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Immunogenetic determinants of chemotherapy response in cancer / Rôle du profile immunogénétique des patientes dans la réponse à la chimiothérapieVacchelli, Erika 15 September 2014 (has links)
L’efficacité de la chimiothérapie contre la croissance tumourale repose sur l'induction d'une mort des cellules tumourales dite immunogène. Les cellules tumourales mourantes agissent alors comme un vaccin thérapeutique en stimulant une réponse immunitaire anti-tumourale capable de contrôler, voire d'éliminer, les cellules cancéreuses résiduel. Les trois marqueurs principales de la mort cellulaire immunogène (MCI), sont (i) l'exposition pré-apoptotique de la calréticuline (CRT) à la surface des cellules, (ii) la sécrétion de l'ATP pendant l'apoptose qui dépend du processus d'autophagie, et (iii) le relargage post-apoptotique de la protéine non-histone de fixation à la chromatine HMGB1 (High Mobility Group B1). CRT, ATP et HMGB1 se lient respectivement à CD91, au récepteur purinergique P2RX7 (Purinergic Receptor P2X, ligand-gated ion channel 7) et au récepteur TLR4 (Toll-like Receptor 4) situés à la surface des cellules dendritiques. En retour, ces interactions initient respectivement la phagocytose des cellules mourantes, la production de l'interleukine-1β et la cross-présentation des antigènes tumouraux aux lymphocytes T.Notre laboratoire a précédemment démontré que la chimiothérapie adjuvante présente une efficacité réduite chez des patients atteints de cancers colorectaux et du sein portant un polymorphisme d'un seul nucléotide ou SNP (Single-Nucleotide Polymorphism) compromettent la fonction des gènes P2RX7 et TLR4, notamment rs3751143 (496Glu>Ala) pour le gène P2RX7 et rs4986790 (299Asp>Gly) pour le gène TLR4.Compte tenu des ces résultats que mettent en évidence la relation étroite entre l’efficacité de la chimiothérapie anticancéreuse et un système immunitaire opérationnel, nous avons décidé d'étudier l'effet de ces SNPs, soit sur la survie globale soit sur la survie sans événement, chez des patients atteints de cancer pulmonaire non à petites cellules ou NSCLC (Non-Small Cell Lung Carcinoma) et de cancers de la tête et du cou ou HNSCC (Head and Neck Squamous Cell Carcinoma). De plus, nous avons porté notre attention sur un autre SNP affectant le gène ATG16L1 (Autophagy-related 16-Like 1), notamment rs2241880 (300Thr>Ala) qui compromet l’activité d’un gène fondamental dans le processus d’autophagie.Dans les cancers NSCLC, les allèles mutants "perte de fonction" des gènes ATG16L1, P2RX7 et TLR4 n'affectent pas la survie globale, indépendamment du type de chimiothérapie administrée. Au contraire, les patientes atteintes de HNSCC, portant au moins un allèle "perte de fonction" d’ATG16L1 et TLR4, présentent un taux de survie sans récidive inferieure par rapport aux patients qui présentent un genotype sauvage. Ce travail décrit pour la première fois un biomarqueur prognostique pour ce type de cancer.De plus, nous avons pu définir, par génotypage à haut débit, une signature de SNPs prédictive de la réponse à la chimiothérapie neoadjuvantes à base d'anthracyclines et des taxanes chez les patients atteints de cancer du sein. En particulier, la combinaison des deux paramètres clinicopathologiques classiques (âge lors du diagnostic et récepteur aux œstrogènes) avec les génotypes rs1076669 du gène ECE1 (Endothelin Converting Enzyme 1; 341Thr>Ile) et rs2277413 du gène PZP (Pregnancy-Zone Protein; 813Val>Ala) a permis de définir trois grandes catégories des patients et leur probabilité respective d'atteindre la réponse complète pathologique après traitement.L'identification de nouveaux biomarqueurs associés à une absence/diminution de réponse à la chimiothérapie apparaît critique pour choisir des alternatives thérapeutiques appropriées et éviter les effets secondaires indésirables chez les non-répondeurs. / Successful chemotherapeutics can induce a type of tumour cell death that is immunogenic, implying that patient’s dying cancer cells function as a therapeutic vaccine and elicit an anti-tumour immune response that controls the residual disease. The three main hallmarks of immunogenic cell death (ICD) are the pre-apoptotic exposure of calreticulin (CRT) on the cell surface, the autophagy-dependent secretion of ATP during the blebbing phase of apoptosis and the post-apoptotic release of the chromatin-binding non-histone protein high mobility group B1 (HMGB1). CRT, ATP and HMGB1 interact with CD91, purinergic receptor P2X, ligand-gated ion channel, 7 (P2RX7) and Toll-like receptor 4 (TLR4), respectively, on the surface of dendritic cells (DCs), thus promoting the engulfment of dying cells, the production of IL-1β and the cross-presentation of tumour-associated antigens to T cells, respectively.Our laboratory has demonstrated that adjuvant chemotherapy exhibits a reduced efficacy in breast and colorectal cancer patients bearing single-nucleotide polymorphisms (SNPs) that compromise the function of P2RX7 or TLR4, such as rs3751143 in P2RX7 (Glu496Ala) and rs4986790 in TLR4 (Asp299Gly).Driven by these results, underpinning the intimate relationship between the success of anti-cancer chemotherapy and an operational immune system, we decided to investigate the effect of these SNPs on disease outcome among non-small cell lung carcinoma (NSCLC) and head and neck squamous cell carcinoma (HNSCC) patients. Additionally, we focused our attention on a SNP in autophagy related 16-like 1 (ATG16L1), namely rs2241880 (Thr300Ala), which compromises the activity of one pivotal autophagic gene. In NSCLC patients, loss-of-function ATG16L1, P2RX7 and TLR4 alleles do not affect overall survival, irrespective of the administration and type of chemotherapy. Conversely, HNSCC patients bearing at least one loss-of-function ATG16L1 or TLR4 allele exhibit a reduced disease-free survival when compared to their wild-type counterparts. This is the first report highlighting a putative prognostic biomarker for this malignancy. Furthermore, taking advantage of a high throughput genotyping study, we delineated a SNP-based signature that predicts the response of breast cancer patients to anthracycline- and taxane-based neoadjuvant chemotherapy. Particularly, the combination of two classical clinicophatological parameters (age at diagnosis and estrogen receptor) and genotype at the ECE1 (rs1076669 Thr341Ile) and PZP (rs2277413 Val813Ala) loci allowed us to define three broad categories with a correspondent probability of achieving pathological complete response. The identification of new biomarkers associated with a reduced/absent response to chemotherapy appears critical for selecting appropriate therapeutic alternatives, and avoiding undesired side effects among non-responders.
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Inducing Cellular Senescence in CancerRestall, Ian J. 22 January 2013 (has links)
Cellular senescence is a permanent cell cycle arrest that is induced as a response to cellular stress. Replicative senescence is a well-described mechanism that limits the replicative capacity of cells and must be overcome by cancer cells. Oncogene-induced senescence (OIS) is a form of premature senescence and a potent tumor suppressor mechanism. OIS is induced in normal cells as a result of deregulated oncogene or tumor suppressor gene expression. An exciting area of research is the identification of novel targets that induce senescence in cancer cells as a therapeutic approach. In this study, a novel mechanism is described where the inhibition of Hsp90 in small cell lung cancer (SCLC) cells induced premature senescence rather than cell death. The senescence induced following Hsp90 inhibition was p21-dependent and the loss of p21 allowed SCLC cells to bypass the induction of senescence. Additionally, we identified a novel mechanism where the depletion of PKCι induced senescence in glioblastoma multiforme (GBM) cells. PKCι depletion-induced senescence did not activate the DNA-damage response pathway and was p21-dependent. Further perturbations of mitosis, using an aurora kinase inhibitor, increased the number of senescent cells when combined with PKCι depletion. This suggests that PKCι depletion-induced senescence involves defects in mitotic progression. Senescent glioblastoma cells at a basal level of senescence in culture, induced by p21 overexpression, and induced after PKCι depletion had aberrant centrosomes. Mitotic slippage is an early exit from mitosis without cell division that occurs when the spindle assembly checkpoint (SAC) is not satisfied. Senescent glioblastoma cells had multiple markers of mitotic slippage. Therefore, PKCι depletion-induced senescence involves mitotic slippage and results in aberrant centrosomes. A U87MG cell line with a doxycycline-inducible shRNA targeting PKCι was developed to deplete PKCι in established xenografts. PKCι was depleted in established glioblastoma xenografts in mice and resulted in decreased cell proliferation, delayed tumor growth and improved survival. This study has demonstrated that both Hsp90 and PKCι are novel targets to induce senescence in cancer cells as a potential therapeutic approach.
