Download Free Deciphering The Immunosuppressive Landscape Of High Grade Serous Ovarian Cancer Book in PDF and EPUB Free Download. You can read online Deciphering The Immunosuppressive Landscape Of High Grade Serous Ovarian Cancer and write the review.

High-grade serous ovarian cancer (HGSC) remains the most common and lethal subtype of ovarian cancer with a 5-year survival rate of ~30%, highlighting an urgent need for new treatments. Cancer immunotherapy has emerged as an efficacious strategy aimed at harnessing the exquisite capabilities of our immune system to destroy malignant cells. However, the development of more effective immunotherapies is hampered by our limited understanding of the phenotype of bona fide tumor-reactive T cells versus irrelevant bystanders. Further, T cells that exhibit tumor specificity appear to encompass a tissue resident memory (TRM) phenotype but combat a harsh immunosuppressive tumor microenvironment, often leading to an exhausted phenotypic state and evasion of immune-mediated destruction. These insights have led to rapid clinical implementation of so-called "checkpoint blockade" therapies that re-invigorate T cell-mediated tumor destruction by blocking surface inhibitory receptors or ligands. Thus, by identifying the phenotype of prognostically favourable TRM T cells and the immunosuppressive networks they face, my thesis work tackles a critical challenge in designing the next generation of therapeutic interventions for this disease. To address this challenge, I hypothesized that (1) the TRM phenotype could be modulated for improving adoptive T cell therapy; (2) TRM TIL characterized by the co-expression of CD103, PD-1, and CD39 in HGSC provide improved prognostic benefit indicative of enriched tumor reactivity; (3) the TIGIT/CD155 signalling axis plays a crucial role in shaping the immunosuppressive landscape impeding TRM T cells in HGSC. Firstly, I developed methods for modulating the TRM phenotype on expanded human and murine T cells for adoptive cell therapy and assessed the therapeutic impact of these phenotypes. Secondly, we applied high-dimensional flow cytometry, single-cell sequencing, and multiplexed immunofluorescence to primary human HGSC specimens to explore the single-cell phenotypic profiles and prognostic significance of tumor-infiltrating T cells co-expressing three putative markers of tumor reactivity: CD39, CD103, and PD-1. These 'triple-positive' T cells exhibited a highly activated/exhausted phenotype and superior prognostic value relative to all other T-cell subsets, suggesting these markers enrich for tumor-reactive clones. Furthermore, these triple-positive cells exhibited heightened expression of the inhibitory checkpoint TIGIT, which plays a prominent role in tumor-mediated immune suppression. Finally, to explore the therapeutic implications of this finding, we investigated the relationship between the TIGIT signaling axis on TIL and prognosis in HGSC. Once again utilizing high-dimensional flow cytometry, multi-color histological imaging, and gene expression profiling we found T cells from HGSC frequently express TIGIT ex vivo and post-clinical expansion. Further, CD155, the dominant ligand for TIGIT, was largely expressed on malignant epithelium in HGSC and showed a negative association with immune infiltration. Thus, TRM T cells represents a compelling immunotherapeutic immune subset in HGSC and one that could be bolstered by immune checkpoint inhibition of the TIGIT/CD155 axis.
In an era of promising advances in cancer research, there are considerable and even alarming gaps in the fundamental knowledge and understanding of ovarian cancer. Researchers now know that ovarian cancer is not a single disease-several distinct subtypes exist with different origins, risk factors, genetic mutations, biological behaviors, and prognoses. However, persistent questions have impeded progress toward improving the prevention, early detection, treatment, and management of ovarian cancers. Failure to significantly improve morbidity and mortality during the past several decades is likely due to several factors, including the lack of research being performed by specific disease subtype, lack of definitive knowledge of the cell of origin and disease progression, and incomplete understanding of genetic and non-genetic risk factors. Ovarian Cancers examines the state of the science in ovarian cancer research, identifies key gaps in the evidence base and the challenges to addressing those gaps, considers opportunities for advancing ovarian cancer research, and examines avenues for translation and dissemination of new findings and communication of new information to patients and others. This study makes recommendations for public- and private-sector efforts that could facilitate progress in reducing the incidence of morbidity and mortality from ovarian cancers.
