<b>Agent-Based Modeling of </b><b>Cell Culture Granuloma Models: </b><b>The Role of Structure, Dimension, Collagen, and Matrix Metalloproteinases</b>

Alexa A Petrucciani (18422784)

22 April 2024

<p dir="ltr">Tuberculosis (TB) remains a global public health crisis, causing over 10 million new infections and 1.3 million deaths in 2022 alone. TB is caused by <i>Mycobacterium tuberculosis </i>(<i>Mtb</i>), which initiates heterogeneous pathology in the lungs, including granulomas and cavities. Granulomas are organized structures of immune cells, traditionally thought to contain bacteria. Cavities are pathological spaces caused by the destruction of extracellular matrix (ECM), which can worsen disease outcomes and cause long-lasting pulmonary impairment.<i> In vitro </i>methods are commonly used to study host-pathogen interactions in <i>Mtb</i> infection, and recent developments have led to models that represent the TB granuloma environment more closely than traditional cell culture. These advances include the development of 3D models and the inclusion of physiological ECM components like collagen. Increasing complexity has been accomplished in a piece-wise manner – minimally necessary components are included to minimize cost while maintaining throughput and tractability. This creates a need for tools to analyze these systems and, more importantly, integrate the independent data created. We developed an agent-based model to characterize multiple <i>in vitro</i> models of TB and apply it to 1) separate the contributions of dimension and structure to bacterial control in granuloma-like spheroids and 2) explore how the interactions of collagen and matrix metalloproteinases (MMP) contribute to clinically relevant outputs such as bacterial load and ECM destruction. The model provides insights into the role of granuloma structure and the conflicting results of MMP inhibition, generating new hypotheses to be tested in tandem with <i>in vitro</i> models.</p>

Immunology not elsewhere classified

tuberculosis

agent-based modeling

spatial model simulation

cell culture models

spheroid culture experiments

collagen

Matrix metalloproteinase

<b>Reprogramming the Pancreatic Cancer Stroma by Targeting Coagulation at the Tumor Microenvironment</b>

Sae Rome Choi (18392505)

17 April 2024

<p dir="ltr">Pancreatic ductal adenocarcinoma (PDAC) remains one of the most deadliest cancer and despite advancements in cancer therapy, remain highly refractory to treatment, largely due to its desmoplastic tumor microenvironment (TME) characterized by complex interactions among cancer cells and stromal components. Particularly, the PDAC associated coagulation system due to leaky tumor vasculatures plays a pivotal role in reshaping the PDAC stroma and its pathogenesis. Understanding the intricate interplay between tumor cells, stromal cells, and the elevated coagulation pathway elements, including tissue factor, thrombin, and fibrin, is essential for developing effective therapeutic strategies. To address these challenges, this research proposes the engineering of a novel PDAC-associated coagulation system using a microfluidic technology, known as coagulation-on-tumor-microenvironment-on-chip (cT-MOC). The study aims to integrate key coagulation pathways in cT-MOC to investigate pivotal interactions in the PDAC stroma: <i>i)</i> thrombin-protease-activated receptors (PARs) mediated promotion of PDAC fibrosis via activation of cancer-fibroblast cross-talk; <i>ii)</i> in-depth analysis of transport and mechanical properties of collagen-fibrin microstructure; <i>iii)</i> inhibited drug delivery in reprogrammed PDAC stroma due to pronounced fibrin deposition on collagen. By leveraging innovative microfluidic technologies and comprehensive experimental approaches, the research endeavors to provide a novel platform that bridges traditional <i>in vitro</i> and <i>in vivo</i> models to overcome the challenges posed by the desmoplastic TME and enhance therapeutic strategies for treatment by targeting the coagulation at the PDAC TME.</p>

Cancer cell biology

Cancer diagnosis

Chemotherapy

Solid tumours

Biofabrication

Biomaterials

Biomechanical engineering

Tissue engineering

pancreatic adenocarcinoma cancer ce...

lab on-a-chip device

preclinical cancer models

Tissue engineered cell culture models

drug delivery & targeting

Expression génique dans les cancers thyroïdiens post-Tchernobyl et dans des modèles cellulaires in vitro suite à des traitements épigénétiques / Gene expression in post-Chernobyl thyroid cancers and in in vitro cell culture models after epigenetic treatments