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Molekulargenetische Veränderungen in nicht kleinzelligen Bronchialkarzinomen, detektiert durch komparative genomische Hybridisierung (CGH) / Molecular genetic changes in non small cell lung cancer, detected by comparative genomic hybridization (CGH)Hellms, Timo 22 January 2013 (has links)
No description available.
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Inducing Cellular Senescence in CancerRestall, Ian J. 22 January 2013 (has links)
Cellular senescence is a permanent cell cycle arrest that is induced as a response to cellular stress. Replicative senescence is a well-described mechanism that limits the replicative capacity of cells and must be overcome by cancer cells. Oncogene-induced senescence (OIS) is a form of premature senescence and a potent tumor suppressor mechanism. OIS is induced in normal cells as a result of deregulated oncogene or tumor suppressor gene expression. An exciting area of research is the identification of novel targets that induce senescence in cancer cells as a therapeutic approach. In this study, a novel mechanism is described where the inhibition of Hsp90 in small cell lung cancer (SCLC) cells induced premature senescence rather than cell death. The senescence induced following Hsp90 inhibition was p21-dependent and the loss of p21 allowed SCLC cells to bypass the induction of senescence. Additionally, we identified a novel mechanism where the depletion of PKCι induced senescence in glioblastoma multiforme (GBM) cells. PKCι depletion-induced senescence did not activate the DNA-damage response pathway and was p21-dependent. Further perturbations of mitosis, using an aurora kinase inhibitor, increased the number of senescent cells when combined with PKCι depletion. This suggests that PKCι depletion-induced senescence involves defects in mitotic progression. Senescent glioblastoma cells at a basal level of senescence in culture, induced by p21 overexpression, and induced after PKCι depletion had aberrant centrosomes. Mitotic slippage is an early exit from mitosis without cell division that occurs when the spindle assembly checkpoint (SAC) is not satisfied. Senescent glioblastoma cells had multiple markers of mitotic slippage. Therefore, PKCι depletion-induced senescence involves mitotic slippage and results in aberrant centrosomes. A U87MG cell line with a doxycycline-inducible shRNA targeting PKCι was developed to deplete PKCι in established xenografts. PKCι was depleted in established glioblastoma xenografts in mice and resulted in decreased cell proliferation, delayed tumor growth and improved survival. This study has demonstrated that both Hsp90 and PKCι are novel targets to induce senescence in cancer cells as a potential therapeutic approach.
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Inducing Cellular Senescence in CancerRestall, Ian J. January 2013 (has links)
Cellular senescence is a permanent cell cycle arrest that is induced as a response to cellular stress. Replicative senescence is a well-described mechanism that limits the replicative capacity of cells and must be overcome by cancer cells. Oncogene-induced senescence (OIS) is a form of premature senescence and a potent tumor suppressor mechanism. OIS is induced in normal cells as a result of deregulated oncogene or tumor suppressor gene expression. An exciting area of research is the identification of novel targets that induce senescence in cancer cells as a therapeutic approach. In this study, a novel mechanism is described where the inhibition of Hsp90 in small cell lung cancer (SCLC) cells induced premature senescence rather than cell death. The senescence induced following Hsp90 inhibition was p21-dependent and the loss of p21 allowed SCLC cells to bypass the induction of senescence. Additionally, we identified a novel mechanism where the depletion of PKCι induced senescence in glioblastoma multiforme (GBM) cells. PKCι depletion-induced senescence did not activate the DNA-damage response pathway and was p21-dependent. Further perturbations of mitosis, using an aurora kinase inhibitor, increased the number of senescent cells when combined with PKCι depletion. This suggests that PKCι depletion-induced senescence involves defects in mitotic progression. Senescent glioblastoma cells at a basal level of senescence in culture, induced by p21 overexpression, and induced after PKCι depletion had aberrant centrosomes. Mitotic slippage is an early exit from mitosis without cell division that occurs when the spindle assembly checkpoint (SAC) is not satisfied. Senescent glioblastoma cells had multiple markers of mitotic slippage. Therefore, PKCι depletion-induced senescence involves mitotic slippage and results in aberrant centrosomes. A U87MG cell line with a doxycycline-inducible shRNA targeting PKCι was developed to deplete PKCι in established xenografts. PKCι was depleted in established glioblastoma xenografts in mice and resulted in decreased cell proliferation, delayed tumor growth and improved survival. This study has demonstrated that both Hsp90 and PKCι are novel targets to induce senescence in cancer cells as a potential therapeutic approach.
