Implication de l’Insulin-like Growth Factor (IGF-I), secrété par le microenvironnement tumoral, dans la survie et la chimiorésistance des cellules cancéreuses

The microenvironment, composed of several cellular elements and extracellular matrix, plays an important role in tumor development and metastasis. Thus, the study of these interactions is important for cell targeted therapies fighting against chemoresistant tumor cells. This thesis aims to investigate the role of growth factor IGF-I in the chemoresistance of ovarian cancer cells and myeloid leukemia, present in the microenvironment.As a first step, we demonstrated that drug resistance of ovarian cancer cells gained by host cells (hospicells) is related to the secretion of IGF-I by these cells. We have also demonstrated that IGF-I is involved in the regulation of genes ABC (MDR-1, MRP1, MRP2, and BCRP) via STAT3, Jak2, PI3K et ERK signaling pathways.In myeloid leukemia, we have shown that IGF-I has an effect on cell proliferation. It induces the expression of P-gp protein and chemoresistance of cells sensitive to chemotherapy. We also determined the role of IGF-I in the resistance of leukemic cells in the presence of hospicells. These cells have an in vivo hyperangiogenic activity, related to HIF-1 and VEGF, and inhibit immune responses of T cells by NO production.We determined the crucial role of MMP-9 in resistant cells migration of breast cancer expressing P-gp protein and in the formation of a tubular network, suggesting a link between the expression of P-gp and MMP-9.Le microenvironnement, composé de différents éléments cellulaires et de la matrice extracellulaire, joue un rôle primordial dans le développement tumoral et la dissémination métastatique. Ainsi, l’étude de ces interactions cellulaires est importante pour que des thérapies ciblées luttent contre la chimiorésistance des cellules tumorales. Ce travail de thèse a pour but d’étudier le rôle du facteur de croissance IGF-I dans la chimiorésistance des cellules du cancer de l’ovaire et des leucémies myéloïdes présente au sein du microenvironnement.Dans un premier temps, nous avons mis en évidence que la chimiorésistance des cellules du cancer de l’ovaire, acquise grâce aux cellules hôtes (hospicells), est liée à la sécrétion de IGF-I par ces cellules. Nous avons également montré que IGF-I est impliqué dans la régulation de certains gènes ABC (MDR-1, MRP1, MRP2, et BCRP) via les voies de STAT3, Jak2, PI3K et ERK.Dans les leucémies myéloïdes, nous avons montré que IGF-I a un effet sur la prolifération des cellules tumorales. Il induit l’expression de la protéine P-gp ainsi que la chimiorésistance des cellules sensibles à la chimiothérapie. Nous avons également déterminé le rôle de IGF-I dans la résistance des cellules leucémiques en présence des hospicells. Ces dernières ont une activité hyperangiogénique in vivo, lié à l’HIF-1 et au VEGF, et inhibent les réponses immunes des lymphocytes T par production de NO.Nous avons déterminé le rôle crucial de MMP-9 dans la migration des cellules résistantes du cancer du sein exprimant la protéine P-gp et dans la formation d’un réseau tubulaire, suggérant un lien existant entre l’expression de P-gp et de MMP-9

the role of insulin-like growth factor (IGF-I) secreted by tumoral microenvironment, in survival and drug resistance cancer cells

