Development of in vitro models of invasion for the pharmacological investigation of small molecule inhibitors of tumour progression. Development and validation of a 3-dimensional tumour spheroid invasion model to evaluate the pharmacological effects of novel small molecule β3 integrin antagonists.

Zraikat, Manar Saleh Ali

January 2015

Tumour dissemination is a major reason for failure of therapy for many tumour types therefore there is a requirement for novel targets & therapies. The αIIbβ3 and αvβ3 integrins have been demonstrated to have significant involvement at many stages of the tumour dissemination process including, tumour cell adhesion, migration, metastasis and angiogenesis, and thus the β3 integrins are a potential target for therapeutic antagonism with small molecules. Because of the clear interaction between the different integrin types, targeting integrins as a therapeutic strategy requires targeting more than one integrin type. Consequently, the ICT is developing a group of novel new αIIbβ3 and αvβ3 integrin dual antagonists. One of the main challenges is having a relevant, validated experimental model that expresses these integrins. The aim of the work presented here is to develop and validate an in vitro αIIbβ3 and αvβ3 integrin expressing assay of tumour cell invasion. The spheroid invasion assay has the advantage over standard monolayer transwell chamber invasion assays of being a 3-dimensional assay, and thus mimics better the cell-cell interactions and architecture that are present in a tumour compared to the monolayer-based assay. A panel of human cancer cell lines known to express one of the molecular targets of interest, αvβ3 integrin was evaluated for the ability to form spheroids and to invade through collagen matrices. One glioma cell line, U87-MG, demonstrated consistent spheroid formation and invasion and was thus selected for further studies. Optimum conditions were established for use of U87-MG in the invasion assay, and the assay was validated using a known inhibitor of invasion, LiCl and known β3 antagonist, cRGDfV. Subsequently a group of novel small molecule β3 antagonists were evaluated at nontoxic concentrations using the assay. Both LiCl and cRGDfV inhibited spheroid invasion through the gel in a dose-dependent manner, thus validating the assay. Furthermore, when the novel small molecule β3 antagonists were evaluated using the model, a dose and time dependent reduction in U87-MG spheroids invasion in collagen was observed. In further work initial steps were taken to construct a cell line which expresses both αIIbβ3 and αvβ3 integrin to use in the model to assess for dual integrin antagonism. In conclusion, this work has established a validated assay which has been utilised for some compounds to evaluate a group of novel small molecule β3 integrin antagonists with encouraging results.

Specific ECM Engagement Differentially Modulates T Cell Cytoskeletal Reorganization By Rho GTPases

Xue, Feng

January 2009

No description available.

Integrins

ECM

fibronectin

CELL

PBT

RHO GTPASES

GTPASES

Effect of alpha 2,6 Sialylation and Ionizing Radiation on Integrin-mediated Cell Adhesion and Cell Cycle Arrest

Yuan, Ye

January 2016

No description available.

Biochemistry

cell adhesion

integrins

sialylation

ECM

ionizing radiation

cell cycle

Biophysics and Biochemistry of Receptor-Ligand Mediated Adhesion to the Endothelium

Shinde Patil, Vivek R.

02 August 2002

No description available.

Engineering, Chemical

Biophysics

Cell adhesion

Endothelium

Particle size

Selectins and Integrins

Characterization of Novel Extracellular and Intracellular Modifiers of Apurinic/Apyrimidinic Endonuclease 1

Stevens, Rachel L.

08 September 2010

No description available.

Cellular Biology

Molecular Biology

Base Excision Repair

APE1, Integrins, PIN1

FAK Modulates Cell Adhesion Strengthening Via Two Distinct Mechanisms: Integrin Binding and Vinculin Localization

Michael, Kristin E.

16 November 2006

Cell adhesion to the extracellular matrix (ECM) provides tissue structure and integrity as well as triggers signals that regulate complex biological processes such as cell cycle progression and tissue-specific cell differentiation. Hence, cell adhesion is critical to numerous physiological and pathological processes, including embryonic development, cancer metastasis, and wound healing, as well as biotechnological applications, such as host responses to implanted devices and integration of tissue-engineered constructs. During the adhesion process, integrin surface receptors bind ECM proteins, cluster, and associate with the actin cytoskeleton. Subsequent strengthening of the integrin/actin cytoskeleton interaction occurs via complexes of proteins known as focal adhesions. Due to the close association between biochemical and biophysical processes within adhesion complexes, mechanical analyses can provide important new insights into structure/function relationships involved in regulating the adhesion process. The objective of this project was to investigate the role of the protein tyrosine kinase FAK in cell adhesion strengthening. Our central hypothesis was that FAK regulates adhesion strengthening by modulating interactions between integrins and FA structural components. Using a novel combination of genetically engineered cells to control the interactions of FAK, a spinning disk adhesion assay with micropatterned substrates to obtain reproducible and sensitive measurements of adhesion strength, and quantitative biochemical assays for analyzing changes in adhesive complexes, we demonstrate that FAK modulates adhesion strengthening via two distinct mechanisms: (1) FAK expression results in elevated integrin activation leading to regulation of strengthening rate and (2) FAK regulates steady-state adhesion strength via vinculin recruitment to focal adhesions. We also show that the autophosphorylation and catalytic sites of FAK are critical to this regulation of adhesion strengthening. This work is significant because it both identifies functional mechanisms of FAK and provides the first evidence that focal adhesion signaling regulates the adhesion strengthening process. Furthermore, this research demonstrates that the dependency of migration on adhesion strength is highly complex and establishes a need for adhesion strengthening metrics in analyzing the functional mechanisms of molecules within adhesion complexes.

