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The massive remodeling of the heart tissue, as observed in response to pressure overload or myocardial infarction, is considered to play a causative role in the development of heart failure. Alterations in the heart architecture clearly affect the mechanical properties of the heart muscle, but they are rooted in changes at the cellular level including modulation of gene expression. Together with integrins, the transmembrane receptors linking the extracellular environment to the cytoskeleton, extracellular matrix (ECM) proteins and matricellular proteins are key components of the remodeling process in the heart. Therefore, this thesis was aimed at analysing the role of integrins in the regulation of gene expression and heart muscle performance during cardiac wound repair induced by pressure overload or myocardial infarction (MI). To investigate the contribution of integrin Beta 1, we characterised the response of mice with a conditional, cardiac-specific deletion of the integrin Beta 1 gene in an experimental model of pressure overload by aortic banding (AB). In particular, we measured physiological alterations and gene expression events in the stressed heart in the presence or absence of integrin Beta 1. Interestingly, mice containing a knock-out allele and the ventricular myocyte-specific conditional allele of the integrin Beta 1 gene were born and grew up to adulthood. Though these animals still exhibited minor amounts of integrin Beta1 in the heart (expressed by non-myocytes), these mice displayed abnormal cardiac function and were highly sensitive to AB. Whereas a compensatory hypertrophic response to pressure overload was observed in wildtype mice, the integrin Beta 1-deficient mice were not able to undergo heart tissue remodeling. Furthermore, ECM gene expression was altered and, in particular, the increased expression of the matricellular protein SPARC after AB was abolished in integrin Beta 1–deficient mice. Interestingly, we also found a transient upregulation of SPARC mRNA during heart remodeling after MI using cDNA macroarrays. Indeed, increased SPARC protein levels were observed starting at day 2 (2.55±0.21fold, p<0.01), day 7 (3.72±0.28 fold, p<0.01) and 1 month (1.9±0.16 fold, p<0.01) after MI, which could be abolished by using an integrin alpha v inhibitor in vivo. Immunofluorescence analysis of heart tissue demonstrated that the increased SPARC expression was confined to the infarcted area and occurred together with the influx of fibroblasts into the heart. In vitro, either TGF-Beta 1 or PDGF-BB stimulated SPARC expression by fibroblasts. Inhibition of integrin alpha v did not interfere with TGF-Beta1 or PDGF induced SPARC secretion as determined by ELISA assays or Western blot. However, secretion of TGF-Beta1 and PDGF-BB by cardiomyocytes was induced by vitronectin, a ligand of integrin alpha v, and this response was blocked by the integrin alpga v inhibitor. Functionally, SPARC modulated the migratory response of fibroblasts towards ECM proteins suggesting that the local deposition of SPARC following MI contributes to scar formation. Taken together, our combined in vivo and in vitro data demonstrate that several integrin subunits play critical roles during tissue remodeling in the injured heart. Integrin-dependent gene expression events such as the upregulation of SPARC following MI are critical to orchestrate the healing response. These processes appear to involve complex cross-talk between different cell types such as cardiomyocytes and fibroblasts to allow for locally confined scar formation. The elucidation of the sophisticated interplay between integrins, matricellular proteins such as SPARC, and growth factors will undoubtedly provide us with a better and clinically useful understanding of the molecular mechanisms governing heart remodeling.
Pfadbildung durch invasive Melanomzellen : Matrixdefekte, Zellfragmente und erleichterte Migration
(2006)
Die metastatische Invasion von Tumorzellen durch die extrazelluläre Matrix von Geweben erfordert aktive Zellmigration sowie häufig auch den Umbau der Gewebestruktur. In dieser Arbeit sollte mittels metastasierender MV3-Melonomzellen in einem 3D-Kollagenmatrixmodell der migrationsassozierte Matrixumbau zellulär und molekular untersucht werden, insbesondere die physikalische Charakterisierung gebildeter Matrixdefekte, die molekulare Identifi kation freigesetzter Zellbestandteile, sowie den Einfluß pfadbildender Zellen auf die Invasion nachfolgender Zellen. Die Daten zeigen, daß MV3-Melanomzellen während der Migration durch ein 3DKollagengewebe komplette Zellfragmente in zurückbleibenden röhrenförmigen Trassen deponieren. Diese beinhalteten Zytoplasma und teils Zytoskelett umgeben von intakter Zellmembran mit integrierten Oberflächenrezeptoren wie β1-Integrinen, nicht jedoch DNA-Material. Der Durchmesser der Fragmente lag überwiegend bei 1-5 μm, selten über 10 μm, entsprechend unspezifisch freigesetzter Zellfragmente, die während der Migration vom Zellhinterende abgeschilftet werden. In einem Sphäroidmodell ließen sich mehrere Invasionsfronten nachweisen, in denen einer ersten pfadbildenden Zelle entlang neu gebildeter Matrixtrassen weitere Zellen den gleichen präformierten Trassen folgten. Die videomikroskopischen Befunde wurden mittels Konfokalmikroskopie bestätigt. Eine erwartete höhere Migrationsgeschwindigkeit der nachfolgenden Zellen in dem präformierten Pfad bestätigte sich jedoch nicht. Somit führt die Invasion von MV3-Melanomzellen zur Ausbildung strukturell umgebauter Matrixtrassen, die aus Matrixdefekt freigesetzten Zellfragmenten und angrenzender Extrazellulärmatrix bestehen und nachfolgenden Zellen als Leitstruktur für eine orientierte Form der Invasion dienen (Kettenwanderung). Diese Befunde beleuchten die Dynamik von Zellarrangements ähnlich dem Invasionsmuster in histopathologischen Tumorproben.