Exploring the Role of Drp1 in Colorectal Cancer

探索 Drp1 在结直肠癌中的作用

基本信息

批准号：
10231360
负责人：
Sumati Raj Hasani
金额：
$ 3.44万
依托单位：
UNIVERSITY OF KENTUCKY
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：
2021-04-01 至 2024-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10231360
关键词：
Acetylation Address Animal Model Attenuated Biochemical Biochemistry Bioenergetics Cancer Center Cancer Etiology Cancer Model Cell Communication Cell Survival Cellular biology Cessation of life Colon Carcinoma Colorectal Cancer Committee Members Consumption Data Development Disease Down-Regulation Environment Fatty Acids Fatty acid glycerol esters Goals High Fat Diet Homeostasis Image Immunofluorescence Immunologic Immunoprecipitation Incidence Kentucky Knock-out Knockout Mice Knowledge Lead Malignant Neoplasms Mediating Mentors Metabolic Metabolic Pathway Mitochondria Modeling Molecular Monomeric GTP-Binding Proteins Mus Nuclear Obesity Organelles Organoids Phosphorylation Play Property Regulation Research Risk Factors Role Signal Pathway Signal Transduction Site Stress Testing Tissues Training United States Universities Up-Regulation WNT Signaling Pathway Western Blotting base beta catenin cancer cell cancer stem cell cancer type career epidemiology study experience experimental study fatty acid metabolism fatty acid oxidation in vivo insight mitochondrial fitness mitochondrial metabolism mortality mouse model neoplastic cell novel novel therapeutics personalized medicine receptor recruit stem cell function tumor tumor initiation tumor microenvironment tumor progression tumorigenesis uptake western diet

项目摘要

Abstract - Exploring the Role of Drp1 in Colorectal Cancer. Colorectal cancer is the second leading cause of cancer-related deaths in the United States. Approximately 150,000 new cases and 50,000 deaths are predicted for the year 2020. Emerging research suggests that the dysregulation of mitochondrial fitness due to an imbalance in mitochondrial dynamics can lead to metabolic reprogramming in various cancer types. A number of epidemiological studies indicate that obesity is as a major risk factor for several types of cancer including colorectal cancer. Our group and others have shown that increased uptake of fatty acids promotes the development and progression of difference cancers by altering metabolic pathways to favor mitochondrial fatty acid oxidation. However, the molecular mechanisms by which fatty acid consumption influences mitochondrial fitness to promote tumor cell survival and progression is poorly understood. In this proposed study, I plan to investigate the signaling crosstalk between mitochondrial dynamics and fatty acid metabolism in colorectal cancer. In my preliminary experiments, I discovered that fatty acid uptake promotes mitochondrial fragmentation by activating Drp1, a small GTPase required for mitochondrial fission, by increasing the phosphorylation at the S616 site and its interaction with mitochondria. Importantly, silencing Drp1 inhibits cancer stem cell functions by attenuating Wnt signaling in colon cancer cells. The central hypothesis is that Drp1-dependent mitochondrial fission is required for fatty acids to promote tumor progression in colon cancer. Specifically, I will determine how fatty acid uptake alters Drp1 activity and how mitochondrial dynamics augments cancer stem cell functions to drive tumorigenesis in vivo. The following specific aims are proposed: 1) to delineate the molecular mechanism by which fatty acid uptake enhances Drp1 activity; 2) to determine the functional importance of Drp1 in promoting CSC functions in colorectal cancer; and 3) to define the role of Drp1 in regulating tumorigenesis using in vivo colon cancer models. Results from this study will provide novel insights into the role of mitochondrial dynamics in connecting cellular metabolic pathways with cancer stem cell signaling. Dr. Gao has extensive experience in studying the regulation of signaling pathways and mitochondrial metabolism in colorectal cancer. I will also benefit from additional expertise provided by my committee members and state- of-the-art facilities of the Markey Cancer Center at the University of Kentucky. A comprehensive training plan has been developed to fit my research background and career goals. Based on my strong preliminary data, with my mentor’s knowledge and training, and the excellent research environment at the Department of Molecular and Cellular Biochemistry and the Markey Cancer Center I am confident that this project will be successful. Ultimately, this study will help develop personalized treatment options by targeting mitochondrial dynamics to eradicate cancer stem cells.

摘要 - 探索 Drp1 在结直肠癌中的作用。结直肠癌大约是美国癌症相关死亡的第二大原因。预计 2020 年将出现 150,000 例新病例和 50,000 例死亡。新兴研究表明，由于线粒体动力学不平衡而导致的线粒体适应性失调可能导致代谢紊乱许多流行病学研究表明，肥胖是多种癌症类型中的一个主要因素。我们的小组和其他人已经表明，包括结直肠癌在内的几种癌症的危险因素。增加脂肪酸的摄入可通过改变促进不同癌症的发生和进展有利于线粒体脂肪酸氧化的代谢途径然而，其分子机制。脂肪酸消耗影响线粒体健康，促进肿瘤细胞存活和进展效果不佳在这项拟议的研究中，我计划研究线粒体动力学之间的信号串扰。在我的初步实验中，我发现脂肪酸的摄取。通过激活 Drp1（线粒体裂变所需的一种小 GTP 酶）来促进线粒体断裂增加 S616 位点的磷酸化及其与线粒体的相互作用，重要的是，沉默 Drp1。通过减弱结肠癌细胞中的 Wnt 信号传导来抑制癌症干细胞功能。 Drp1 依赖性线粒体裂变是脂肪酸促进结肠肿瘤进展所必需的具体来说，我将确定脂肪酸摄取如何改变 Drp1 活性以及线粒体动力学。增强癌症干细胞功能以驱动体内肿瘤发生，提出了以下具体目标： 1) 描述脂肪酸摄取增强 Drp1 活性的分子机制；2) 确定 Drp1 在促进结直肠癌 CSC 功能中的功能重要性；以及 3) 定义 Drp1 的作用这项研究的结果将提供新的见解。研究线粒体动力学在连接细胞代谢途径与癌症干细胞信号传导方面的作用。高博士在信号通路调控和线粒体代谢研究方面具有丰富的经验我还将受益于我的委员会成员和州提供的额外专业知识。肯塔基大学马基癌症中心最先进的设施全面的培训计划。是根据我强有力的初步数据开发的，以适应我的研究背景和职业目标。我的导师的知识和培训，以及分子系优良的研究环境和细胞生物化学和马基癌症中心我相信这个项目将会成功。最终，这项研究将通过针对线粒体动力学来帮助开发个性化治疗方案根除癌症干细胞。