Targeting Oncogenic KRAS with Brush-Architectured Poly(ethylene glycol)-DNA Conjugates

使用刷状结构的聚（乙二醇）-DNA 缀合物靶向致癌 KRAS

• 批准号: 10653706
• 负责人: Ke Zhang
• 金额: $ 36.72万
• 依托单位: NORTHEASTERN UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-07-06 至 2025-06-30
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10653706
• 关键词: Acceleration; Address; Animal Cancer Model; Animal Model; Antisense Oligonucleotides; Architecture; Area Under Curve; Automobile Driving; Binding; Biodistribution; Biological Products; Blood Coagulation Disorders; Cancer Model; Cancer cell line; Cell Proliferation; Cells; Cellular biology; Characteristics; Chemicals; Chemistry; Clinic; Clinical; Clinical Research; Colorectal Cancer; DNA; Data; Deoxyribonucleases; Development; Drug Kinetics; Effectiveness; Exhibits; Gene Expression Regulation; Genes; Genetically Engineered Mouse; Goals; Half-Life; Human; Immune system; Immunologic Stimulation; Inflammation; Intracellular Transport; Investigation; Kidney; Liver; Lung Adenocarcinoma; MEKs; Malignant Neoplasms; Malignant neoplasm of lung; Malignant neoplasm of pancreas; Mediating; Messenger RNA; Methods; Modality; Modeling; Mus; Mutate; Mutation; Non-Small-Cell Lung Carcinoma; Nucleic Acids; Oligonucleotides; Oncogenes; Oncogenic; Oncoproteins; Outcome; Patients; Pharmaceutical Preparations; Pharmacologic Substance; Pharmacology; Plasma; Polyethylene Glycols; Polymers; Pre-Clinical Model; Property; Proteins; RAS Family Gene; Rattus; Refractory; Research; Ribonuclease H; Safety; Side; Signal Pathway; Signal Transduction; Structure; Therapeutic Agents; Therapeutic Intervention; Toll-like receptors; Toxic effect; Translating; Translational Repression; Translations; Tumor Suppression; Validation; Viral Oncogene; Work; Xenograft Model; Xenograft procedure; acute toxicity; alternative treatment; biological systems; cancer cell; dosage; ethylene glycol; improved; in vivo; inhibitor; insight; intravenous administration; knock-down; lung cancer cell; mouse model; mutant; nanoparticle; neoplastic cell; novel; nucleic acid-based therapeutics; patient derived xenograft model; pharmacokinetics and pharmacodynamics; pharmacologic; pre-clinical; prevent; sarcoma; side effect; single molecule; small molecule; small molecule inhibitor; stem; subcutaneous; therapeutic DNA; three dimensional cell culture; three-dimensional modeling; trafficking; treatment strategy; tumor; tumor microenvironment; uptake

Project Summary/Abstract Mutant forms of KRAS are a key driver in human tumors but remains refractory to therapeutic intervention despite over three decades of research. Clinical attempts to directly or indirectly inhibit KRAS function have both yielded unsatisfactory results. The difficulty for developing small molecule KRAS inhibitors has heightened the importance of alternative methods targeting the oncogene. One such strategy involves therapeutic nucleic acids, which make it possible to deplete target proteins that are intractable to conventional drug modalities. We have developed a novel form of nucleic acid therapeutics, termed pacDNA, that substantially enhances the antitumor activity of nucleic acid drugs by elevating in vivo stability, accelerating cellular uptake, and improving plasma pharmacokinetics and tumor accumulation, allowing a much lower dosage to be used compared to conventional methods. The pacDNA also suppresses nearly all side effects associated with traditional nucleic acid drugs by reducing unwanted nucleic acid-protein interactions. In this proposal, we aim to build upon our promising preliminary results, and gain deeper insights into the cell biology of the pacDNA with respect to cell uptake mechanism, intracellular trafficking, KRAS depletion and subsequent cell signaling, and demonstrate efficacy in KRAS-dependent non-small cell lung cancer cell lines and 3D models. In addition, we will study the primary pharmacology and antitumor activity of pacDNA in advanced preclinical lung cancer models including an orthotopic tumor model, a patient derived tumor model, and a syngeneic genetically engineered mouse model (GEMM), and perform initial in vivo safety and tolerability studies. The outcome of this project will be a safe and potent anti-KRAS agent that can be readily translated into clinical studies for non-small cell lung cancer and potentially additional cancer classes.

