@phdthesis{Alexander2019,
  author    = {Alexander, Stephanie},
  title     = {Collective cancer cell invasion \(in\) \(vivo\): function of β1 and β3 integrins in perivascular invasion and resistance to therapy},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85435},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {Pro-migratory signals mediated by the tumor microenvironment contribute to the cancer progression cascade, including invasion, metastasis and resistance to therapy. Derived from in vitro studies, isolated molecular steps of cancer invasion programs have been identified but their integration into the tumor microenvironment and suitability as molecular targets remain elusive. The purpose of the study was to visualize central aspects of tumor progression, including proliferation, survival and invasion by real-time intravital microscopy. The specific aims were to monitor the kinetics, mode, adhesion and chemoattraction mechanisms of tumor cell invasion, the involved guidance structures, and the response of invasion zones to anti-cancer therapy. To reach deeper tumor regions by optical imaging with subcellular resolution, near-infrared and infrared excited multiphoton microscopy was combined with a modified dorsal skinfold chamber model. Implanted HT-1080 fibrosarcoma and B16/F10 and MV3 melanoma tumors developed zones of invasive growth consisting of collective invasion strands that retained cell-cell contacts and high mitotic activity while invading at velocities of up to 200 μm per day. Collective invasion occurred predominantly along preexisting tissue structures, including blood and lymph vessels, collagen fibers and muscle strands of the deep dermis, and was thereby insensitive to RNAi based knockdown and/or antibody-based treatment against β1 and β3 integrins, chemokine (SDF-1/CXCL12) and growth factor (EGF) signaling. Therapeutic hypofractionated irradiation induced partial to complete regression of the tumor main mass, yet failed to eradicate the collective invasion strands, suggesting a microenvironmentally privileged niche. Whereas no radiosensitization was achieved by interference with EGFR or doxorubicin, the simultaneous inhibition of β1 and β3 integrins impaired cell proliferation and survival in spontaneously growing tumors and strongly enhanced the radiation response up to complete eradication of both main tumor and invasion strands. In conclusion, collective invasion in vivo is a robust process which follows preexisting tissue structures and is mainly independent of established adhesion and chemoattractant signaling. Due to its altered biological response to irradiation, collective invasion strands represent a microenvironmentally controlled and clinically relevant resistance niche to therapy. Therefore supportive regimens, such as anoikisinduction by anti-integrin therapy, may serve to enhance radio- and chemoefficacy and complement classical treatment regimens.},
  subject      = {Tumorzelle},
  language  = {en}
}
@phdthesis{Adae2009,
  author    = {Adae, Jasmin},
  title     = {Interaktion von malignen Tumorzellen mit extrazellul{\"a}rer Matrix und Migration: Rolle von Rac und ROCK},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-52894},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2009},
  abstract  = {Auf dem Weg vom Prim{\"a}rtumor zur systemischen Metastasierung, der Haupttodesursache von Krebserkrankungen, ist die Einzelzellmigration von Tumorzellen durch dreidimensionales Bindegewebe ein entscheidender Schritt. Die vorliegende Arbeit zeigt Untersuchungen zur Tumorzellmigration und -plastizit{\"a}t in einem 3D-Migrationsmodell. Kleine G-Proteine kontrollieren Zytoskelettfunktionen, insbesondere Aktinpolymerisation und die Bildung von Zellprotrusionen durch Rac sowie Actomyosinkontraktion durch Rho. Durch pharmakologische Inhibitoren von Rac und dem Rho-Effektor ROCK soll deren Bedeutung f{\"u}r Einzelzellmigration in einem dreidimensionalen Modell und vor allem der Effekt auf Morphologie, Plastizit{\"a}t und Migration von Tumorzellen gekl{\"a}rt werden. Nach Inhibition von ROCK zeigen hochinvasive HT1080 Fibrosarkomzellen einen multipolar-dendritischen und sessilen Ph{\"a}notyp. Nach Hemmung von Rac wird hingegen ein rundlicher, aber ebenfalls apolarer und sessiler Ph{\"a}notyp induziert. Bei simultaner Inhibition von Rac und ROCK entstehen rundliche, apolare, sessile Zellen mit abortiven Pseudopodien. Wird das Gleichgewicht von Rac und ROCK durch konstitutive Aktivierung von ROCK gest{\"o}rt, so entsteht eine zweigeteilte Population, bestehend aus rundlichen Zellen, die Blebs bilden, und langgezogenen Zellen. Nach Sortierung nach ihrem ß1-Integrinexpressionsniveau zeigten Zellen mit niedriger Integrin-Expression einen rundlichen Migrationstyp mit blasenartigen dynamischen Protrusionen, w{\"a}hrend Zellen mit hoher Integrin-Expression langgezogen-mesenchymal migrierten. Somit steuern ROCK und Rac gemeinsam und zeitgleich die mesenchymale Einzelzellmigration. W{\"a}hrend Rac Protrusion vermittelt, ist ROCK f{\"u}r Kontraktilit{\"a}t und Retraktion verantwortlich. Erst durch Koordination von Rac und Rho/ROCK entsteht somit Polarit{\"a}t und 3D mesenchymale Migration.},
  subject      = {Zellmigration},
  language  = {de}
}
@phdthesis{Mayer2006,
  author    = {Mayer, Christian},
