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Project 2: Immune signals promoting pancreas cancer stemness and progression

项目2：促进胰腺癌干性和进展的免疫信号

基本信息

批准号：
10704088
负责人：
STEVEN E ARTANDI
金额：
$ 41.46万
依托单位：
STANFORD UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-08-01 至 2026-07-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10704088
关键词：
Acinar Cell Affect Cell Communication Cells Chemoresistance Chronic Communication Development Disease Ductal Epithelial Cell Early Diagnosis Environment Epigenetic Process Experimental Models Feedback Fibroblasts Fibrosis Genetic Genetic Engineering Goals Growth Human Immune Immune signaling In Vitro Infiltration Inflammation Lead Link LoxP-flanked allele Malignant Neoplasms Malignant neoplasm of pancreas Mediating Methods Mus Neoplasm Metastasis Oncogenic Pancreas Pancreas Transplantation Pancreatic Ductal Adenocarcinoma Pancreatic Intraepithelial Neoplasia Pancreatic duct Pancreatitis Pathway interactions Patients Peripheral Phenotype Platelet-Derived Growth Factor alpha Receptor Play Population Process Prognosis Property Radiation therapy Recurrence Regulation Resistance Risk Factors Role STAT3 gene Sampling Shapes Signal Pathway Signal Transduction Stromal Cells Survival Rate TP53 gene Tamoxifen Testing Therapeutic Tumor Promotion Tumorigenicity Work acute pancreatitis cancer cell cancer stem cell cancer subtypes carcinogenesis chemotherapy chronic pancreatitis dimensional analysis driver mutation genetic approach immunoregulation improved in vivo insight interleukin-22 molecular targeted therapies mouse model novel pancreatic cancer cells pancreatic ductal adenocarcinoma cell pancreatic ductal adenocarcinoma model pancreatic stellate cell pharmacologic receptor selective expression single-cell RNA sequencing stemness synergism therapeutic evaluation therapeutic target tissue repair tumor microenvironment tumor progression tumorigenic

项目摘要

ABSTRACT (Project 2) There is an urgent need to discover improved therapies for pancreatic ductal adenocarcinoma (PDAC), which require a better understanding of mechanisms underlying development and recurrence. Chronic inflammation is a feature and an independent risk factor for PDAC. Interactions between immune cells, cancer associated fibroblasts (CAFs), and cancer cells can promote PDAC development and progression. However, little is known about how immune cells or immune cell-related signals affect PDAC development. Our long-term goal is to identify signaling nodes that facilitate the crosstalk between immune cells, cancer cells and CAFs to promote PDAC progression. In healthy subjects, IL-22 is expressed by immune cells while its receptor, IL22RA1, is selectively expressed in non-immune cells. IL-22 and IL-22RA1 expression are both elevated in PDAC, but little is known about the role of this signaling axis in PDAC. We have recently demonstrated high, heterogeneous expression of IL-22RA1 in human and mouse PDAC. Importantly, high IL-22RA1 expression is associated with poor prognosis of PDAC patients. Furthermore, we showed that IL-22RA1high cells in PDAC have cancer stem cell properties, including high tumorigenicity in vivo. We found that IL-22 stimulates IL22RA1 expression through STAT3 activation in PDAC cells, and postulate that this positive feedback loop enhances stemness and tumorigenicity of PDAC cancer cells. Thus, IL-22RA1/STAT3 signaling might provide a therapeutic target to treat PDAC with high IL-22RA1. We will use different mouse models of PDAC to study the effects of genetic deletion of IL-22RA1 in acinar cells or PSCs on PDAC growth, metastasis, and stemness in vivo. We will use novel, multi- dimensional analysis methods to analyze if inflammation drives carcinogenesis via IL-22, IL-22 expression in immune cell populations in PDAC mouse models and test therapeutic benefit of blocking IL-22 signaling in PDAC using pharmacologic and genetic approaches. We will determine the expression and role of IL-22/IL-22RA1 axis in human PDAC. Using primary human pancreatic ductal epithelial cells with defined PDAC genetic driver mutations, we will study the contribution and regulation of IL-22/IL-22RA1 signaling in human PDAC development. Our proposed studies will novel insights into how genetic drivers and inflammation orchestrate functional connection and communication between immune and non-immune components in PDAC. Further, we will gain mechanistic understanding of how (1) immune cell, CAF, and cancer cell interactions mediated by the IL-22/IL-22RA1 axis lead to PDAC development and (2) inhibition of the IL-22/IL-22RA1 signaling axis provides a therapeutic strategy that targets cancer stemness, a major factor in therapy resistance and the dismal prognosis associated with PDAC.

摘要（项目2）迫切需要发现胰腺导管腺癌（PDAC）的改进疗法，需要更好地了解发展和复发的机制。慢性炎症是PDAC的特征和独立风险因素。免疫细胞之间的相互作用，癌症相关成纤维细胞（CAF）和癌细胞可以促进PDAC的发展和进展。然而，了解免疫细胞或免疫细胞相关信号如何影响PDAC发育。我们的长期目标是识别促进免疫细胞、癌细胞和CAF之间串扰的信号节点，促进PDAC进展。在健康受试者中，IL-22由免疫细胞表达，而其受体IL22 RA 1在非免疫细胞中选择性表达。IL-22和IL-22 RA 1表达均升高， PDAC，但很少有人知道这个信号轴在PDAC中的作用。我们最近表现出了很高的， IL-22 RA 1在人和小鼠PDAC中异质表达。重要的是，高IL-22 RA 1表达是与PDAC患者预后不良相关。此外，我们还发现PDAC中IL-22 RA 1高表达细胞，具有癌症干细胞特性，包括体内高致瘤性。我们发现IL-22刺激IL在PDAC细胞中，通过STAT 3激活22 RA 1表达，并假设这种正反馈回路增强PDAC癌细胞的干性和致瘤性。因此，IL-22 RA 1/STAT 3信号传导可能提供一种治疗靶点，用于治疗具有高IL-22 RA 1的PDAC。我们将使用不同的PDAC小鼠模型来研究腺泡细胞或PSC中IL-22 RA 1基因缺失对PDAC生长、转移和干性的影响 in vivo.我们将使用新颖的、多维度的分析方法来分析炎症是否驱动 PDAC小鼠模型中通过IL-22、IL-22在免疫细胞群中表达的致癌作用和测试使用药理学和遗传学方法阻断PDAC中的IL-22信号传导的治疗益处。我们将确定IL-22/IL-22 RA 1轴在人PDAC中的表达和作用。使用原代人胰腺导管上皮细胞与定义的PDAC基因驱动突变，我们将研究的贡献和调控 IL-22/IL-22 RA 1信号转导在人PDAC发育中的作用。我们提出的研究将对遗传驱动因素和炎症如何协调提供新的见解 PDAC中免疫和非免疫成分之间的功能连接和沟通。此外，本发明还我们将获得如何（1）免疫细胞，CAF，和癌细胞相互作用介导的机制的理解， IL-22/IL-22 RA 1轴导致PDAC发展和（2）IL-22/IL-22 RA 1信号传导轴的抑制提供了一种治疗策略，靶向癌症的干性，治疗抵抗的主要因素，与PDAC相关的不良预后。