Focal adhesion kinase

Extracellular matrix

Integrins

Cell adhesion

Cell mechanics

Force

Migration

Fibronectin

Extracellular matrix

Integrins

Fibronectins

Immobilized proteins

Focal adhesion kinase

Cell adhesion

The role of integrin-dependent cell matrix adhesion in muscle development /

Jani, Klodiana.

January 2009

Cell adhesion is essential to cell motility and tissue integrity and is regulated by the Integrin family of transmembrane receptors. Integrin binds to ligand extracellularly and provide anchor to the intracellular cytoskeleton via adhesion scaffolding proteins. In order to link cell to the surrounding matrix Integrin needs to be activated. Intracellular activation signals induce perturbations in Integrin cytoplasmic domain that are translated into a conformational change in extracellular region for high affinity ligand binding. Integrin engagement by matrix, in turn, triggers the assembly of adhesion complexes. Such early adhesions promote cytoskeletal organization with subsequent contractile activity that exerts forces against initial Integrin-matrix adhesions. In response to force, Integrin strengthens the interaction with matrix through its clustering and successive recruitment of additional adhesion components. These bidirectional regulatory loops mediated by such interactions are largely dependent on the unique function of Integrin adhesion components. / We demonstrate a novel role for the PDZ/LIM domain protein Zasp as a core component of Integrin adhesions. Specifically, Zasp colocalizes with Integrins at focal adhesion in cultured cells and myotendinous junctions in Drosophila embryos. In both cases elimination of Zasp modifies Integrin function causing consequently defects in cell spreading and muscle attachment. Zasp supports Integrin adhesion to the extracellular matrix that is required to withstand tensile forces exerted during cell spreading and muscle contraction. Furthermore, we found that the distribution of Zasp in muscle Z-lines is essential to orchestrate the cross-linking of alpha-Actinin and Actin filaments. Disruption of Zasp leads to loss of muscle cytoarchitecture, pointing to a larger role for Zasp in sarcomere assembly. Finally, we demonstrate that Zasp, in addition to alpha-Actinin, physically interacts with the Integrin- and Actin-bound cytoskeletal protein Talin. / Collectively, our results point to a dual role for Zasp as a structural scaffold. First it regulates Integrin adhesion to the extracellular matrix by interacting with the head domain of Talin at the myotendinous junctions. Second, Zasp controls sarcomere assembly by tethering the presarcomeric alpha-Actinin component to the tail domain of Talin. Zasp finding as a crucial adhesion component provides further insights on the mechanism underlying Integrin-mediated adhesion.

Striated muscle -- Metabolism.

Integrins -- Metabolism.

Cell adhesion.

Muscle, Skeletal -- metabolism.

Integrins -- metabolism.

Drosophila Proteins -- metabolism.

Carrier Proteins -- metabolism.

Cell Adhesion -- physiology.

