Rôle de l'EMMPRIN, inducteur des MMPs,dans l'activation des fibroblastes : conséquences sur la formation du stroma tumoral / Role of EMMPRIN, an MMPs inducer, in fibroblast activation : conséquences in tumor stroma formation

Jarosz, Camille

31 January 2014

Les fibroblastes activés qui composent les stromas tumoraux sont des acteurs majeurs des interactions tumeur-stroma impliquées dans la croissance et la dissémination des cellules tumorales. Ce processus d'activation des fibroblastes est caractérisé par l'expression de marqueurs protéiques spécifiques parmi lesquels figure l'alphaSMA et FAPalpha;. Le TGFbeta;, cytokine secrétée massivement par les cellules tumorales, est un des éléments impliqués dans l'activation des fibroblastes et la formation du stroma tumoral qui en résulte. L'EMMPRIN, glycoprotéine transmembranaire surexprimée dans les cellules tumorales est également un médiateur des interactions tumeur-stroma puisqu'il a la capacité d'induire la synthèse des MMPs par les fibroblastes péri-tumoraux accroissant ainsi la propagation des cellules tumorales à travers l'organisme. Nos travaux identifièrent que le TGFbeta secrété par les cellules tumorales induisait la synthèse du marqueur FAPalpha par les fibroblastes. L'EMMPRIN stromal apparaît comme récepteur de ces signaux tumoraux et est nécessaire à la synthèse du marqueur FAPalpha; par les fibroblastes. L'EMMPRIN participe donc à l'activation TGFbeta; dépendante des fibroblastes. Son inhibition dans ces cellules conduit à un dysfonctionnement de la signalisation médiée par les protéines Smad2/Smad3 aboutissant à une diminution de la synthèse du marqueur alphaSMA ainsi que de certaines protéines matricielles induites par le TGFbeta. L'étude du mécanisme d'action de l'EMMPRIN dans ce processus a permis d'identifier l'EMMPRIN comme nouvelle protéine chaperonne du récepteur de type I au TGFbeta;. / Tumor stroma activated fibroblasts are major actors of tumor stroma interactions taking to tumor growth and spreading. Activated fibroblasts are characterized by the expression of specific markers including alphaSMA and FAPalpha;. The TGFbeta;, a cytokine highly secreted by tumor cells, is one of the key factors involved in fibroblast activation and tumor stroma formation. EMMPRIN, a transmembrane glycoprotein overexpressed in tumor cells, is also a mediator of tumor-stroma interactions by its ability to induce the synthesis of MMPs by peri-tumor fibroblasts enhancing then tumor cells dissemination across the organism.Here, we demonstrate that TGFbeta; secreted by tumor cells is the tumor factor involved in the synthesis of FAPalpha; by fibroblasts. Stromal EMMPRIN appeared to be the receptor of these tumor-stroma interactions and is required for the synthesis of FAPalpha; by fibroblasts. EMMPRIN was also evidenced to take part in TGFbeta;-dependent fibroblast activation. Its inhibition in these cells correlate to a dysfunction in Smad2/Smad3 signaling leading to a decrease in the expression of alphaSMA and matrix proteins induced by TGFbeta;. The study of the mechanism used by EMMPRIN in this process evidenced this protein as a new chaperone for the type I TGFbeta; receptor.

