Elastic interactions of cellular force patterns / Elastic interactions of cellular force patterns

Bischofs, Ilka Bettina

January 2004

Gewebezellen sammeln ständig Informationen über die mechanischen Eigenschaften ihrer Umgebung, indem sie aktiv an dieser ziehen. Diese Kräfte werden an Zell-Matrix-Kontakten übertragen, die als Mechanosensoren fungieren. Jüngste Experimente mit Zellen auf elastischen Substraten zeigen, dass Zellen sehr empfindlich auf Veränderungen der effektiven Steifigkeit ihrer Umgebung reagieren, die zu einer Reorganisation des Zytoskeletts führen können. In dieser Arbeit wird ein theoretisches Model entwickelt, um die Selbstorganisation von Zellen in weichen Materialien vorherzusagen. Obwohl das Zellverhalten durch komplexe regulatorische Vorgänge in der Zelle gesteuert wird, scheint die typische Antwort von Zellen auf mechanische Reize eine einfache Präferenz für große effektive Steifigkeit der Umgebung zu sein, möglicherweise weil in einer steiferen Umgebung Kräfte an den Kontakten effektiver aufgebaut werden können. Der Begriff Steifigkeit umfasst dabei sowohl Effekte, die durch größere Härte als auch durch elastische Verzerrungsfelder in der Umgebung verursacht werden. Diese Beobachtung kann man als ein Extremalprinzip in der Elastizitätstheorie formulieren. Indem man das zelluläre Kraftmuster spezifiziert, mit dem Zellen mit ihrer Umgebung wechselwirken, und die Umgebung selbst als linear elastisches Material modelliert, kann damit die optimale Orientierung und Position von Zellen vorhergesagt werden. Es werden mehrere praktisch relevante Beispiele für Zellorganisation theoretisch betrachtet: Zellen in externen Spannungsfeldern und Zellen in der Nähe von Grenzflächen für verschiedene Geometrien und Randbedingungen des elastischen Mediums. Dafür werden die entsprechenden elastischen Randwertprobleme in Vollraum, Halbraum und Kugel exakt gelöst. Die Vorhersagen des Models stimmen hervorragend mit experimentellen Befunden für Fibroblastzellen überein, sowohl auf elastischen Substraten als auch in physiologischen Hydrogelen. Mechanisch aktive Zellen wie Fibroblasten können auch elastisch miteinander wechselwirken. Es werden daher optimale Strukturen als Funktion von Materialeigenschaften und Zelldichte bzw. der Geometrie der Zellpositionen berechnet. Schließlich wird mit Hilfe von Monte Carlo Simulationen der Einfluss stochastischer Störungen auf die Strukturbildung untersucht. Das vorliegende Model trägt nicht nur zu einem besseren Verständnis von vielen physiologischen Situationen bei, sondern könnte in Zukunft auch für biomedizinische Anwendungen benutzt werden, um zum Beispiel Protokolle für künstliche Gewebe im Bezug auf Substratgeometrie, Randbedingungen, Materialeigenschaften oder Zelldichte zu optimieren. / Adherent cells constantly collect information about the mechanical properties of their extracellular environment by actively pulling on it through cell-matrix contacts, which act as mechanosensors. In recent years, the sophisticated use of elastic substrates has shown that cells respond very sensitively to changes in effective stiffness in their environment, which results in a reorganization of the cytoskeleton in response to mechanical input. We develop a theoretical model to predict cellular self-organization in soft materials on a coarse grained level. Although cell organization in principle results from complex regulatory events inside the cell, the typical response to mechanical input seems to be a simple preference for large effective stiffness, possibly because force is more efficiently generated in a stiffer environment. The term effective stiffness comprises effects of both rigidity and prestrain in the environment. This observation can be turned into an optimization principle in elasticity theory. By specifying the cellular probing force pattern and by modeling the environment as a linear elastic medium, one can predict preferred cell orientation and position. Various examples for cell organization, which are of large practical interest, are considered theoretically: cells in external strain fields and cells close to boundaries or interfaces for different sample geometries and boundary conditions. For this purpose the elastic equations are solved exactly for an infinite space, an elastic half space and the elastic sphere. The predictions of the model are in excellent agreement with experiments for fibroblast cells, both on elastic substrates and in hydrogels. Mechanically active cells like fibroblasts could also interact elastically with each other. We calculate the optimal structures on elastic substrates as a function of material properties, cell density and the geometry of cell positioning, respectively, that allows each cell to maximize the effective stiffness in its environment due to the traction of all the other cells. Finally, we apply Monte Carlo simulations to study the effect of noise on cellular structure formation. The model not only contributes to a better understanding of many physiological situations. In the future it could also be used for biomedical applications to optimize protocols for artificial tissues with respect to sample geometry, boundary condition, material properties or cell density.