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Measurement of analyte concentrations and gradients near 2D cell cultures and analogs using electrochemical microelectrode arrays: fast transients and physiological applicationsJose F. Rivera-Miranda (5930195) 12 October 2021 (has links)
This PhD research relates to the design,
fabrication, characterization, and optimization of on-chip electrochemical
microelectrode arrays (MEAs) for measurement of transient concentrations and
gradients, focusing on fast transients and physiological applications. In
particular, this work presents the determination of kinetic mechanisms taking
place at an active interface (either physiological or non-physiological) in
contact with a liquid phase using the MEA device to simultaneously estimate the
concentration and gradient of the analyte of interest at the surface of the
active interface. The design approach of the MEA device and the corresponding
measurement methodology to acquire reliable concentration information is
discussed. The ability of the MEA device to measure fast (i.e., in sub-second
time scale) transient gradients is demonstrated experimentally using a
controllable diffusion-reaction system which mimics the consumption of hydrogen
peroxide by a 2D cell culture. The proposed MEA device and measurement
methodology meet effectively most of the requirements for physiological applications
and as a demonstration of this, two physiological applications are presented.
In one application, the MEA device was tailored to measure the hydrogen
peroxide uptake rate of human astrocytes and glioblastoma multiforme cells in
2D cell culture as a function of hydrogen peroxide concentration at the cell
surface; the results allowed to quantitatively determine the uptake kinetics
mechanisms which are well-described by linear and Michaelis-Menten expressions,
in agreement with the literature. In the other application, further
customization of the MEA device was realized to study the glucose uptake
kinetics of human bronchial epithelial and small cell lung cancer cells, these
latter with and without DDX5 gene knockdown; the results allowed to distinguish
mechanistic differences in the glucose uptake kinetics among the three cell
lines. These results were complemented with measurements of glycolytic and
respiration rates to obtain a bigger picture of the glucose metabolism of the
three cell lines. Finally, additional applications, both physiological and
non-physiological, are proposed for the developed MEA device.
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Regulace genové exprese v nádorové tkáni / Regulation of Gene Expression in Tumour TissueKulda, Vlastimil January 2018 (has links)
Deregulation of gene expression caused by genetic or epigenetic changes plays an important role in pathogenesis of cancer. The thesis is a commented collection of ten publications dealing with the molecular biology of tumours. The author has significantly contributed to all of them. All the articles contained in the thesis are linked to the topic of assessment of molecules involved in gene expression regulation (microRNAs) or DNA alterations that affect gene expression (promoter methylation, presence of a fusion gene). MicroRNAs are short single-stranded RNA molecules involved in posttranscriptional regulation of gene expression by triggering mRNA degradation or inhibiting translation. It is a basic mechanism with an impact on all cellular processes including the pathogenesis of various diseases. MicroRNAs can either act as oncogenes by decreasing the expression of tumour-suppressor genes or as tumour-suppressor genes by decreasing the expression of oncogenes. However, the network of microRNA - RNA interactions is much more complex. Our published results that are part of this thesis are focused on colorectal carcinoma (CRC), prostate cancer, head and neck squamous cell carcinoma (HNSCC), gastric cancer and non-small cell lung cancer (NSCLC). In patients with CRC, we demonstrated the prognostic...
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Combinatorial Anticancer Therapy Strategy Using a Pan-Class I Glucose Transporter Inhibitor with Chemotherapy and Target Drugs in vitro and in vivoBachmann, Lindsey 28 April 2022 (has links)
No description available.