This volume includes contributions from the speakers of the Second IMD Congress (September 10-15, 2007; Moscow, Russia) who were eager to share some of the academic and clinical enthusiasm that defines the IMD meetings. The goal of the International Immune-Mediated Diseases: From Theory to Therapy (IMD) Congress is to bring the world’s best immunologists and clinicians to Moscow.
Overcoming Ovarian Cancer Chemoresistance presents non-overlapping review chapters that discuss the state of the field in overcoming chemoresistance of ovarian cancer and treatment options before and following recurrence, considering the genetic makeup of the ovarian cancer patient and her tumor. With the uptake of both germline and somatic gene testing, clinicians can obtain a more comprehensive understanding of ovarian tumors and this book provides information to link the genetic makeup of a tumor (or patient) with the best available treatment. The book discusses topics such as strategies to fight chemo-resistance in ovarian cancer, circulating DNA as a monitor of response, BRCA mutations, ovarian cancer stem cells, immunotherapy and vaccines. Additionally, it brings a list of promising agents at clinical and pre-clinical stage that will impact the treatment in the near future. This book is a valuable source for cancer researchers, oncologists and several members of biomedical field who need to understand how to battle chemoresistance in ovarian cancer. Provides a comprehensive view of both biological and genetic determinants of resistance, as well as technical approaches to monitor response Discusses genetic reversions as a unique alteration and a new field of study Includes a chapter on upcoming and promising agents that are in the pre-clinical and early clinical space, to set the stage for future directions in the field
This book is a printed edition of the Special Issue "The Tumor Microenvironment of High Grade Serous Ovarian Cancer" that was published in Cancers
Cancer immunotherapy, including immune checkpoint inhibitors (ICIs) and chimeric antigen receptor T-cell (CAR-T) therapy, has revolutionized the paradigm in cancer treatment. However, the clinical outcome of immunotherapy varies considerably among patients and only a minority of patients achieve long-term clinical benefits. This is largely attributed to the fact that existing cancer immunotherapies, which concentrate on several classical targets (CTAL-4, PD-1/PD-L1, etc.) and limited types of immune cell populations (T cells), are insufficient to cope with the complexity of highly heterogeneous tumor microenvironment (TME). This calls for more efforts to not only expand our toolbox for manipulating anticancer immunity but also diversify our combinational strategies. To this end, it is urgent to deeper our understanding of cancer immunotherapy by using both experimental and computational methodologies from multi-scale perspectives: 1) novel targets from either tumor cells or non-tumor cells within TME (e.g., tumor intrinsic resistance drivers, new immune checkpoints, neoantigens), 2) in-depth characterization of more immune cell populations (e.g., macrophages, Tregs, B cells) and their interactions and dynamics within TME, 3) landscape of actionable targets in patient populations for combination design. These efforts will open the avenue of rational design of combinational immunotherapies, allowing researchers and clinicians to design novel targeting therapeutics or to optimally orchestrate combinatory strategies aiming to surmount resistance mechanisms and improve clinical outcomes.
The present book on Molecular & Diagnostic Imaging and Treatment Strategies of ovarian cancer is one of two companion books with the second one being focused on Cell and Molecular Biology of Ovarian Cancer. Both books include new exciting aspects of ovarian cancer research with chapters written by experts in their respective fields who contributed their unique expertise in specific ovarian cancer research areas and include cell and molecular details that are important for the specific subtopics. Comprehensive and concise reviews are included of key topics in the field.
Recent studies have highlighted that epithelial-mesenchymal transition (EMT) is not only about cell migration and invasion, but it can also govern many other important elements such as immunosuppression, metabolic reprogramming, senescence-associated secretory phenotype (SASP), stem cell properties, therapy resistance, and tumor microenvironment interactions. With the on-going debate about the requirement of EMT for cancer metastasis, an emerging focus on intermediate states of EMT and its reverse process mesenchymal-epithelial transition (MET) offer new ideas for metastatic requirements and the dynamics of EMT/MET during the entire metastatic cascade. Therefore, we would like to initiate discussions on viewing EMT and its downstream signaling networks as a fulcrum of cellular plasticity, and a facilitator of the adaptive responses of cancer cells to distant organ microenvironments and various therapeutic assaults. We hereby invite scientists who have prominently contributed to this field, and whose valuable insights have led to the appreciation of epithelial-mesenchymal plasticity as a more comprehensive mediator of the adaptive response of cancer cells, with huge implications in metastasis, drug resistance, tumor relapse, and patient survival.