Physics

The Tyrosine Kinase GTK : Signal Transduction and Biological Function

Annerén, Cecilia

January 2001

Protein tyrosine kinases play an important role in the regulation of various cellular processes such as growth, differentiation and survival. GTK, a novel SRC-like cytoplasmic tyrosine kinase, was recently cloned from a mouse insulinoma cell line and the present work was conducted in order to find a biological function of GTK in insulin producing and neuronal cells. It was observed that kinase active GTK-mutants, expressed in RINm5F cells, transferred to the cell nucleus and increased the levels of the cell cycle regulatory protein p27KIP1, reduced cell growth and stimulated glucagon mRNA expression. Furthermore, wild type GTK induces neurite outgrowth in the rat adrenal pheochromocytoma PC12 cell line, through activation of the RAP1-pathway, suggesting a role of GTK for cell differentiation. Studies using transgenic mice, expressing GTK under the control of the rat insulin 1 promoter, demonstrated a dual role of GTK for β-cell growth: Whereas GTK increases the β-cell mass and causes enhanced β-cell proliferation in response to partial pancreatectomy it also induced β-cell death in response to proinflammatory cytokines and impaired the glucose tolerance in mice treated with the β-cell toxin streptozotocin suggesting a possible role of GTK for β-cell destruction in Type 1 diabetes. We have also observed that GTK-transgenic islets and GTK-expressing RINm5F cells exhibit a reduced insulininduced activation of the insulin receptor substrate (IRS-1 and IRS-2)-pathways, partly due to an increased basal activity of these. GTK was found to associate with and phosphorylate the SH2 domain adapter protein SHB, which could explain many of the GTK-dependent effects both in vitro and in vivo. In summary, the present work suggests that the novel tyrosine kinase GTK is involved in various signal transduction pathways, regulating different cellular responses, such as proliferation, differentiation and survival.

Cell biology

Protein tyrosine kinases

GTK

SHB

proliferation

survival

differentiation

β cells

pancreatectomy

cytokines

diabetes

PC12 cells

NGF

streptozotocin

focal adhesion kinase

RAP1

Cellbiologi

Cell biology

Cellbiologi

Molecular Mechanisms of Action of Histidine-rich Glycoprotein in Angiogenesis Inhibition

Lee, Chunsik

January 2006

Angiogenesis, de novo synthesis of blood vessels from the pre-existing vasculature, is required both during embryonic development and in pathophysiological conditions. In particular, tumor growth needs new capillary vessels in order to both deliver oxygen and nutrients and to remove toxin and metabolites. Growth of most solid tumors would be restricted to a microscopic size in the absence of neovascularization. Angiogenesis ensues as a result of a shift in the balance between pro- and anti-angiogenic molecules. Histidine-rich glycoprotein (HRGP) is a heparin-binding plasma protein. We showed that HRGP inhibits endothelial cell migration and adhesion to vitronectin. As a consequence, HRGP attenuates growth and vascularization of mouse model tumors. The anti-angiogenic effect of HRGP is mediated by the central histidine/proline (His/Pro)-rich domain, which must be released from the parent molecule to exert its effect. A 35-amino acid residue peptide denoted HRGP330, derived from the His/Pro-rich domain, was identified as a minimal active anti-angiogenic domain of HRGP. HRGP330 induces disruption of molecular interactions required for cell motility, such as the integrin-linked kinase/paxillin complex. Moreover, HRGP330 inhibits VEGF-induced tyrosine phosphorylation of α-actinin, a focal adhesion kinase (FAK) substrate. Consequently, the motility of endothelial cells is arrested. By use of a signal transduction antibody array, we identified FAK, paxillin and growth factor receptor-bound 2 (Grb2) as tyrosine phosphorylated in HRGP330-treated cells. We confirmed that HRGP targets focal adhesions in endothelial cells, thereby disrupting the cytoskeletal organization and the ability of endothelial cells to assemble into vessel structures. A critical role of FAK in HRGP-inhibition of angiogenesis was validated using a FAK inhibitor, geldanamycin, which allowed rescue of endothelial cell actin rearrangement. We identified another potential mechanism in the HRGP/HRGP330 anti-angiogenic effects, exerted through regulation of tumor-associated macrophages (TAMs). HRGP/HRGP330 treatment led to reduced TAM infiltration, which in turn caused a marked decrease in VEGF and MMP-9 levels in the tumor. Taken together, our present studies show that HRGP/HRGP330 target endothelial cell adhesion, migration, focal adhesions, and furthermore, that HRGP is involved in regulation of macrophage infiltration.