  title     = {Pfadbildung durch invasive Melanomzellen : Matrixdefekte, Zellfragmente und erleichterte Migration},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-19657},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2006},
  abstract  = {Die metastatische Invasion von Tumorzellen durch die extrazellul{\"a}re Matrix von Geweben erfordert aktive Zellmigration sowie h{\"a}ufig auch den Umbau der Gewebestruktur. In dieser Arbeit sollte mittels metastasierender MV3-Melonomzellen in einem 3D-Kollagenmatrixmodell der migrationsassozierte Matrixumbau zellul{\"a}r 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 w{\"a}hrend der Migration durch ein 3DKollagengewebe komplette Zellfragmente in zur{\"u}ckbleibenden r{\"o}hrenf{\"o}rmigen Trassen deponieren. Diese beinhalteten Zytoplasma und teils Zytoskelett umgeben von intakter Zellmembran mit integrierten Oberfl{\"a}chenrezeptoren wie \&\#946;1-Integrinen, nicht jedoch DNA-Material. Der Durchmesser der Fragmente lag {\"u}berwiegend bei 1-5 \&\#956;m, selten {\"u}ber 10 \&\#956;m, entsprechend unspezifisch freigesetzter Zellfragmente, die w{\"a}hrend der Migration vom Zellhinterende abgeschilftet werden. In einem Sph{\"a}roidmodell ließen sich mehrere Invasionsfronten nachweisen, in denen einer ersten pfadbildenden Zelle entlang neu gebildeter Matrixtrassen weitere Zellen den gleichen pr{\"a}formierten Trassen folgten. Die videomikroskopischen Befunde wurden mittels Konfokalmikroskopie best{\"a}tigt. Eine erwartete h{\"o}here Migrationsgeschwindigkeit der nachfolgenden Zellen in dem pr{\"a}formierten Pfad best{\"a}tigte sich jedoch nicht. Somit f{\"u}hrt die Invasion von MV3-Melanomzellen zur Ausbildung strukturell umgebauter Matrixtrassen, die aus Matrixdefekt freigesetzten Zellfragmenten und angrenzender Extrazellul{\"a}rmatrix bestehen und nachfolgenden Zellen als Leitstruktur f{\"u}r eine orientierte Form der Invasion dienen (Kettenwanderung). Diese Befunde beleuchten die Dynamik von Zellarrangements {\"a}hnlich dem Invasionsmuster in histopathologischen Tumorproben.},
  language  = {de}
}
@phdthesis{Wolf2002,
  author    = {Wolf, Katarina},
  title     = {Migration of tumor cells and leukocytes in extracellular matrix : proteolytic and nonproteolytic strategies for overcoming tissue barriers},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-5670},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2002},
  abstract  = {The extracellular matrix within connective tissues represents a structural scaffold as well as a barrier for motile cells, such as invading tumor cells or passenger leukocytes. It remains unclear how different cell types utilize matrix-degrading enzymes for proteolytic migration strategies and, on the other hand, non-proteolytic strategies to overcome 3D fibrillar matrix networks. To monitor cell migration, a 3D collagen model in vitro or the mouse dermis in vivo were used, in combination with time-lapse video-, confocal- or intravital multiphoton-microscopy, and computer-assisted cell tracking. Expression of proteases, including several MMPs, ADAMs, serine proteases and cathepsins, was shown by flow cytometry, Western blot, zymography, and RT-PCR. Protease activity by migrating HT-1080 fibrosarcoma cells resulting in collagenolysis in situ and generation of tube-like matrix defects was detected by three newly developed techniques:(i) quantitative FITC-release from FITC-labelled collagen, (ii) structural alteration of the pyhsical matrix structure (macroscopically and microscopically), and (iii) the visualization of focal in situ cleavage of individual collagen fibers. The results show that highly invasive ollagenolytic cells utilized a spindle-shaped "mesenchymal" migration strategy, which involved beta1 integrindependent interaction with fibers, coclustering of beta1 integrins and matrix metalloproteinases (MMPs) at fiber bundling sites, and the proteolytic generation of a tube-like matrix-defect by MMPs and additional proteases. In contrast to tumor cells, activated T cells migrated through the collagen fiber network by flexible "amoeboid" crawling including a roundish, elliptoid shape and morphological adaptation along collagen fibers, which was independent of collagenase function and fiber degradation. Abrogation of collagenolysis in tumor cells was achieved by a cocktail of broad-spectrum protease inhibitors at non-toxic conditions blocking collagenolysis by up to 95\%. While in T cells protease inhibition induced neither morphodynamic changes nor reduced migration rates, in tumor cells a time-dependent conversion was obtained from proteolytic mesenchymal to non-proteolytic amoeboid migration in collagen lattices in vitro as well as the mouse dermis in vivo monitored by intravital microscopy. Tumor cells vigorously squeezed through matrix gaps and formed constriction rings in regions of narrow space, while the matrix structure remained intact. MMPs were excluded from fiber binding sites and beta1 integrin distribution was non-clustered linear. Besides for fibrosarcoma cells, this mesenchymal-toameboid transition (MAT) was confirmed for epithelial MDA-MB-231 breast carcinoma cells. In conclusion, cells of different origin exhibit significant diversity as well as plasticity of protease function in migration. In tumor cells, MAT could respresent a functionally important cellular and molecular escape pathway in tumor invasion and migration.},
  subject      = {Zellmigration},
  language  = {en}
}