquelette d'actine? De plus, il paraît essentiel de comprendre le rôle de cette protéine dans les cellules car son expression est fortement diminuée dans la plupart des cancers alors qu'à l'inverse sa surexpression bloque la prolifération cellulaire. / The endothelium forms the main barrier regulating the passage of macromolecules and circulating cells between the blood and tissue. Historically viewed as a passive vascular lining, vascular endothelium plays important roles in the regulation of vascular pressure, hemostasis, immune and inflammatory responses. In vascular endothelium, cell/cell adhesion is mediated by homophilic interactions of VE-cadherin molecules (= adherens junctions). Cytoskeleton and junction dynamics are important for intercellular junctions remodelling that occurs during angiogenesis, vasculogenesis and endothelium repair. So, determining the underlying molecular mechanisms is essential for the comprehension of pathologic phenomena such as angiogenesis, tumor progression or inflammation. We learn from the literature that EPLIN is involved in E-cadherin/α-catenin/EPLIN complex formation and cortical actin stabilization. Usually described as a protein specific of epithelial models, we wondered if EPLIN is able to link VE-cadherin complex to actin cytoskeleton. Furthermore, it seems essential to understand its cellular role since it is downregulated in many cancers while in contrast its overexpression blocks cell proliferation.

Jonction adhérente

VE-acdhérine

Endothélium

Alpha-caténine

EPLIN

Adherens junction

VE-cadherin

Alpha-catenin

EPLIN

570

From Womb to Doom: Mechanical Regulation of Cardiac Tissue Assembly in Morphogenesis and Pathogenesis

McCain, Megan Laura

January 2012

The assembly, form, and function of the heart is regulated by complex mechanical signals originating from intrinsic and extrinsic sources, such as the cytoskeleton and the extracellular matrix. During development, mechanical forces influence the self-assembly of highly organized ventricular myocardium. However, mechanical overload induces maladaptive remodeling of tissue structure and eventual failure. Thus, mechanical forces potentiate physiological or pathological remodeling, depending on factors such as frequency and magnitude. We hypothesized that mechanical stimuli in the form of microenvironmental stiffness, cytoskeletal architecture, or cyclic stretch regulate cell-cell junction formation and cytoskeletal remodeling during development and disease. To test this, we engineered cardiac tissues in vitro and quantified structural and functional remodeling over multiple spatial scales in response to diverse mechanical perturbations mimicking development and disease. We first asked if the mechanical microenvironment impacts tissue assembly. To investigate this, we cultured two-cell cardiac µtissues on flexible substrates with tunable stiffness and monitored cell-cell junction formation over time. As myocytes transitioned from isolated cells to interconnected µtissues, focal adhesions disassembled near cell-cell interfaces and mechanical forces were transmitted almost completely through cell-cell junctions. However, µtissues cultured on stiff substrates mimicking fibrotic microenvironments retained focal adhesions near the cell-cell interface, potentially to reinforce the cell-cell junction in response to excessive forces generated by myofibrils in stiff microenvironments. Intercellular electrical conductance between myocytes was measured as a function of connexin 43 immunosignal and the length-to-width ratio of cell pairs. We observed that conductance was correlated to connexin 43 immunosignal and cell pair length-to-width ratio, indicating that tissue architecture can affect electrical coupling. The impact of mechanical overload was also determined by applying chronic cyclic stretch to engineered cardiac tissues. Stretch activated gene expression patterns characteristic of pathological remodeling, including up-regulation of focal adhesion genes, and impacted sarcomere alignment and myocyte shape. Furthermore, chronic cyclic stretch altered intracellular calcium cycling in a manner similar to heart failure and decreased contractile stress generation, suggestive of maladaptive remodeling. In summary, we show that the assembly, form, and function of cardiac tissue is sensitive to a wide range of mechanical cues that emerge during physiological and pathological growth. / Engineering and Applied Sciences

adherens junction

cardiac myocyte

focal adhesion

intercalated disc

mechanotransduction

sarcomere

biomedical engineering

cellular biology

biophysics

Identification of echinus and characterization of its role in Drosophila eye development

Bosdet, Ian Edward

11 1900

The precise structure of the adult Drosophila eye results from a coordinated process of cell sorting, differentiation and selective cell death in the retinal epithelium. Mutations in the gene echinus cause supernumerary pigment cells due to insufficient cell death. This study reports the identification of echinus and the characterization of its role in Drosophila retinal development. Using a combination of deletion mapping, gene expression analysis and genomic sequencing, echinus was cloned and several alleles were sequenced. echinus encodes a ~180kDa protein containing an ubiquitin hydrolase domain at its N-terminus and a polyglutamine tract at its C-terminus. echinus is expressed in the retina during pupal development and mutants of echinus have decreased levels of apoptosis during several stages of retinal development. Defects in the cell sorting process that precedes cell death are also observed in echinus loss-of-function mutants and echinus overexpression can cause defects in ommatidial rotation and the morphology of cone cells. echinus is a positive regulator of DE-cadherin and Enabled accumulation in adherens junctions of retinal epithelial cells. Genetic interactions were observed between echinus and the genes wingless, enabled and expanded. An immunofluorescence assay in Drosophila S2 cell cultured demonstrated that Echinus localizes to intracellular vesicles that do not appear to be endocytic in nature, and the C-terminal region of Echinus was shown to be necessary for this association. A protein interaction screen using an immunoprecipitation and mass spectrometry approach identified interactions between Echinus and the vesicle coat protein Clathrin, the scaffolding protein RACK1 and the casein kinase I epsilon (Dco). Co-immunoprecipitation additionally identified an interaction between Echinus and Enabled. This work has revealed echinus to be an important regulator of cell sorting and adherens junction formation in the developing retina and has identified multiple interactions between echinus and enabled, a regulator of the actin cytoskeleton.