Cell and molecular biology

anti-angiogenesis

angiogenesis inhibitor

endothelial cell

histidine-rich glycoprotein

focal adhesion

tumor-associated macrophages

VEGF

MMP

Cell- och molekylärbiologi

Study of marrow microenvironment and focal adherences in myelodysplastic syndromes and leukemias

Robu, Carmen Mariana

12 March 2012

Myelodysplastic syndromes (MDS) are regarded as clonal disorders of haematopoietic stem cells (HSC). Recent evidence demonstrates that stromal microenvironment, in addition to HSC defects, plays a particular role via its direct contact with haematopoietic precursor cells (HPC). This thesis aims at evaluating the putative growth deficiencies of mesenchymal stromal cells (MSC) from MDS individuals compared with normal controls, exploring their adhesion profile, assessing the adhesion process-involved molecular substrates, and establishing correlations with their growth patterns and HPC dysfunctions. Functional assays revealed that MSC from MDS are intrinsically pathological, show a continuous decline of proliferation over a 14-day culture and a reduced clonogenic capacity in the absence of signals from HPC. MSC growth defects significantly correlate with decreased CD44 and CD49e expression. Moreover, stroma-dependent adhesion mechanisms control HPC clonogenic potential and CD49e might be one of the molecules involved in this process. Qualitative and quantitative abnormalities of focal adhesion (FA) proteins paxillin and pFAK [Y397] and of two regulatory proteins, HSP90αβ and p130CAS were identified via immunofluorescence analysis. Paxillin, pFAK [Y397] and HSP90αβ increased expression, besides its stronger nuclear colocalization in MSC from RAEB correlates with a consistent proliferative advantage and has a negative impact on HPC clonogenic capacity. These results open interesting opportunities, e.g. HPC-to-MSC interactions involve FA proteins signalling, and, as FAK is an HSP90αβ-client protein, it may enhance the utility of HSP90αβ inhibitors as adjuvant therapy in MDS

Myelodisplastic syndromes

Refractory aneamia with excess blasts

Mesenchymal stroma cells

Focal adhesion proteins

Paxillin

Growth patterns

Focal adhesion kinase signaling spatially regulates adhesion dynamics in fibroblasts

Iwanicki, Marcin P.

January 2008

Thesis (Ph. D.)--University of Virginia, 2008. / Title from title page. Includes bibliographical references. Also available online through Digital Dissertations.

Avaliação imunohistoquímica das alterações do citoesqueleto na parede alveolar em modelo experimental de lesão pulmonar induzida pela ventilação mecânica em ratos / Immunohistochemical evaluation of the cytoskeletal alterations in the alveolar wall in an experimental model of ventilator-induced lung injury in rats