Le microenvironnement, composé de différents éléments cellulaires et de la matrice extracellulaire, joue un rôle primordial dans le développement tumoral et la dissémination métastatique. Ainsi, l’étude de ces interactions cellulaires est importante pour que des thérapies ciblées luttent contre la chimiorésistance des cellules tumorales. Ce travail de thèse a pour but d’étudier le rôle du facteur de croissance IGF-I dans la chimiorésistance des cellules du cancer de l’ovaire et des leucémies myéloïdes présente au sein du microenvironnement.Dans un premier temps, nous avons mis en évidence que la chimiorésistance des cellules du cancer de l’ovaire, acquise grâce aux cellules hôtes (hospicells), est liée à la sécrétion de IGF-I par ces cellules. Nous avons également montré que IGF-I est impliqué dans la régulation de certains gènes ABC (MDR-1, MRP1, MRP2, et BCRP) via les voies de STAT3, Jak2, PI3K et ERK.Dans les leucémies myéloïdes, nous avons montré que IGF-I a un effet sur la prolifération des cellules tumorales. Il induit l’expression de la protéine P-gp ainsi que la chimiorésistance des cellules sensibles à la chimiothérapie. Nous avons également déterminé le rôle de IGF-I dans la résistance des cellules leucémiques en présence des hospicells. Ces dernières ont une activité hyperangiogénique in vivo, lié à l’HIF-1 et au VEGF, et inhibent les réponses immunes des lymphocytes T par production de NO.Nous avons déterminé le rôle crucial de MMP-9 dans la migration des cellules résistantes du cancer du sein exprimant la protéine P-gp et dans la formation d’un réseau tubulaire, suggérant un lien existant entre l’expression de P-gp et de MMP-9.The microenvironment, composed of several cellular elements and extracellular matrix, plays an important role in tumor development and metastasis. Thus, the study of these interactions is important for cell targeted therapies fighting against chemoresistant tumor cells. This thesis aims to investigate the role of growth factor IGF-I in the chemoresistance of ovarian cancer cells and myeloid leukemia, present in the microenvironment.As a first step, we demonstrated that drug resistance of ovarian cancer cells gained by host cells (hospicells) is related to the secretion of IGF-I by these cells. We have also demonstrated that IGF-I is involved in the regulation of genes ABC (MDR-1, MRP1, MRP2, and BCRP) via STAT3, Jak2, PI3K et ERK signaling pathways.In myeloid leukemia, we have shown that IGF-I has an effect on cell proliferation. It induces the expression of P-gp protein and chemoresistance of cells sensitive to chemotherapy. We also determined the role of IGF-I in the resistance of leukemic cells in the presence of hospicells. These cells have an in vivo hyperangiogenic activity, related to HIF-1 and VEGF, and inhibit immune responses of T cells by NO production.We determined the crucial role of MMP-9 in resistant cells migration of breast cancer expressing P-gp protein and in the formation of a tubular network, suggesting a link between the expression of P-gp and MMP-9

Implication de l'Insulin-like Growth Factor (IGF-I), secrété par le microenvironnement tumoral, dans la survie et la chimiorésistance des cellules cancéreuses

Le microenvironnement, composé de différents éléments cellulaires et de la matrice extracellulaire, joue un rôle primordial dans le développement tumoral et la dissémination métastatique. Ainsi, l étude de ces interactions cellulaires est importante pour que des thérapies ciblées luttent contre la chimiorésistance des cellules tumorales. Ce travail de thèse a pour but d étudier le rôle du facteur de croissance IGF-I dans la chimiorésistance des cellules du cancer de l ovaire et des leucémies myéloïdes présente au sein du microenvironnement.Dans un premier temps, nous avons mis en évidence que la chimiorésistance des cellules du cancer de l ovaire, acquise grâce aux cellules hôtes (hospicells), est liée à la sécrétion de IGF-I par ces cellules. Nous avons également montré que IGF-I est impliqué dans la régulation de certains gènes ABC (MDR-1, MRP1, MRP2, et BCRP) via les voies de STAT3, Jak2, PI3K et ERK.Dans les leucémies myéloïdes, nous avons montré que IGF-I a un effet sur la prolifération des cellules tumorales. Il induit l expression de la protéine P-gp ainsi que la chimiorésistance des cellules sensibles à la chimiothérapie. Nous avons également déterminé le rôle de IGF-I dans la résistance des cellules leucémiques en présence des hospicells. Ces dernières ont une activité hyperangiogénique in vivo, lié à l HIF-1 et au VEGF, et inhibent les réponses immunes des lymphocytes T par production de NO.Nous avons déterminé le rôle crucial de MMP-9 dans la migration des cellules résistantes du cancer du sein exprimant la protéine P-gp et dans la formation d un réseau tubulaire, suggérant un lien existant entre l expression de P-gp et de MMP-9.The microenvironment, composed of several cellular elements and extracellular matrix, plays an important role in tumor development and metastasis. Thus, the study of these interactions is important for cell targeted therapies fighting against chemoresistant tumor cells. This thesis aims to investigate the role of growth factor IGF-I in the chemoresistance of ovarian cancer cells and myeloid leukemia, present in the microenvironment.As a first step, we demonstrated that drug resistance of ovarian cancer cells gained by host cells (hospicells) is related to the secretion of IGF-I by these cells. We have also demonstrated that IGF-I is involved in the regulation of genes ABC (MDR-1, MRP1, MRP2, and BCRP) via STAT3, Jak2, PI3K et ERK signaling pathways.In myeloid leukemia, we have shown that IGF-I has an effect on cell proliferation. It induces the expression of P-gp protein and chemoresistance of cells sensitive to chemotherapy. We also determined the role of IGF-I in the resistance of leukemic cells in the presence of hospicells. These cells have an in vivo hyperangiogenic activity, related to HIF-1 and VEGF, and inhibit immune responses of T cells by NO production.We determined the crucial role of MMP-9 in resistant cells migration of breast cancer expressing P-gp protein and in the formation of a tubular network, suggesting a link between the expression of P-gp and MMP-9.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