Stroma tumoral

Emmprin

TGFbeta

Fibroblastes

Protéine chaperonne

Tumour stroma

Emmprin

TGFbeta

Fibroblasts

Chaperon protein

570

The prostatic tumour stroma

Bonda, Ulrich

12 August 2016

The majority of cancer research projects mainly focus on the epithelial cancer cell, while the role of the tumour stroma has been largely neglected. Conventional 2D techniques, such as well plates and other kinds of tissue culture plastic, and animal models are mainly used to broaden our understanding of how tumours arise, develop, and induce metastasis. However, there is accumulating evidence suggesting a tremendous impact of the non‐cancerous tumour stroma on carcinogenesis, while other publications illustrate the great importance of advanced 3D in vitro models for cancer research. The overall goal of this work was to investigate how cancer associated fibroblasts (CAFs; the most abundant component in the tumour stroma) and normal prostate fibroblasts (NPFs), isolated from patients diagnosed with aggressive forms of prostate cancer, contribute to angiogenesis, an important hallmark of cancer progression. For this purpose, a 3D in vitro angiogenesis co‐culture model was established. At first, two (semi‐) synthetic hydrogel platforms, gelatine methacrylate (GelMA) and star‐shaped (star)PEG‐heparin hydrogels were characterised and their physicochemical properties were compared with each other. Interestingly, GelMA gels shrank while starPEG‐heparin gels swelled in cell culture medium over the course of 24 hours. The cell concentration, in addition to the stiffness, was critical for the formation of endothelial networks, and the knowledge of swelling behaviour enabled the adjustment of initial cell density to ensure the density between both gel types was comparable. Moreover, preliminary tests with mesenchymal stem cells demonstrated that the hydrogel can be actively remodelled, as evaluated by stiffness parameters at day one and seven of incubation. Growth factors (GFs) affect cellular fate and behaviour, and storage, presentation and administration of such chemokines can be critical for certain cellular applications. Due to the high anionic charge density of heparin, starPEG‐heparin hydrogels are known to reversibly immobilise several GFs and thereby might mimic the GF reservoir of the extra cellular matrix. Thus, transport processes of GFs with low and high heparin affinity inside these hydrogels were analysed by fluorescence correlation spectroscopy and a bulk diffusion approach. Results indicated that diffusion constants were synergistically decreased with increasing size and heparin affinity of the diffusant. Next, the capability of endothelial cells (ECs) to self‐assemble and organise into 3D capillary networks was tested in GelMA, starPEG‐heparin and Matrigel hydrogels. Only starPEG‐heparin hydrogels allowed the formation of interconnected capillaries in macroscopic hydrogel samples. However, as it is widely used to test for pro‐ and anti‐angiogenic agents, the 2D Matrigel angiogenesis assay was included for subsequent co‐culture experiments of ECs and fibroblasts in order to investigate how the stromal cells influence the formation of endothelial networks. For a detailed characterisation of 3D structures, a conventionally applied 2D method (Maximum Intensity Projection for 3D reconstructed images, MIP) was compared to an optimised 3D analysing tool. As a result, it was discovered that MIP analysis did not allow for an accurate determination of 3D endothelial network parameters, and can result in misleading interpretations of the data set. Indirect co‐cultures of hydrogel‐embedded ECs with a 2D layer of fibroblasts showed that fibroblast‐derived soluble factors, including stromal cell‐derived factor 1 and interleukin 8, affected endothelial network properties. However, only co‐encapsulation of ECs and fibroblasts in starPEG‐heparin hydrogel discs revealed remarkable changes in endothelial network parameters between CAF and NPF samples. In detail, the total length and branching of the capillaries was increased. For two donor pairs, the diameter of capillaries was decreased in CAF samples compared to NPF samples, underlining the high physiological relevance of this model. In contrast, significant differences in 2D Matrigel assays were not detected between, CAF, NPF and control (ECs only) samples. In summary, a 3D angiogenesis co‐culture system was successfully developed and used to characterise stromal‐endothelial interactions in detail. The combination of advanced biomaterials (starPEG‐heparin) and 3D analysing techniques goes beyond conventional 2D in vitro cancer research, and opens new avenues for the development of more complex models to further improve the acquisition of more biologically relevant data.

Tumor-Stroma

Prostatakarzinom

3D Zellkultur

Angiogenese Assays

3D Analyse

Diffusion in Hydrogelen

Tumour Stroma

Prostate Cancer

3D Cell Culture

Angiogenesis Assays

3D Analysis

Diffusion in Hydrogels

ddc:570

rvk:XH 8000

Genetická analýza nádorů hlavy a krku / Genetical analysis of head and neck squamous cell carcinomas

Čapková, Markéta

January 2016

Head and neck squamous cell carcinoma is the fifth most common cancer worldwide. They are associated with high morbidity and mortality. Despite considerable advances in surgical and oncological treatment over the past two decades, overall treatment outcome has only slightly improved. In my thesis I focused on serum gene expression analysis of head and neck cancer patients, which followed the tissue gene expression analysis in same patients. Further we investigated gene expression analysis in tumour stroma, which is now considered as significant factor in cancer initiation and progression. We revealed several candidate genes, which are involved in signalling pathways connected with cell differentiation and proliferation and are involved in apoptotic pathway (BCl-2, BCl-XL a MAX). As well we detected down-regulation of the main tumour suppressor p 53 protein. In peritumoural tissue we detected overexpression of cytokines typical for embryonal development and ectoderm differentiation - IGF-2 and BMP-4, which significantly influence the phenotype of normal keratinocytes. Further we identified several candidate genes relating with overexpression of Gal-1 in stromal myofibroblasts rich tissue (SPIN1, FUSIP1, TRIM23, SLC25A40, PTPLAD1, MP3K2). HNSCC is a heterogeneous disease despite the presence of...