Dom, Geneviève

29 April 2014

Dans la première partie du travail, nous avons étudié l’expression génique dans les cancers thyroïdiens survenus après l’explosion de la centrale nucléaire de Tchernobyl. L’incidence des cancers thyroïdiens papillaires a fortement augmenté après l’accident de Tchernobyl chez les enfants, offrant l’opportunité exceptionnelle d’étudier les caractéristiques moléculaires des cancers thyroïdiens radioinduits. Contrairement aux études précédentes qui comportaient toutes des facteurs confondants, nous avons pu investiguer l’expression des ARN messagers des tumeurs et de leurs tissus contra-latéraux normaux de patients exposés et de patients non exposés aux retombées radioactives, en utilisant une cohorte de patients appariés pour l’âge et l’ethnicité. L’irradiation d’une population conduit au développement de cancers dans une fraction de cette population. Les individus atteints peuvent l’avoir été de manière stochastique, ou à cause d’une prédisposition ou sensibilité particulière à l’irradiation. La comparaison des tumeurs exposées et non exposées permet d’étudier l’effet de l’irradiation, et celle des tissus normaux contralatéraux offre la possibilité d’étudier la susceptibilité aux radiations dont les implications sont nombreuses en médecine (radio-diagnostic, cancers secondaires) et en radioprotection. L’expression génomique complète a été analysée sur puces Affymetrix pour les tissus de 45 patients. Vingt-deux de ces patients ont été exposés aux retombées de Tchernobyl, vingt-trois autres, appariés selon l'âge et résidant dans les mêmes régions de l'Ukraine, n'ont pas été exposés à l’irradiation. Notre travail a mis en évidence l’existence d’une signature transcriptionnelle permettant de différencier les tissus normaux exposés des non exposés, les gènes qui composent cette signature ayant trait à la prolifération ;nos résultats suggèrent qu’un niveau plus élevé de prolifération dans les tissus normaux pourrait être associé aux cancers radioinduits, soit en tant que facteur prédisposant au cancer, soit en tant que conséquence de la radiation.<p><p>La deuxième partie du travail a été consacrée à la caractérisation in vitro de différentes lignées cellulaires humaines de cancers thyroïdiens. Ces lignées sont souvent employées comme modèles pour l’étude et le développement d’approches thérapeutiques pour ces cancers mais notre laboratoire a démontré que ces lignées s’étaient dédifférenciées au cours de leur propagation in vitro et que leurs profils transcriptionnels se rapprochaient essentiellement des tumeurs les plus dédifférenciées, les cancers anaplasiques. Nous avons tenté de ré-induire dans ces lignées l’expression des marqueurs de différenciation de la thyroïde au moyen d’agents épigénétiques, l’idée étant que ces gènes dont l’expression est caractéristique de la thyroïde ne s’expriment plus suite à l’action de mécanismes épigénétiques comme la méthylation au niveau de leurs promoteurs. Les cancers thyroïdiens dédifférenciés étant les plus agressifs et ayant perdu l’expression des facteurs de différenciation dont le transporteur sodium/iodure (NIS), ils sont inaccessibles au traitement par l’iode radioactif I131. La réexpression des marqueurs de différenciation thyroïdienne permettrait d’une part d’employer plus adéquatement les lignées comme modèle d’étude des cancers différenciés, et d’autre part d’envisager l’emploi de(s) substances(s) qui ont permis cette réexpression en tant que médicaments pour les cancers dédifférenciés. Nos travaux montrent que les traitements épigénétiques des lignées cancéreuses ne permettent pas une réinduction significative de la différenciation mais tendent à démontrer que l’inactivation épigénétique provoque dans ces lignées la perte de l’expression de gènes n’ayant aucun rôle utile pour la cellule au cours des milliers de réplications in vitro / In the first part of the work, we studied gene expression in thyroid cancers following the explosion of the Chernobyl nuclear power plant. The incidence of thyroid papillary cancers rose sharply after the Chernobyl accident in children, providing an exceptional opportunity to study the molecular characteristics of radiation-induced thyroid cancers. Unlike previous studies that included confounding factors, we were able to investigate the expression of messenger RNA from tumors and their normal contra-lateral tissue of patients exposed and not exposed to the fallout using a cohort of patients matched for age and ethnicity. The irradiation of a population leads to the development of cancer in a fraction of the population. Affected individuals may have been stochastically, or because of a particular predisposition or susceptibility to irradiation. Comparison of tumors exposed and unexposed allows to study the effect of irradiation, and the contra-lateral normal tissue offers the possibility to study the susceptibility to radiation whose implications are numerous: medical (radio - diagnosis, secondary cancers ) and radiation protection. The complete gene expression was analyzed on Affymetrix for tissues of 45 patients. Twenty- two of these patients were exposed to fallout from Chernobyl, twenty-three, matched for age and residing in the same regions of Ukraine have not been exposed to radiation. Our work has demonstrated the existence of a transcriptional signature allowing to differentiate exposed and unexposed normal tissues, and the genes that compose the signature are related to proliferation; our results suggest that a higher level of proliferation in normal tissues may be associated with radiation-induced cancers, either as a predisposing factor for cancer,or as a result of the radiation.<p><p>The second part was devoted to the in vitro characterization of different human cell lines of thyroid cancer. These lines are often used as models for the study and development of therapeutic approaches for these cancers, but our laboratory has demonstrated that these cell lines dedifferentiated during their in vitro propagation and their transcriptional profiles are essentially closer to the most dedifferentiated tumors, the anaplastic cancers. We tried to re- induce in these lines the expression of differentiation markers of thyroid using epigenetic agents, the idea being that these genes whose expression is characteristic of thyroid are no longer expressed due to epigenetic mechanisms such as methylation of their promoters. Dedifferentiated thyroid cancers are more aggressive and have lost the expression of differentiation factors including sodium/iodide transporter(NIS), they are inaccessible to treatment with radioactive iodine I131. Re-expression of thyroid differentiation markers could allow in one hand to use more adequately cell lines as models to study differentiated cancers, and secondly to consider the used substances that helped this re-expression as drugs for the dedifferentiated cancers. Our work shows that epigenetic treatments for cancer cell lines do not allow a significant re-induction of differentiation but tend to demonstrate that the epigenetic inactivation in these cell lines causes the loss of expression of genes that have no useful role in the cells over thousands of replication in vitro .<p><p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Disciplines biomédicales diverses

Médecine pathologie humaine

Thyroid gland -- Cancer

Thyroid gland -- Cancer -- Treatment

Gene expression

Epigenetics

Thyroïde -- Cancer

Thyroïde -- Cancer -- Traitement

Expression génique

Epigénétique

expression génique

cancer de la thyroïde

cell culture models

NIS

epigenetic drugs

modèles cellulaires

gene expression

Tchernobyl