High Expression of HLA-G in Ovarian Carcinomatosis: The Role of Interleukin-1β

The present study focuses on the influence of the tumor microenvironment on the expression of HLA-G in ovarian cancer and its impact on immune cells. We used carcinomatosis fluids (n = 16) collected from patients diagnosed with epithelial ovarian cancer, detected by an increase in CA125 levels. Our results indicate that HLA-G is expressed by 1) ascitic cell clusters, 2) stromal cells (hospicells) extracted from cancer cell clusters, and 3) cancer cell lines and tumor cells. The origin of HLA-G was linked to inflammatory cytokines present in the cancer microenvironment. In parallel, the ascitic fluid of patients with ovarian cancer contains soluble HLA-G (sHLA-G). The mesothelial cell layer and submesothelial tissues, as well as the immune cell infiltrate, do not secrete HLA-G. In contrast, sHLA-G is absorbed by peritoneal tissues along with mesothelial layers as well as immune cell infiltrates. We demonstrated that interleukin-1β along with TGF-β can be a major HLA-G–inducing factor that upregulates HLA-G expression through the NF-κB pathway. The level of HLA-G in ascites correlated positively with the expression of T regulatory (T-regs) cells, while it negatively correlated with the expression of natural killer and memory cells in tumor-infiltrating immune cells. In conclusion, the production of HLA-G is associated with the presence of inflammatory cytokines and is strongly correlated with microenvironment tolerant cells such as T-regs and diminution of NK and memory T cells

A subset of bone marrow stromal cells regulate ATP-binding cassette gene expression via insulin-like growth factor-I in a leukemia cell line

International audienceThe importance of the insulin-like growth factor, IGF, as a signaling axis in cancer development, progression and metastasis is highlighted by its effects on cancer cells, notably proliferation and acquired resistance. The role of the microenvironment within which cancer cells evolve and which mediates this effect is far from clear. Here, the involvement of IGF-I in inducing multidrug resistance in a myeloid leukemia cell line, grown in the presence of bone marrow-derived stromal cells called `Hospicells' (BMH), is demonstrated. We found that i) drug sensitive as well as resistant leukemia cells express IGF-I and its receptor IGF-IR. However, the resistant cells were found to secrete high levels of IGF-I. ii) Presence of exogenous IGF-I promoted cell proliferation, which decreased when an inhibitor of IGF-IR (picropodophyllin, PPP) was added. iii) BMH and IGF-I are both involved in the regulation of genes of the ATP binding cassette (ABC) related to resistance development (MDR1, MRP1, MRP2, MRP3 and BCRP). iv) The levels of ABC gene expression by leukemia cells were found to increase in the presence of increasing numbers of BMH. However, these levels decreased when IGF-IR was inhibited by addition of PPP. v) Co-culture of the drug-sensitive leukemia cells with BMH induced protection against the action of daunorubicin. This chemoresistance was amplified by the presence of IGF-I whereas it decreased when IGF-IR was inhibited. Our results underline the role of microenvironment in concert with the IGF-1 pathway in conferring drug resistance to leukemia cells

Faeces‐derived extracellular vesicles participate in the onset of barrier dysfunction leading to liver diseases

International audienceThe role of extracellular vesicles (EVs) from faeces (fEVs) and small circulating EVs (cEVs) in liver diseases such as non-alcoholic fatty diseases (NAFLD) and nonalcoholic steatohepatitis (NASH) has not been demonstrated. fEVs and cEVs of healthy donors, NAFLD and NASH patients were isolated and characterized. The effects of EVs were evaluated in intestinal, endothelial, Kupffer and stellate cells. Nonmuscular myosin light chain kinase (nmMLCK) deficient mice were used in vivo. Bacterial origins of fEVs were analysed by 16s rDNA gene sequencing. fEVs and small cEVs were composed of prokaryotic and eukaryotic origins. Only NASH-fEVs exerted deleterious effects. NASH-fEVs increased intestinal permeability and reduced expression of tight junction proteins that were prevented by nmMLCK inhibition, increased endothelial cell permeability and inflammatory cytokines and chemokines requiring TLR4/lipopolysaccharide pathway. NASH-fEVs and NASH-cEVs activated profibrotic and proinflammatory proteins of hepatic stellate cells. Treatment with NASH-fEVs evoked an increase in intestinal permeability in wild type but not in nmMLCK deficient mice. Bacterial origins of fEVs were different between NAFLD and NASH patients and 16 amplicon sequence variants were differentially abundant. We demonstrate that fEVs actively participate in barrier dysfunctions leading to liver injuries underscoring the role of nmMLCK and lipopolysaccharide carried by fEVs