Genetická analýza nádorů hlavy a krku / Genetical analysis of head and neck squamous cell carcinomas

Čapková, Markéta

January 2016

Head and neck squamous cell carcinoma is the fifth most common cancer worldwide. They are associated with high morbidity and mortality. Despite considerable advances in surgical and oncological treatment over the past two decades, overall treatment outcome has only slightly improved. In my thesis I focused on serum gene expression analysis of head and neck cancer patients, which followed the tissue gene expression analysis in same patients. Further we investigated gene expression analysis in tumour stroma, which is now considered as significant factor in cancer initiation and progression. We revealed several candidate genes, which are involved in signalling pathways connected with cell differentiation and proliferation and are involved in apoptotic pathway (BCl-2, BCl-XL a MAX). As well we detected down-regulation of the main tumour suppressor p 53 protein. In peritumoural tissue we detected overexpression of cytokines typical for embryonal development and ectoderm differentiation - IGF-2 and BMP-4, which significantly influence the phenotype of normal keratinocytes. Further we identified several candidate genes relating with overexpression of Gal-1 in stromal myofibroblasts rich tissue (SPIN1, FUSIP1, TRIM23, SLC25A40, PTPLAD1, MP3K2). HNSCC is a heterogeneous disease despite the presence of...

The prostatic tumour stroma: Design and validation of a 3D in vitro angiogenesis co‐culture model

Bonda, Ulrich

09 August 2016

The majority of cancer research projects mainly focus on the epithelial cancer cell, while the role of the tumour stroma has been largely neglected. Conventional 2D techniques, such as well plates and other kinds of tissue culture plastic, and animal models are mainly used to broaden our understanding of how tumours arise, develop, and induce metastasis. However, there is accumulating evidence suggesting a tremendous impact of the non‐cancerous tumour stroma on carcinogenesis, while other publications illustrate the great importance of advanced 3D in vitro models for cancer research. The overall goal of this work was to investigate how cancer associated fibroblasts (CAFs; the most abundant component in the tumour stroma) and normal prostate fibroblasts (NPFs), isolated from patients diagnosed with aggressive forms of prostate cancer, contribute to angiogenesis, an important hallmark of cancer progression. For this purpose, a 3D in vitro angiogenesis co‐culture model was established. At first, two (semi‐) synthetic hydrogel platforms, gelatine methacrylate (GelMA) and star‐shaped (star)PEG‐heparin hydrogels were characterised and their physicochemical properties were compared with each other. Interestingly, GelMA gels shrank while starPEG‐heparin gels swelled in cell culture medium over the course of 24 hours. The cell concentration, in addition to the stiffness, was critical for the formation of endothelial networks, and the knowledge of swelling behaviour enabled the adjustment of initial cell density to ensure the density between both gel types was comparable. Moreover, preliminary tests with mesenchymal stem cells demonstrated that the hydrogel can be actively remodelled, as evaluated by stiffness parameters at day one and seven of incubation. Growth factors (GFs) affect cellular fate and behaviour, and storage, presentation and administration of such chemokines can be critical for certain cellular applications. Due to the high anionic charge density of heparin, starPEG‐heparin hydrogels are known to reversibly immobilise several GFs and thereby might mimic the GF reservoir of the extra cellular matrix. Thus, transport processes of GFs with low and high heparin affinity inside these hydrogels were analysed by fluorescence correlation spectroscopy and a bulk diffusion approach. Results indicated that diffusion constants were synergistically decreased with increasing size and heparin affinity of the diffusant. Next, the capability of endothelial cells (ECs) to self‐assemble and organise into 3D capillary networks was tested in GelMA, starPEG‐heparin and Matrigel hydrogels. Only starPEG‐heparin hydrogels allowed the formation of interconnected capillaries in macroscopic hydrogel samples. However, as it is widely used to test for pro‐ and anti‐angiogenic agents, the 2D Matrigel angiogenesis assay was included for subsequent co‐culture experiments of ECs and fibroblasts in order to investigate how the stromal cells influence the formation of endothelial networks. For a detailed characterisation of 3D structures, a conventionally applied 2D method (Maximum Intensity Projection for 3D reconstructed images, MIP) was compared to an optimised 3D analysing tool. As a result, it was discovered that MIP analysis did not allow for an accurate determination of 3D endothelial network parameters, and can result in misleading interpretations of the data set. Indirect co‐cultures of hydrogel‐embedded ECs with a 2D layer of fibroblasts showed that fibroblast‐derived soluble factors, including stromal cell‐derived factor 1 and interleukin 8, affected endothelial network properties. However, only co‐encapsulation of ECs and fibroblasts in starPEG‐heparin hydrogel discs revealed remarkable changes in endothelial network parameters between CAF and NPF samples. In detail, the total length and branching of the capillaries was increased. For two donor pairs, the diameter of capillaries was decreased in CAF samples compared to NPF samples, underlining the high physiological relevance of this model. In contrast, significant differences in 2D Matrigel assays were not detected between, CAF, NPF and control (ECs only) samples. In summary, a 3D angiogenesis co‐culture system was successfully developed and used to characterise stromal‐endothelial interactions in detail. The combination of advanced biomaterials (starPEG‐heparin) and 3D analysing techniques goes beyond conventional 2D in vitro cancer research, and opens new avenues for the development of more complex models to further improve the acquisition of more biologically relevant data.

info:eu-repo/classification/ddc/570

ddc:570