Leandro Utino Taniguchi

14 September 2009

INTRODUÇÃO: A ventilação mecânica é uma terapia importante, mas com possíveis complicações. Uma das mais relevantes é a lesão pulmonar induzida pelo ventilador (VILI do inglês Ventilator-induced lung injury). Devido à hiperdistensão alveolar, o pulmão inicia um processo inflamatório, com infiltrado neutrofílico, formação de membrana hialina, fibrogênese e prejuízo de troca gasosa. Nesse processo, a mecanotransdução do estímulo da hiperdistensão celular se faz através do citoesqueleto da célula e de suas interações com a matriz extracelular e com as células vizinhas. Apesar desse papel fundamental no processo da VILI, não existem estudos in vivo sobre as alterações do citoesqueleto e de suas proteínas associadas durante esse processo patológico. O objetivo desse estudo foi descrever as alterações no citoesqueleto e em duas de suas principais proteínas associadas (FAK e paxilina) durante esse processo. MÉTODOS: Nesse estudo experimental foram feitos três grupos (n = 4 6): um controle e dois ventilados por quatro horas com PEEP de 5 cmH2O. Um grupo foi ventilado com volume corrente de 8 ml/kg (BV) e o outro com 24 ml/kg (AV). Dados de mecânica respiratória foram calculados no início e no final do período experimental. Os pulmões foram avaliados por histomorfometria quanto à área proporcional de parênquima, índice de infiltrado neutrofílico e índice de edema perivascular, quanto à quantidade de fosfo-FAK, fosfo-paxilina, paxilina total, actina músculo liso e alfa-tubulina por Western Blot, quanto à imunofluorescência para paxilina total com microscopia confocal a laser e com microscopia eletrônica de transmissão. RESULTADOS: os grupos foram semelhantes nas características basais. Houve aumento da elastância dinâmica (Edin) no grupo BV e redução no grupo AV (Edin inicial e final: 0,76 ± 0,4 vs 1,02 ± 0,47 respectivamente, em cmH2O/ml; p = 0,001). Não houve diferença na área proporcional de parênquima ou índice de edema perivascular entre os grupos estudados. A ventilação mecânica induziu infiltrado neutrofílico pulmonar nos animais, tanto no grupo BV como no AV em relação ao controle (p < 0,001). O infiltrado foi mais importante no grupo AV que no BV (p = 0,003). Houve um aumento de 40% na fosfo-FAK pelo Western Blot no grupo AV em relação ao controle (p=0,069) e aumento significativo de fosfo-paxilina no grupo AV em relação ao controle (p<0,001) e ao BV (p<0,001). Não se observaram diferenças para paxilina total, actina músculo liso e alfa-tubulina. A microscopia confocal demonstrou marcação para paxilina total nos septos alveolares. A microscopia eletrônica sugeriu reorganização do citoesqueleto nas zonula adherens do grupo AV. CONCLUSÕES: A ventilação mecânica promove lesão pulmonar com infiltrado neutrofílico numa relação dose-dependente. A ventilação com alto volume corrente promove fosforilação da FAK e de paxilina. As alterações no citoesqueleto em modelo in vivo de VILI são possíveis de serem descritas utilizando-se de métodos de microscopia confocal, Western Blot e microscopia eletrônica. / INTRODUCTION: Mechanical ventilation is an important therapy, but is associated with complications. One of the most relevant is ventilator-induced lung injury (VILI). Due to alveolar hyperdistension, the lung initiates an inflammatory process, with neutrophilic infiltration, hyaline membrane formation, fibrogenesis and gas exchange impairment. In this process, cellular mechanotransduction of the overstretching stimulus is mediated through the cytoskeleton and its cell-cell and cell-matrix interactions. But, although the cytoskeleton has this important role in the pathogenesis of VILI, there are no in vivo models for the research of cytoskeletal and cytoskeleton-associated proteins modifications during this pathological process. Our objective was to describe the immunohistochemical modifications during this process on the cytoskeleton and on two of its associated proteins (FAK and paxillin). METHODS: in this experimental study, three groups (n = 4 6) were studied: a control group and two ventilated for four hours with PEEP of 5 cmH2O. One group was ventilated with tidal volume of 8 mL/kg (LV) and the other with 24 mL/kg (HV). Data of respiratory mechanics were obtained at the beginning and the end of the experimental period. The lungs were evaluated with histomorphometry for parenchymal proportional area, neutrophilic infiltrate and perivascular edema, with Western Blot for phospho-FAK, phospho-paxillin, total paxillin, alpha-smooth muscle actin and alpha-tubulin, with confocal laser scanning microscopy for total paxillin, and with transmission electron microscopy. RESULTS: the groups were similar at the baseline. Dynamic elastance (Edin) increased in LV group and decreased in HV group (Edin initial to final: 0.76 ± 0.4 vs. 1.02 ± 0.47 respectively, in cmH2O/ml; p = 0.001). There was no difference in the parenchymal proportional area or the perivascular edema in the three groups. Mechanical ventilation induced pulmonary neutrophilic infiltration, both in the LV group and the HV group in comparison with control (p < 0.001). The infiltrate was more important in the HV group than in the LV group (p = 0.003). Phospho-FAK increased 40% in the HV group in Western Blot in comparison with control (p=0.069). Phosphopaxillin increased significantly in HV group compared with control (p<0.001) and with LV (p<0.001). Total paxillin, alpha-smooth muscle actin and alpha-tubulin did not show any differences. Confocal microscopy showed total paxillin labeling at alveolar septa. Electron microscopy suggested cytoskeleton reorganization at the zonula adherens in the AV group. CONCLUSIONS: Mechanical ventilation induces pulmonary injury with neutrophilic infiltrate in a dose-dependent relationship. Ventilation with high tidal volume promotes FAK and paxillin phosphorilation. The alterations in cytoskeleton in an in vivo model of VILI are possible to be studied with confocal microscopy, Western Blot and electron microscopy.