项目概要/摘要 KRAS 突变形式是人类肿瘤的关键驱动因素，但仍然难以治疗干预 尽管进行了三十多年的研究。直接或间接抑制 KRAS 功能的临床尝试 两者都取得了不令人满意的结果。小分子KRAS抑制剂开发难度加大 针对癌基因的替代方法的重要性。其中一种策略涉及治疗性核酸 酸，可以消除传统药物难以处理的靶蛋白。我们 开发了一种新型核酸疗法，称为 pacDNA，它大大增强了 通过提高体内稳定性、加速细胞摄取、改善核酸药物的抗肿瘤活性 血浆药代动力学和肿瘤蓄积，与相比允许使用低得多的剂量 常规方法。 pcDNA 还抑制了与传统核酸相关的几乎所有副作用 酸药物通过减少不需要的核酸-蛋白质相互作用。在本提案中，我们的目标是在我们的基础上 有希望的初步结果，并深入了解 pacDNA 的细胞生物学 摄取机制、细胞内运输、KRAS 消耗和随后的细胞信号传导，并证明 在 KRAS 依赖性非小细胞肺癌细胞系和 3D 模型中的功效。此外，我们还将研究 pacDNA 在晚期临床前肺癌模型中的主要药理学和抗肿瘤活性，包括 原位肿瘤模型、患者来源的肿瘤模型和同基因基因工程小鼠 模型（GEMM），并进行初步的体内安全性和耐受性研究。该项目的成果将是 安全有效的抗 KRAS 药物，可轻松转化为非小细胞肺的临床研究 癌症和潜在的其他癌症类别。

项目成果

A Long-Circulating Vector for Aptamers Based upon Polyphosphodiester-Backboned Molecular Brushes.

• DOI: 10.1002/anie.202204576
• 发表时间: 2022-10-10
• 期刊: ANGEWANDTE CHEMIE-INTERNATIONAL EDITION
• 影响因子: 16.6
• 作者: Wang, Yuyan;Wang, Dali;Lin, Jiachen;Lyu, Zidi;Chen, Peiru;Sun, Tingyu;Xue, Chenyang;Mojtabavi, Mehrnaz;Vedadghavami, Armin;Zhang, Zheyu;Wang, Ruimeng;Zhang, Lei;Park, Christopher;Heo, Gyu Seong;Liu, Yongjian;Dong, Sijia;Zhang, Ke
• 通讯作者: Zhang, Ke

Targeting oncogenic KRAS with molecular brush-conjugated antisense oligonucleotides.

• DOI: 10.1073/pnas.2113180119
• 发表时间: 2022-07-19
• 期刊: Proceedings of the National Academy of Sciences of the United States of America
• 影响因子: 11.1

A mechanistic study on the cellular uptake, intracellular trafficking, and antisense gene regulation of bottlebrush polymer-conjugated oligonucleotides.

• DOI: 10.1039/d2cb00149g
• 发表时间: 2023-02-08
• 期刊: RSC CHEMICAL BIOLOGY
• 影响因子: 4.1
• 作者: Zhang, Lei;Wang, Yuyan;Chen, Peiru;Wang, Dali;Zhang, Zheyu;Wang, Ruimeng;Kang, Xi;Fang, Yang;Lu, Hao;Cai, Jiansong;Ren, Mengqi;Dong, Sijia;Zhang, Ke;Sun, Tingyu
• 通讯作者: Sun, Tingyu

Self-Assembled DNA-PEG Bottlebrushes Enhance Antisense Activity and Pharmacokinetics of Oligonucleotides.

• DOI: 10.1021/acsami.0c13995
• 发表时间: 2020-10-14
• 期刊: ACS applied materials & interfaces
• 影响因子: 9.5
• 作者: Wang Y;Wang D;Jia F;Miller A;Tan X;Chen P;Zhang L;Lu H;Fang Y;Kang X;Cai J;Ren M;Zhang K
• 通讯作者: Zhang K

Exploring the Structural Diversity of DNA Bottlebrush Polymers Using an Oligonucleotide Macromonomer Approach.

• DOI: 10.1021/acs.macromol.1c02624
• 发表时间: 2022-03-22
• 期刊: MACROMOLECULES
• 影响因子: 5.5
• 作者: Lu, Hao;Cai, Jiansong;Fang, Yang;Ren, Mengqi;Tan, Xuyu;Jia, Fei;Wang, Dali;Zhang, Ke
• 通讯作者: Zhang, Ke