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Caractérisation moléculaire et fonctionnelle de cellules tumorales circulantes dans le cancer de la prostate et le cancer bronchique non à petites cellules / Molecular and functional characterization of circulating tumor cells in prostate cancer and non small cell lung cancerFaugeroux, Vincent 12 December 2017 (has links)
Les cellules tumorales circulantes (CTC) représentent une source de matériel tumoral accessible de manière non invasive, susceptible de fournir des informations cliniques et fondamentales. Ces cellules issues de tumeurs primitives ou métastatiques représentent une population hétérogène d’éléments très rares circulant dans le sang. La personnalisation des traitements en oncologie repose sur la caractérisation moléculaire de biopsies tumorales mais celles-ci peuvent être difficiles à réaliser ou peu informatives. De ce fait, la caractérisation moléculaire et fonctionnelle des CTC présente un double intérêt, clinique pour identifier des biomarqueurs de sensibilité à des traitements, et fondamental pour étudier les mécanismes qui sous-tendent leur potentiel à initier des tumeurs.Les objectifs de ma thèse ont été d’une part de caractériser par séquençage de l’exome (WES) les CTC à l’échelle de cellule unique de patients atteints de cancers de la prostate (PCa) métastatiques et d’autre part d’établir puis caractériser des modèles de xénogreffes dérivés de CTC (CDX) chez des patients atteints de cancers bronchiques non à petites cellules (CBNPC) ou de PCa.Pour répondre au premier objectif, nous avons développé une méthode expérimentale globale incluant trois approches technologiques permettant d’enrichir et d’isoler des CTC individuelles de différents phénotypes (épithélial, épithélio-mésenchymateux et mésenchymateux), d’amplifier la totalité du génome (WGA) et de le séquencer. Le WES a été réalisé pour 34 échantillons de CTC sélectionnés sur des critères de qualité du WGA, ainsi que pour les biopsies de métastases correspondantes chez sept patients. Deux patients présentant une hétérogénéité phénotypique de leurs CTC, ont été analysés en profondeur. Nous avons mis en évidence des mutations partagées entre les CTC et les biopsies tumorales correspondantes ainsi que des mutations uniquement retrouvées dans les CTC. Ces mutations spécifiques aux CTC sont présentes dans tous les phénotypes et affectent particulièrement les gènes impliqués dans le remodelage du cytosquelette, la réparation de l’ADN ou l’invasion. L’existence de mutations communes entre les CTC de différents phénotypes suggère une relation phylogénique entre ces cellules mais une évolution divergente pendant le processus métastatique. Ce travail est soumis pour publication.Dans la seconde partie de ma thèse, nous avons implantés les CTC de 67 patients atteints de CBNPC et 24 patients atteints de PCa chez des souris immunodéprimées. Nous avons établis quatre CDX de CBNPC et un CDX de PCa. La caractérisation de ces modèles, des biopsies tumorales, des CTC collectées au moment de la xénogreffe, des CDX et des lignées cellulaires établies à partir du CDX, ont révélé que les CTC, le CDX et les lignées cellulaires « miment » le phénotype et le profil mutationnel des biopsies tumorales. La caractérisation plus approfondie de l’une des lignées cellulaires montre la présence d’un stress réplicatif et d’une instabilité génomique élevée. Ce résultat nous oriente sur l’hypothèse d’un rôle éventuel de l’instabilité génomique dans la tumorigénicité des CTC.Dans ce travail, nous avons montré que le profil mutationnel des CTC présente de fortes similitudes avec les biopsies tumorales des patients dans les patients atteints de PCa étudiés. De plus, nous avons observé l’existence de mutations spécifiques aux CTC, non détectées dans les biopsies tumorales. Également, nous montrons que des CTC issues de CBNPC et de PCa sont tumorigéniques in vivo et qu’elles reflètent le profil mutationnel des biopsies tumorales des patients. Ces modèles constituent des outils originaux et intéressants pour identifier de nouvelles cibles thérapeutiques et stratégies anti-cancéreuses, et comprendre les mécanismes qui supportent le potentiel des CTC à initier des tumeurs. / Circulating tumor cells (CTCs) represents an non invasive source of tumor material which may provide clinical and basic information. These cells derived from primary or metastatic tumors represents an heterogeneous population of very rare events which circulates in the blood. Oncology personnalized medicine is based on biopsies molecular characterization but these are sometimes which difficult to realize and poorly informative. Thereby molecular and functional characterization of CTCs presents a double interest, clinical to identify treatments biomarkers sensitivity and basic to study mechanisms underlying their tumor inititiating cell (TIC) potential. The two goals of my thesis were on the one hand to characterize by whole-exome sequencing (WES) at the single level the CTCs from patients with metastatic prostate cancers (mPCa) and