Citoesqueleto

Lesão pulmonar induzida por ventilador

Paxilina

Quinase 1 da adesão focal

Ratos

Respiração artificial

artificial

Cytoskeleton

Focal adhesion kinase 1

Paxillin

Rats

Respiration

Ventilador induced lung injury

Mecanismos de controle da expressão e atividade de metaloproteinases 2 e 9 pela quinase de adesão focal em fibroblastos / Mechanisms of control metalloproteinases 2 and 9 expression and activity by focal adhesion kinase un mouse cardiac fibroblasts

Costa, Ana Paula Dalla

03 May 2009

Orientador: Kleber Gomes Franchini / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciencias Medicas / Made available in DSpace on 2018-08-13T09:40:02Z (GMT). No. of bitstreams: 1 Costa_AnaPaulaDalla_M.pdf: 3504258 bytes, checksum: c5455cd7943b5dcb62c07cb63be2f681 (MD5) Previous issue date: 2009 / Resumo: Mudancas dinamicas que ocorrem no intersticio do coracao contribuem diretamente para o remodelamento miocardico decorrente de doencas cardiacas tais como infarto do miocardio, cardiopatia hipertensiva e cardiomiopatias. As metaloproteinases de matriz extracelular (MMPs) sao importantes no remodelamento destas doencas. Estimulos mecanicos e neuro-humoral regulam a expressao e atividade de MMPs atraves de multiplos processos. Em estudos previos verificamos que o silenciamento da FAK no VE de camundongos inibe a fibrose e reduz a atividade de MMP2. Objetivamos avaliar o papel da FAK no controle da ativacao de fibroblastos cardiacos de ratos(FCRNs), induzidos por estiramento mecanico. Os FCRNs foram cultivados em placas Bioflex e submetidos a estiramento ciclico (10%) por ate 8 horas, exceto os controles. A expressao e atividade da FAK foram avaliadas por imunoblottings com anticorpos especificos para FAK ou pFAK Tyr397, respectivamente. A expressao das MMPs 2 e 9 foi avaliada em imunoblottings e a atividade por zimografia ambas no sobrenadante da cultura. O estiramento provocou aumento de 2.4 vezes da quantidade de FAK fosforilada em Tyr397, alem da expressao e a atividade de MMP 2 e 9. Alem disto, modificou os parametros de proliferacao dos FCRNs, mostrando aumento de celulas positivas para Ki67 e BrdU. Do mesmo modo, a diferenciacao em miofibroblastos foi ativada(celulas positivas para a-actina de musculo liso (a-SMA). A inibicao genica da FAK atraves da tecnica de interferencia de RNA (siRNAFAK), nos FCRNs, inibiu a expressao de a-SMA, a atividade e a expressao das MMPs 2 e 9. Alem disso, a deplecao da FAK em FCRNs promoveu a diminuicao da fosforilacao em AKT Ser473, TSC-2 Thr1462, e S6 quinase Thr389 em resposta ao estiramento mecanico. A ativacao dos FCRNs foi impedida pelo pre-tratamento com o inibidor do complexo mTOR, rapamicina. Assim mostramos que a FAK medeia a ativacao de FCRNs invocado pelo estresse mecanico, possivelmente atraves da coordenacao da via de sinalizacao mTOR. Os