Leveraging Mammalian Cancers, Platinum-Quality Genome Assemblies, and Large-Scale Data to Identify Mechanisms of Rare Human Cancers

利用哺乳动物癌症、白金级基因组组装和大规模数据来识别罕见人类癌症的机制

• 批准号: 10334726
• 负责人: Kiley Graim
• 金额: $ 24.83万
• 依托单位: UNIVERSITY OF FLORIDA
• 依托单位国家: 美国
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-08-05 至 2027-07-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10334726
• 关键词: Adult; Affect; Algorithms; Atlases; Automobile Driving; Biological; Cancer Model; Cancer Patient; Clinical; Communities; Comparative Study; Complement; Data; Databases; Development; Early Diagnosis; Effectiveness; Epigenetic Process; Evolution; Foundations; Frequencies; Genes; Genetic; Genome; Genomics; Goals; Graph; Human; Immune system; In Vitro; Incidence; Individual; Joints; Link; Machine Learning; Malignant Childhood Neoplasm; Malignant Neoplasms; Mammalian Genetics; Maps; Methods; Modeling; Neoplasm Metastasis; Oncogenes; Oncology; Pan Genus; Pathway interactions; Patients; Pattern; Platinum; Predisposition; Process; Proliferating; Reporting; Research; Research Personnel; Resistance; Resources; Risk; Role; Sampling; Scientist; Surveys; Time; Training; Translating; Variant; Work; Zoo Animals; anticancer research; biomedical scientist; cancer gene expression; cancer initiation; cancer risk; cancer therapy; cohort; comorbidity; comparative; comparative genomics; deep learning algorithm; experience; genetic resource; genetic signature; genomic data; high throughput analysis; human data; human model; improved outcome; insight; large scale data; machine learning method; machine learning model; machine learning prediction; mammalian genome; new therapeutic target; novel; open source library; pre-clinical; precision medicine; rare cancer; recruit; reference genome; skills; success; tool; tumor; tumor microenvironment; tumor progression; user-friendly

PROJECT SUMMARY Studying cancer across a diverse array of species provides a unique opportunity to interrogate factors underpinning cancer initiation and progression and facilitating the modeling of new therapeutic targets in the setting of spontaneous tumors complicated by comorbidities and metastases. While there is extensive reporting of the frequency and diversity of tumors in animals from zoos, it has not been systematically linked to the plethora of genomic resources available. To facilitate the transition of comparative oncology studies from human plus one or two other species, to pan-mammalian analyses, we propose building a pan-mammalian tumor compendium and portal to easily disseminate our resource. We will develop and apply machine learning tools to detect patterns of cancer emergence and cancer resistance in human and non-human mammalian tumors. Our approach provides opportunities to leverage the largely understudied mammalian tumor data jointly with human data to identify reciprocal links between evolution and cancer resistance. This will allow us to make new human cancer discoveries through integrative analysis of high-throughput biological data in the context of mammalian species. We offer a powerful approach combining high-quality reference genomes and genomic data from hundreds of mammalian species with machine learning, that has the promise to unearth the evolutionary genetic underpinnings that are cornerstones of cancer initiation and progression. We will develop and apply models to identify mammalian tumors that effectively mimic rare human cancers, work with collaborators to acquire tumor samples from strongest identified mammalian models, then sequence and analyze these samples to validate their effectiveness as models of human cancers.

项目概要 研究多种物种的癌症为探究因素提供了独特的机会 支持癌症的发生和进展，并促进新治疗靶点的建模 自发性肿瘤并发合并症和转移的情况。虽然有大量报道 关于动物园动物肿瘤的频率和多样性，尚未系统地将其与过多的肿瘤联系起来。 可用的基因组资源。促进比较肿瘤学研究从人类加一的过渡 或其他两个物种，为了进行泛哺乳动物分析，我们建议建立一个泛哺乳动物肿瘤概要 和门户以轻松传播我们的资源。我们将开发并应用机器学习工具来检测 人类和非人类哺乳动物肿瘤的癌症出现和抗癌性模式。我们的 该方法提供了与人类联合利用大量未充分研究的哺乳动物肿瘤数据的机会 数据来确定进化和癌症抵抗力之间的相互联系。这将使我们能够创造新人类 通过对哺乳动物的高通量生物数据进行综合分析发现癌症 物种。我们提供了一种强大的方法，将高质量的参考基因组和来自的基因组数据相结合 数百种具有机器学习能力的哺乳动物物种有望揭示进化遗传 是癌症发生和进展的基石。我们将开发并应用模型 识别有效模仿罕见人类癌症的哺乳动物肿瘤，与合作者合作获取肿瘤 从最强的已识别哺乳动物模型中获取样本，然后对这些样本进行测序和分析以验证 它们作为人类癌症模型的有效性。