on the other hand to establish and characterize CTC-derived xenografts (CDX) from patients with non-small-cell lung cancer (NSCLC) or mPCa. For the first goal we developped a global workflow which include three technological approaches to enrich and isolate individual CTCs from different phenotype (epithelial, epithelial and mesenchymal, mesenchymal), to perform whole genome amplification (WGA) and to sequence them. WES was performed on 34 CTC samples selected according to WGA quality and on corresponding metastasis biopsies from seven patients. Two patients with phenotypic heterogeneity of CTCs were deeply analyzed. We highlighted shared mutations between CTCs and matched biopsies as well as mutations only detected in CTCs. These private CTC mutations are detected in all phenotype and particularly affect genes invlved in cytoskeleton remodeling, DNA repair or invasion. The existence of common mutations between CTCs from various phenotype suggests a phylogenic link between these cells but a divergent evolution during metastatic process. This work is submitted for publication. For the second goal, we implanted CTCs from 67 NSCLC patients and 28 mPCa patients in immunocompromised mice. We established four NSCLC CDX and one mPCa CDX. The characterization of tumor biopsies, CTCs collected at the time of xenograft, CDX and CDX-derived cell lines revealed that CTCs, CDX and cell lines miror the phenotype and mutational landscape of tumor biopsies. The more deeply characterization of one cell line show the presence of a high replicative stress and genomic instability. This result directs us to the hypothesis of a possible role of the genomic instability in CTC tumorigenicity.We demonstrated in this work that CTCs mutational landscape harbors high similairities with patients tumor biopsies in mPCa. Furthermore we observed CTC private mutations not detected in tumor biopsies. Also we showed that some CTCs from NSCLC and mPCa are tumorigenic in vivo and that these CTCs mirror mutational profile of patients tumor biopsies. These models are original and interesting tools to identify new therapeutic targets and anti-tumoral strategies and understand mechanisms underlying the TIC potential of CTCs.
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Effect of Tumor Microenvironmental Conditions on Non Small Cell Lung CancerArikatla, Swetha 01 January 2017 (has links)
Tumor microenvironmental conditions play a vital role in promoting metastasis and tumor recurrence. Due to inefficient vasculature, cancer cells experience hypoxia, glucose deprivation and low pH even during the early stages of tumor growth. Tumor cells are proposed to adapt to these microenvironmental conditions by acquiring increased migratory and invasion potential and tumor initiating ability. Our research addresses the effect of these biochemical factors of the tumor microenvironment (TME) on motility, epithelial to mesenchymal transition (EMT) and stemness of non-small cell lung cancer (NSCLC). NCI-H292 and NCI-H1650 NSCLC cell lines were used to measure the effect of the above mentioned TME conditions. Apart from acidic pH, low glucose and hypoxia, the effect of high glucose conditions was also measured on H292 and H1650 cell lines. Acidic pH, high and low glucose conditions were observed to have no effect on the motility, EMT and stemness of H1650 cell line. Hence, use of this cell line was discontinued and no further treatment conditions were tested on this cell line. In H292 cell line, acidic pH, low glucose and tumor like conditions combined together (acidic pH + low glucose + hypoxia) [AP+LG+HYP] significantly decreased motility whereas hypoxia significantly increased the motility of H292 cells. High glucose did not affect the motility of H292 cells. Although N-cadherin, a mesenchymal marker, expression was significantly upregulated by acidic pH, high and low glucose conditions, no direct correlation was observed between N-cadherin expression and motility. E-cadherin expression was not affected by acidic pH, high and low glucose conditions. An increase in N-cadherin expression and no change in E-cadherin expression under these conditions might be an indication of partial EMT. Hypoxia and AP+LG+HYP did not alter the expression of E-cadherin and N-cadherin. Although expression of vimentin, another mesenchymal marker, and Sox2, a cancer stem cell marker (CSC), was observed at the mRNA level, no expression of vimentin and Sox2 proteins was observed in H292 cells under any of these treatment conditions. The expression of OCT4, another CSC marker, was also not observed at the protein level in H292 cells. HIF-1α expression was observed in H292 cells under normoxic conditions and was unaffected by hypoxia and AP+LG+HYP. Therefore our research indicates that the effect of these TME conditions might be different on different cancer cell lines or cancer types. Not all cancers may depend on EMT for metastasis. An increase in metastasis under hypoxia may be independent of HIF-1α.
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