resultados do presente estudo indicam a ativacao da FAK pode ter um papel critico na proliferacao e diferenciacao, e na ativacao de MMPs em FCRNs quando submetidos a estiramento, e ainda o knockdown da FAK apresenta efeitos contrarios, logo, infere-se o papel da FAK na ativacao de fibroblastos cardiacos. / Abstract: Dynamic changes that occur in the heart interstitium contribute directly to the myocardial remodeling due to heart disease such as myocardial infarction, hypertensive heart disease and cardiomyopathies. The extracellular matrixmetalloproteinases (MMPs) play an important role in remodeling in these diseases. Mechanical and neuro-humoral stimuli regulate the MMPs expression/activity through several processes which include the control of expression, activation by cascades of own MMPs and endogenous inhibitors. In recent studies from our laboratory showed that the FAK silencing in the left ventricle of mice inhibits the fibrosis development, and in parallel reduced the MMP2.activity and expression. The purpose of this study was to evaluate the role of FAK in controlling the MMP 2 and 9 expression and activity in rat cardiac fibroblasts. Cardiac fibroblasts from neonatal rat (FCRNs) were grown on silicon plates and then subjected to cyclic stretch (10%) for up to 8 hours, except the controls. The FAK expression and activity were assessed for imunoblottings through with specific antibodies to FAK or phospho -FAK Tyr397, respectively. The expression of MMP 2 and 9 was evaluated with specific antibodies in imunoblottings and activity through zimography both in the supernatant culture. Furthermore, FCRNs depleted of FAK was defective in AKT Ser473, TSC-2 Thr1462, and S6 kinase Thr389 phosphorylation in response to cyclic stretch. The activation of CF-P3/80 invoked by cyclic stretch was prevented by pre-treatment with the mTOR complex inhibitor rapamycin. These findings demonstrate that FAK signaling plays a critical role in mediating the activation of cardiac fibroblasts invoked by mechanical stress possibly by coordinating the downstream mTOR signaling pathway. The results of this study indicate that the activation of FAK can have a critical role to MMPs activation in cardiac fibroblasts, as well as, the proliferation and differentiation of these cells when subjected to stretching, and the FAK knockdown presents contrary effects, therefore, to corroborate infer the FAK role in differentiation and proliferation cell, and the MMPs balance in cardiac fibroblasts. / Mestrado / Biologia Estrutural, Celular e do Desenvolvimento / Mestre em Fisiopatologia Médica

Metaloproteinase 2 da matriz

Metaloproteinase 9 da matriz

Fibroblasto

Focal adhesion kinase

Matrix metalloproteinase 2

Matrix metalloproteinase 9

Fibroblasts

Towards Novel Effective Combination Therapy for KRAS Mutant Non-Small Cell Lung Cancer

