Investigating lineage plasticity in castration-resistant prostate cancer

研究去势抵抗性前列腺癌的谱系可塑性

• 批准号: 10164741
• 负责人: MICHAEL M. SHEN
• 金额: $ 42.79万
• 依托单位: COLUMBIA UNIVERSITY HEALTH SCIENCES
• 依托单位国家: 美国
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-07-01 至 2025-06-30
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10164741
• 关键词: 3-Dimensional; Adenocarcinoma; Adenocarcinoma Cell; Adopted; Affect; Androgen Antagonists; Androgen Receptor; Antiandrogen Therapy; Biochemical; Biological Assay; Biological Models; Cells; ChIP-seq; Characteristics; Chromatin; Clinical; Clustered Regularly Interspaced Short Palindromic Repeats; Complex; Computer Analysis; DNA Methylation; DNA Modification Methylases; Data; Development; Disease; EZH2 gene; Epigenetic Process; Epithelial; Genetically Engineered Mouse; Genitourinary system; Genomics; Histones; Human; Investigation; Laboratories; Lead; Malignant neoplasm of prostate; Mediating; Metastatic Prostate Cancer; Modeling; Modification; Molecular; Molecular Analysis; Molecular Computations; Mus; Neuroendocrine Cell; Neuroendocrine Prostate Cancer; Neuroendocrine Tumors; Neurosecretory Systems; Organoids; Pathology; Pathway interactions; Patients; Pattern; Pharmaceutical Preparations; Pharmacology; Phenotype; Play; Polycomb; Population; Population Heterogeneity; Property; Prostate; Prostate Cancer therapy; Prostatic Neoplasms; Relapse; Resistance; Sampling; System; Systems Biology; Transitional Cell; Validation; XCL1 gene; abiraterone; base; bisulfite sequencing; candidate validation; castration resistant prostate cancer; cell type; drug candidate; effective therapy; epigenetic regulation; gain of function; improved; in vivo; innovation; insight; interest; methylation pattern; mouse model; neuroendocrine differentiation; new therapeutic target; novel; novel therapeutics; programs; receptor expression; recruit; single-cell RNA sequencing; therapeutic target; therapy resistant; transdifferentiation; translational impact; tumor; whole genome

Project Summary The clinical use of anti-androgens such as abiraterone and enzalutamide has greatly improved prostate cancer treatment, but patients treated with these drugs still relapse with more aggressive forms of the disease, collectively termed as castration-resistant prostate cancer (CRPC). These forms of CRPC are characterized by increased lineage plasticity, often associated with loss of androgen receptor (AR) expression and neuroendocrine differentiation. Our laboratory focuses on analyses of cell type differentiation in the normal and transformed prostate epithelium, and has recently used genetically-engineered mouse models to show that neuroendocrine cells in CRPC arise by transdifferentiation from luminal adenocarcinoma cells. In preliminary studies for this proposal, we have generated organoid models of CRPC from these mouse prostate tumors, and have demonstrated by single-cell RNA sequencing that these organoids recapitulate much of the spectrum of human CRPC, including distinct heterogeneous populations composed of AR-pathway positive prostate cancer, neuroendocrine prostate cancer, and double-negative prostate cancer. Further analysis of these organoid lines has revealed a complex genomic landscape of chromatin accessibility, and has identified active histone marks that are associated with neuroendocrine differentiation. These findings indicate that epigenetic reprogramming may play a key role in the lineage plasticity of castration-resistant prostate cancer. Based on these preliminary data, we hypothesize that molecular analysis of epigenetic reprogramming in castration-resistant prostate cancer will identify candidate drivers and mechanisms of lineage plasticity. To investigate this hypothesis, we will pursue three innovative aims that integrate in vivo, ex vivo, molecular, and computational systems approaches to analyze genetically-engineered mouse models, organoids, grafts, and human prostate tumor samples. Our specific aims are as follows: (1) Analysis of lineage plasticity in CRPC organoid and mouse models to examine potential pathways of interconversion between distinct forms of CRPC; (2) Investigation of epigenetic pathways in CRPC organoid models by examining chromatin accessibility, histone marks, and DNA methylation patterns to identify epigenetic marks and regulators that drive lineage plasticity; and (3) Functional analysis of candidate regulators of lineage plasticity in CRPC using computational systems approaches to identify candidate regulators of plasticity followed by experimental validation using organoid and graft assays together with analyses of human tumor samples. Overall, these studies will provide essential insights into the molecular basis of lineage plasticity and treatment resistance in prostate cancer, and will have significant implications for the development of novel therapies.

项目摘要 抗雄激素（例如阿比罗酮和恩扎拉胺）的临床使用大大改善了前列腺 癌症治疗，但是用这些药物治疗的患者仍然会以更具侵略性的疾病复发， 统称为cast割的前列腺癌（CRPC）。这些形式的CRPC的特征是 谱系可塑性增加，通常与雄激素受体（AR）表达的丧失有关 神经内分泌分化。我们的实验室重点是在正常和 转化的前列腺上皮，最近使用了基因工程的小鼠模型表明 CRPC中的神经内分泌细胞是通过腔腺癌细胞转分化而引起的。在初步 为此提案的研究，我们从这些小鼠前列腺肿瘤中产生了CRPC的类器官模型，并且 通过单细胞RNA测序证明了这些类器官概括了许多光谱 人CRPC，包括由AR-Pathway阳性前列腺癌组成的不同异质种群， 神经内分泌前列腺癌和双阴性前列腺癌。对这些类型线的进一步分析 已经揭示了染色质可及性的复杂基因组景观，并鉴定了活跃的组蛋白标记 与神经内分泌分化有关的。这些发现表明表观遗传重编程 可能在耐cast割前列腺癌的谱系可塑性中起关键作用。 基于这些初步数据，我们假设表观遗传重编程的分子分析 在cast割的前列腺癌中，将确定候选驱动因素和谱系可塑性的机制。到 调查这一假设，我们将追求三个创新的目标，这些目标在体内，离体，分子和 计算系统的方法来分析遗传学工程的小鼠模型，器官，移植物和 人前列腺肿瘤样品。我们的具体目的如下：（1）CRPC中谱系可塑性的分析 器官和小鼠模型检查不同形式的CRPC之间的互连潜在途径； （2）通过检查染色质可及性，组蛋白来研究CRPC类器官模型中表观遗传途径 标记和DNA甲基化模式，以识别驱动谱系可塑性的表观遗传标记和调节剂； （3）使用计算系统对CRPC中谱系可塑性的候选调节剂的功能分析 确定可塑性调节因子的方法，然后使用类angeroid和 移植分析以及对人肿瘤样品的分析。总体而言，这些研究将提供必不可少的 深入了解前列腺癌中谱系可塑性和治疗耐药性的分子基础，并将具有 对新疗法的发展具有重要意义。