Zeb2 as a regulator of adhesion interplay in the developing mouse neocortex

Epifanova, Ekaterina

23 February 2022

Der menschliche Neokortex wird als Hauptsitz kognitiver Funktionen höherer Ordnung angesehen. Das Verständnis der neokortikalen Entwicklung anderer Säugetierarten ist von wesentlicher Bedeutung, um die menschliche Gehirnorganisation im Allgemeinen und neurologische Entwicklungsstörungen im Speziellen besser zu verstehen. In dieser Arbeit habe ich die Rolle des mit dem Mowat-Wilson-Syndrom assoziierten Transkriptionsfaktors Zeb2 in der neokortikalen Entwicklung der Maus untersucht. Ich habe nachgewiesen, dass Zeb2 die Adhäsion neugeborener kortikaler Neurone sowohl vor als auch nach der radialen Migration über zwei unabhängige molekulare Wege reguliert. Hierbei konnte ich zeigen, dass die Adhäsion im Vorfeld der radialen Migration über den molekularen Zeb2-Nrp1-Itgβ1- Weg reguliert wird. Zeb2 unterdrückt zell-intrinsisch die neuronale Adhäsion an die extrazelluläre Matrix und kontrolliert dadurch den Beginn der radialen Migration, die Dauer des multipolaren Stadiums sowie die Motilität multipolarer Neurone, ohne die radiale Migration selbst oder das spätere Zellschicksal innerhalb der kortikalen Schichten zu beeinflussen. Hierbei sind die apikalen Dendriten der Neurone normalerweise parallel zueinander und senkrecht zur Hirnhautoberfläche ausgerichtet. Ich habe gezeigt, dass die Ausrichtung der Neurone im Anschluss an ihre Migration von der Adhäsion der Zellen untereinander sowie zur extrazellulären Matrix abhängt und dieser Prozess unabhängig von der radialen Migration erfolgt. Zeb2 koordiniert das gesamt e Repertoire dieser postmigratorischen Adhäsion über den molekularen Zeb2-Cdh6-Itgβ1-Weg. Zusammenfassend zeigt diese Studie die Bedeutung der neuronalen Adhäsion während der neokortikalen Entwicklung auf und entschlüsselt die Regulationsmechanismen für die Initiierung der radialen Migration sowie für die postmigratorische Orientierung der Neurone der oberen kortikalen Schichten. / The human brain is a highly sophisticated biological structure and its formation is a highly orchestrated process. The human neocortex, in particular, is the main place of higher-order cognitive functions. Understanding the neocortical development of other mammalian species is essential for understanding brain organisation in common neurodevelopmental disorders in particular. Here I studied the role of Mowat-Wilson syndrome-associated transcription factor Zeb2 in mouse neocortical development. I have shown in this study that Zeb2 regulates adhesion of new born cortical neurons both before and after radial locomotion via two independent molecular pathways. I have shown that adhesion prior to radial locomotion is tightly regulated via Zeb2-Nrp1-Itgβ1 molecular pathway. Zeb2 cell-intrinsically suppresses adhesion of neurons to the extracellular matrix and therefore restricts the initiation of radial locomotion, multipolar stage duration and motility of multipolar neurons without affecting radial locomotion itself and layer cell fate acquisition. Once radial migration is finished neurons have to form apical dendrite and establish contact with the meningeal surface. Normally, apical dendrites of neurons are oriented parallel to each other and perpendicular to the meningeal surface. I have shown that postmigratory orientation of neurons is dependent on cell-to-cell and cell-to-extracellular matrix adhesion and occurs independently from radial migration. Zeb2 orchestrates the whole repertoire of adhesion of neurons completed radial migration via Zeb2-Cdh6-Itgβ1 molecular pathway. I have demonstrated that Cadherin 6 balance is crucial for establishment of postmigratory neuronal orientation under normal conditions. Taken together, this study has revealed the importance of neuronal adhesion during neocortical development and separated the regulation mechanisms for initiation of radial migration and postmigratory orientation of upper layer neurons.

Entwicklung des Neokortex

Zeb2

Neuronalen Adhäsion

Nrp1

Cdh6

Integrins

Neocortical development

Zeb2

Neuronal adhesion

Nrp1

Cdh6

Integrins

570 Biologie

WX 6501

WX 6504

WW 3880

WW 2520

ddc:570

The role of integrin-dependent cell matrix adhesion in muscle development /

Jani, Klodiana.

January 2009

No description available.

Cell adhesion.

Integrins -- Metabolism.

Striated muscle -- Metabolism.

Integrins -- metabolism.

Carrier Proteins -- metabolism.

Drosophila Proteins -- metabolism.

Cell Adhesion -- physiology.

Muscle, Skeletal -- metabolism.

Prostate transglutaminase (TGase-4, TGaseP) enhances the adhesion of prostate cancer cells to extracellular matrix, the potential role of TGase-core domain

Jiang, Wen, Ye, Lin, Sanders, Andrew, Ruge, Fiona, Kynaston, Howard, Ablin, Richard, Mason, Malcolm

January 2013

BACKGROUND:Transglutaminase-4 (TGase-4), also known as the Prostate Transglutaminase, is an enzyme found to be expressed predominately in the prostate gland. The protein has been recently reported to influence the migration and invasiveness of prostate cancer cells. The present study aimed to investigate the influence of TGase-4 on cell-matrix adhesion and search for the candidate active domains] within the protein.METHODS:Human prostate cancer cell lines and prostate tissues were used. Plasmids that encoded different domains and full length of TGase-4 were constructed and used to generate sublines that expressed different domains. The impact of TGase-4 on in vitro cell-matrix adhesion, cell migration, growth and in vivo growth were investigated. Interactions between TGase-4 and focal adhesion complex proteins were investigated using immunoprecipitation, immunofluorescence and phosphospecific antibodies.RESULTS:TGase-4 markedly increased cell-matrix adhesion and cellular migration, and resulted in a rapid growth of prostate tumours in vivo. This effect resided in the Core-domain of the TGase-4 protein. TGase-4 was found to co-precipitate and co-localise with focal adhesion kinase (FAK) and paxillin, in cells, human prostate tissues and tumour xenografts. FAK small inhibitor was able to block the action mediated by TGase-4 and TGase-4 core domain.CONCLUSION:TGase-4 is an important regulator of cell-matrix adhesion of prostate cancer cells. This effect is predominately mediated by its core domain and requires the participation of focal adhesion complex proteins.

Transglutaminase

Transglutaminase-4

Cell-matrix adhesion

Focal adhesion kinase

Paxillin

Integrins

Electric cell sensing

Prostate cancer