Kurim, Sara

12 April 2018

Non-small-cell lung cancer (NSCLC) accounts for 80–85% of all lung cancers and is associated with significant mortality. As epidermal-growth-factor receptor (EGFR) is over-expressed in 80-90% of NSCLC, its inhibition via EGFR-Tyrosine Kinase inhibitors (EGFR-TKIs) is a main therapeutic strategy. However, patients with mutations in KRAS are resistant to EGFR-TKIs. A study in mutant KRAS-driven lung cancer in transgenic mice showed that tumor growth was dependent on the activity of focal adhesion kinase (FAK). Therefore, we hypothesized that KRAS-mutant NSCLC will be sensitive to FAK-TKIs and, given known FAK-EGFR cross-talk, FAK inhibition will sensitize KRAS-mutant NSCLC to EGFR-TKIs. We performed cell viability assays of WT versus mutant KRAS NSCLC cell lines following treatment with FAK-TKI alone or in combination with a clinically relevant EGFR-TKI. We found that KRAS-mutant cells were more sensitive to FAK-TKI than KRAS-WT NSCLC. In addition, we found that the combination treatment including FAK and EGFR TKIs resulted in reduced tumor cell viability as compared to treatment with either drug alone. This enhanced anti-tumor response could be due to FAK-TKI’s ability to down-regulate EGFR downstream targets. Our preliminary data suggests that in KRAS-mutant cells the drug combination appears to more effectively inhibit Akt activity than single drug treatment alone. This suggests an enhanced ability to impair cell survival following treatment with the drug combination. We also found that treatment with FAK TKI in KRAS mutant NSCLC cells resulted in increased activation of EGFR which was due in part to modulation of EGFR recycling and production of endogenous EGFR ligands. Thus, the combination of FAK- and EGFR-TKIs may be more effective in KRAS mutant NSCLC as treatment with EGFR-TKI overcomes the unexpected ‘side effect’ of treatment with FAK-TKI, namely activation of the EGFR pathway by this drug. The findings of our study are novel and have uncovered previously unrecognized outcomes of FAK inhibition on EGFR activity. Moreover, our data support the notion that the combination of FAK- and EGFR-TKIs could be an effective treatment for KRAS mutant NSCLC patients.

EGFR, epidermal growth factor receptor

FAK, focal adhesion kinase

NSCLC, non-small cell lung cancer

TKI, tyrosine kinase inhibitor

PF-271, PF-562,271

AFA, Afatinib

Microscopie de nano-objets individuels : étude de la diffusion des intégrines dans les sites d'adhésion focales de cellules vivantes / Microscopy of single nano-objects : study of integrins diffusion in focal adhesions in live cells

Octeau, Vivien

06 July 2010

L’effet photothermique permet de détecter efficacement des nanoparticules d’or avec un microscope en champ lointain grâce à leur forte absorption de la lumière. L’absence de problème photophysique fait des nanoparticules d’or une alternative au marquage de biomolécules par des sondes fluorescentes. La méthode PhACS (Photothermal Absorption Correlation Spectroscopy) utilise les fluctuations de signal photothermique dues au passage de nanoparticules dans le volume de détection pour étudier leur diffusion. Cette méthode permet également la mesure précise de diamètres hydrodynamiques de nanoparticules fonctionnalisées. La méthode SNaPT (Single Nano-Particle Tracking) réalise le suivi bidimensionnel de nanoparticules individuelles grâce à une localisation effectuée par triangulation. Nous avons appliqué cette méthode pour étudier la diffusion des intégrines alphaV-beta3 marquées par des nanoparticules d’or de 5 nm dans les adhérences focales, points d’ancrage entre le cytosquelette de la cellule et la matrice extracellulaire. Nous observons que ces intégrines ont tendance à former des agrégats qui alternent entre un mouvement diffusif et un mouvement confiné. Ce résultat appelle maintenant à un nouveau modèle où nous aurions une redistribution continue des intégrines au sein des adhérences focales. / Gold nanoparticles may be detected with optical far-field microscopy by use of the photothermal effect due to their strong light absorbance. With no photophysic issues, gold nanoparticles are an alternative to fluorescent probes for use in biological systems. The PhACS method (Photothermal Absorption Correlation Spectroscopy) is used to study diffusion by measuring the autocorrelation of photothermal signal fluctuations due to nanoparticles passing through the detection volume. This method is sensitive enough to mesure the precise hydrodynamic diameter of functionalised nanoparticles. The SnaPT method (Single Nano-Particle Tracking) can track 2-dimensional motion of individual nanoparticles by pinpointing the localization with a triangulation method. The SNaPT method was used to study motion of alphaV-beta3 integrins that were bound to a 5 nm gold nanoparticle inside focal adhesion, where the cell cytoskeleton is linked to the extracullular matrix. The integrin was found to organize into clusters oscillating between the bound and diffuse states. These observations require new working models where integrins would be constantly redistributed.