Drosophila

Echinus

Cell adhesion

Programmed cell death

Retina development

Adherens junction

Cell sorting

Identification of echinus and characterization of its role in Drosophila eye development

Bosdet, Ian Edward

11 1900

The precise structure of the adult Drosophila eye results from a coordinated process of cell sorting, differentiation and selective cell death in the retinal epithelium. Mutations in the gene echinus cause supernumerary pigment cells due to insufficient cell death. This study reports the identification of echinus and the characterization of its role in Drosophila retinal development. Using a combination of deletion mapping, gene expression analysis and genomic sequencing, echinus was cloned and several alleles were sequenced. echinus encodes a ~180kDa protein containing an ubiquitin hydrolase domain at its N-terminus and a polyglutamine tract at its C-terminus. echinus is expressed in the retina during pupal development and mutants of echinus have decreased levels of apoptosis during several stages of retinal development. Defects in the cell sorting process that precedes cell death are also observed in echinus loss-of-function mutants and echinus overexpression can cause defects in ommatidial rotation and the morphology of cone cells. echinus is a positive regulator of DE-cadherin and Enabled accumulation in adherens junctions of retinal epithelial cells. Genetic interactions were observed between echinus and the genes wingless, enabled and expanded. An immunofluorescence assay in Drosophila S2 cell cultured demonstrated that Echinus localizes to intracellular vesicles that do not appear to be endocytic in nature, and the C-terminal region of Echinus was shown to be necessary for this association. A protein interaction screen using an immunoprecipitation and mass spectrometry approach identified interactions between Echinus and the vesicle coat protein Clathrin, the scaffolding protein RACK1 and the casein kinase I epsilon (Dco). Co-immunoprecipitation additionally identified an interaction between Echinus and Enabled. This work has revealed echinus to be an important regulator of cell sorting and adherens junction formation in the developing retina and has identified multiple interactions between echinus and enabled, a regulator of the actin cytoskeleton.

Drosophila

Echinus

Cell adhesion

Programmed cell death

Retina development

Adherens junction

Cell sorting

Identification of echinus and characterization of its role in Drosophila eye development

Bosdet, Ian Edward

11 1900

The precise structure of the adult Drosophila eye results from a coordinated process of cell sorting, differentiation and selective cell death in the retinal epithelium. Mutations in the gene echinus cause supernumerary pigment cells due to insufficient cell death. This study reports the identification of echinus and the characterization of its role in Drosophila retinal development. Using a combination of deletion mapping, gene expression analysis and genomic sequencing, echinus was cloned and several alleles were sequenced. echinus encodes a ~180kDa protein containing an ubiquitin hydrolase domain at its N-terminus and a polyglutamine tract at its C-terminus. echinus is expressed in the retina during pupal development and mutants of echinus have decreased levels of apoptosis during several stages of retinal development. Defects in the cell sorting process that precedes cell death are also observed in echinus loss-of-function mutants and echinus overexpression can cause defects in ommatidial rotation and the morphology of cone cells. echinus is a positive regulator of DE-cadherin and Enabled accumulation in adherens junctions of retinal epithelial cells. Genetic interactions were observed between echinus and the genes wingless, enabled and expanded. An immunofluorescence assay in Drosophila S2 cell cultured demonstrated that Echinus localizes to intracellular vesicles that do not appear to be endocytic in nature, and the C-terminal region of Echinus was shown to be necessary for this association. A protein interaction screen using an immunoprecipitation and mass spectrometry approach identified interactions between Echinus and the vesicle coat protein Clathrin, the scaffolding protein RACK1 and the casein kinase I epsilon (Dco). Co-immunoprecipitation additionally identified an interaction between Echinus and Enabled. This work has revealed echinus to be an important regulator of cell sorting and adherens junction formation in the developing retina and has identified multiple interactions between echinus and enabled, a regulator of the actin cytoskeleton. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Drosophila

Echinus

Cell adhesion

Programmed cell death

Retina development

Adherens junction

Cell sorting

The Role of mDia2 in Adherens Junctions in Epithelial Ovarian Cancer

Zhang, Yuqi

09 September 2019

No description available.

Medicine

Cellular Biology

Formin

mDia2

DIAPH3

Adherens Junction

Ovarian Cancer

catenin