PROMINENT-DUKE

著名公爵

基本信息

批准号：
10845753
负责人：
CHRISTOPHER M COUNTER
金额：
$ 23.83万
依托单位：
DUKE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-06-22 至 2024-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10845753
关键词：
Address Aging Alcohol consumption Architecture Bioinformatics Biological Biological Models Body Weight decreased Breast CRISPR screen Cancer Etiology Cancer Model Cells Clonal Evolution Clustered Regularly Interspaced Short Palindromic Repeats Collection Colorectal Communities Country DNA Data Data Set Development Endogenous Factors Endometrial Environment Environmental Risk Factor Epidemiology Epigenetic Process Epithelial Cells Event Excision Exposure to Gene Expression Generations Genetic Genomics Goals High-Risk Cancer Human Individual Inflammation Intervention Intervention Studies Investigation Life Style Limited Stage Link Machine Learning Malignant - descriptor Malignant Neoplasms Maps Measures Methods Modeling Molecular Molecular Target Mus Mutate Mutation Neoplasms Normal Cell Normal tissue morphology Obesity Organoids Pathway Analysis Pathway interactions Pattern Phenotype Population Prevalence Process Proteome Proteomics Research Personnel Risk Risk Factors Role Route Sampling Structure of parenchyma of lung Testing Time Tissue Donors Tissue Sample Tissue imaging Tissues Tumor Promoters Tumor Promotion Tumor Tissue Tumor stage Unhealthy Diet anticancer research cancer prevention cancer risk carcinogenesis cellular targeting chemical property chemotherapy data integration detection method driver mutation environmental agent epidemiology study epigenomics experience genome-wide hematopoietic tissue human tissue immune cell infiltrate in vivo Model inhibitor innovation lifestyle factors mouse model multidisciplinary neoplastic novel promoter response small molecule smoking cessation stem stem cells tool transcriptomics tumor tumorigenesis whole genome

项目摘要

The cancer research community is on the verge of a major leap in our understanding of the factors that contribute to human cancer risk. While it is clear that mutations in DNA, either spontaneous or environmentally induced, are essential for cancer development, recent advances have highlighted the importance of non-mutagenic factors as rate-limiting determinants of cancer risk in human populations and in mouse cancer models. The root causes of human cancer have been widely debated, but most of the emphasis has been on the origins of the “driver” mutations that are ubiquitous in human tumours. Although epidemiology studies have highlighted the possible roles of lifestyle factors such as obesity, alcohol consumption, inflammation and poor diet in cancer risk, it has generally been assumed that these factors act directly or indirectly to cause mutations in DNA, thus contributing to tumour mutational burden and resulting in increased cancer risk. In contrast, recent sequencing studies have uncovered abundant mutations in normal human tissues, suggesting that even strong cancer driver mutations are not sufficient for cancer formation. These results were presaged by studies of mouse tumour models, some carried out more than 50 years ago, showing that promotion is the rate-limiting step in tumour development. To identify the mechanisms that control mutated normal cells, and to elucidate the precise mechanisms by which promoting factors stimulate the conversion of these cells to neoplastic growth, we have assembled a multidisciplinary team of investigators with wide-ranging experience in epidemiology, genetics, computational network analysis and machine learning, tissue imaging of gene expression, single cell transcriptomics, and genome-wide CRISPR functional screens. We will focus human analysis on a unique collection of several thousand human normal and matched tumour samples from >20 countries, including regions of both high and low cancer risk. Detailed risk factor information and whole genome sequence data is available from all these samples as part of the Grand Challenge Mutographs study. Analysis of these samples, together with detailed intervention studies in human populations, mouse models and human organoids, will allow us to develop a roadmap of tumour promotion from single normal cells carrying driver mutations, through to malignant progression. Our findings will facilitate identification of the causative environmental factors that promote cancer and provide routes to new methods and approaches to cancer prevention based on a deeper understanding of the process of initiated cell selection by tumour promoting agents.

癌症研究界在我们对人类癌症风险因素的理解上正处于重大飞跃的边缘，尽管很明显 DNA 突变（无论是自发的还是环境诱导的）对于癌症的发展至关重要，但最近的进展凸显了这一点。非诱变因素作为人类和小鼠癌症模型中癌症风险的限速决定因素的重要性。人类癌症的根本原因一直存在广泛争议，但大多数重点都集中在人类肿瘤中普遍存在的“驱动”突变的起源上，尽管流行病学研究强调了肥胖、酒精等生活方式因素的可能作用。消费、炎症和不良饮食与癌症风险有关，人们普遍认为这些因素直接或间接导致DNA突变，从而导致肿瘤突变负担并导致癌症风险增加。相反，最近的测序研究发现了大量的癌症风险。突变在正常人体组织中，即使是强的癌症驱动突变也不足以促进癌症的形成。这些结果是由小鼠肿瘤模型研究所预示的，其中一些研究是在 50 多年前进行的，表明促进是肿瘤的限速步骤。发展。为了确定控制突变正常细胞的机制，并阐明促进因子刺激这些细胞转化为肿瘤生长的精确机制，我们组建了一个多学科研究团队，他们在流行病学、遗传学、计算网络方面拥有广泛的经验我们将重点对来自超过 20 个国家（包括多个地区）的数千个人类正常和匹配肿瘤样本进行人体分析。作为 Grand Challenge Mutographs 研究的一部分，可以从所有这些样本中获取高和低癌症风险，以及对人群、小鼠模型和人类类器官的详细干预研究。，将使我们能够制定从携带驱动突变的单个正常细胞到恶性进展的肿瘤促进路线图，我们的研究结果将有助于识别促进癌症的致病环境因素，并为基于癌症预防的新方法和途径提供途径。更深入地了解肿瘤促进剂启动细胞选择的过程。