Microscopie

Effet photothermique

Nanoparticule d'or

Suivi de particule unique

Spectroscopie de corrélation

Intégrine

Adhérence focale

Microscopy

Photothermal effect

Gold nanoparticle

Single particle tracking

Correlation spectroscopy

Integrin

Focal adhesion

Study of marrow microenvironment and focal adherences in myelodysplastic syndromes and leukemias / Étude du microenvironnement médullaire et des complexes d’adhérence focale dans le myélodysplasies et leucémies

Robu, Carmen Mariana

12 March 2012

Les syndromes myélodysplasiques (SMD) sont considérés comme des maladies clonales des cellules souches hématopoïétiques (CSH). Le microenvironnement joue un rôle important par ses contacts direct avec les cellules progénitrices hématopoïétiques (CPH). Notre objectif était d'évaluer les défauts de croissance des cellules stromales mésenchymateuses (CSM) dans les MDS, d’explorer les molécules d’adhérence impliquées, et d'effectuer des corrélations avec leurs dysfonctionnements de croissance et les anomalies des CPH. Les CSM de MDS sont intrinsèquement pathologiques, montrant une baisse continue de la prolifération pendant 14 jours de culture et une capacité clonogénique réduite. Ces anomalies sont corrélés à une diminution des molécules d'adhérence CD44 et CD49e. Par ailleurs, le potentiel clonogénique des CPH est contrôlé par des mécanismes d'adhérence dépendant du stroma, CD49e pouvant être une des molécules impliquées. L’analyse en immunofluorescence des protéines d'adhérence focale (FA), paxilline et pFAK [Y397], et des deux protéines régulatrices, HSP90αβ et p130CAS permet l'identification d’anomalies qualitatives et quantitatives. Une expression accrue de paxilline, pFAK et HSP90αβ et leur forte co-localisation nucléaire dans les CSM d'anémie réfractaire avec excès de blastes (AREB) sont corrélées avec un avantage prolifératif et un impact négatif sur la capacité clonogénique de CPH. Ces résultats ouvrent des possibilités intéressantes : la signalisation via les protéines FA pourrait être impliquée dans les interactions HPC-MSC ; par ailleurs, FAK étant une protéine cliente d’HSP90, les inhibiteurs d’HSP90 sont une potentielle thérapie adjuvante dans les myélodysplasies / Myelodysplastic syndromes (MDS) are regarded as clonal disorders of haematopoietic stem cells (HSC). Recent evidence demonstrates that stromal microenvironment, in addition to HSC defects, plays a particular role via its direct contact with haematopoietic precursor cells (HPC). This thesis aims at evaluating the putative growth deficiencies of mesenchymal stromal cells (MSC) from MDS individuals compared with normal controls, exploring their adhesion profile, assessing the adhesion process-involved molecular substrates, and establishing correlations with their growth patterns and HPC dysfunctions. Functional assays revealed that MSC from MDS are intrinsically pathological, show a continuous decline of proliferation over a 14-day culture and a reduced clonogenic capacity in the absence of signals from HPC. MSC growth defects significantly correlate with decreased CD44 and CD49e expression. Moreover, stroma-dependent adhesion mechanisms control HPC clonogenic potential and CD49e might be one of the molecules involved in this process. Qualitative and quantitative abnormalities of focal adhesion (FA) proteins paxillin and pFAK [Y397] and of two regulatory proteins, HSP90αβ and p130CAS were identified via immunofluorescence analysis. Paxillin, pFAK [Y397] and HSP90αβ increased expression, besides its stronger nuclear colocalization in MSC from RAEB correlates with a consistent proliferative advantage and has a negative impact on HPC clonogenic capacity. These results open interesting opportunities, e.g. HPC-to-MSC interactions involve FA proteins signalling, and, as FAK is an HSP90αβ-client protein, it may enhance the utility of HSP90αβ inhibitors as adjuvant therapy in MDS

Syndromes myélodisplasiques

Cellules stromales mésenchymateuses

Protéines d'adhérence focale

Paxilline

Modèles de croissance

Myelodisplastic syndromes

Refractory aneamia with excess blasts

Mesenchymal stroma cells

Focal adhesion proteins

Paxillin

Growth patterns