Compacted DNA Nanoparticles for Ocular Therapy

用于眼部治疗的压缩 DNA 纳米颗粒

• 批准号: 7353945
• 负责人: Muna I. Naash
• 金额: $ 36.63万
• 依托单位: UNIVERSITY OF OKLAHOMA HLTH SCIENCES CTR
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7353945
• 关键词: Acute; Address; Adult; Biological; Biomedical Engineering; CMV promoter; Caliber; Cell Nucleus; Cell membrane; Cells; Charge; Chemistry; Chickens; Circular DNA; Clinical; Complementary DNA; DNA; Defect; Development; Disease; Disease model; Drops; Drug Formulations; Effectiveness; Endocytosis; Engineering; Epithelial Cells; Eye diseases; Gene Delivery; Gene Expression; Gene Transduction Agent; Gene Transfer; Gene Transfer Techniques; Generations; Genes; Goals; Human; Immune response; In Vitro; Inflammation; Injection of therapeutic agent; Interphase Cell; Knock-out; Lead; Leber' s amaurosis; Left; Longevity; Lysine; Measures; Mitotic; Modeling; Molecular; Mus; Nanotechnology; Non-Viral Vector; Nuclear Envelope; Opsin; Pattern; Pharmacologic Substance; Phenotype; Photoreceptors; Physical condensation; Physics; Plasmid Cloning Vector; Plasmids; Play; Polyethylene Glycols; Polymers; RPE65 protein; Retina; Retinal; Retinal Degeneration; Retinal Photoreceptors; Role; Safety; Specificity; Standards of Weights and Measures; Stargardt' s disease; Structure of retinal pigment epithelium; Technology; Testing; Therapeutic; Tissues; Toxic effect; Transduction Gene; Universities; Vertebral column; Viral Vector; Vitelliform macular dystrophy; Week; Wild Type Mouse; Work; base; beta Actin; clinical application; computer science; day; design; early onset; gene delivery system; gene therapy; human TFRC protein; improved; in vivo; nanoparticle; non-viral gene delivery; non-viral gene therapy; novel; nucleolin; particle; plasmid DNA; postnatal; pre-clinical; programs; promoter; radius bone structure; ranpirnase; receptor; retinal progenitor cell; retinal rods; retinol binding protein 3, interstitial, human; size; subretinal injection; trafficking; transgene expression; uptake; vector

DESCRIPTION (provided by applicant): The goal of this program is to advance the current compacted DNA nanoparticle based gene therapy technology to enable efficient and long-lasting gene delivery to dividing and non-dividing cells. The program will merge experts with molecular bioengineering, physics, chemistry, and computer science backgrounds at OUHSC, Stanford University and Copernicus Therapeutics, Inc, to accelerate essential preclinical steps for effective non-viral gene therapy. The plan is to engineer DNA vectors with efficient uptake and transport through the plasma membrane that can provide persistent transgene expression without toxicity. This technology can unimolecularly compact DNA with lysine polymers substituted with polyethylene glycol (PEG) into neutral charge nanoparticles with radii of less than 18 nm. These particles can penetrate the cell membrane via nucleolin receptor associated endocytosis and cross the nuclear membrane pore to the nucleus within 15 minutes. The DNA condensation formulation will compact either linear or circular DNA enabling us to eliminate plasmid backbone sequences known to play a significant role in inhibiting gene expression. The potential scientific and clinical benefits of these enhancements are substantial. While our ultimate aim is to use gene transfer to treat human ocular disease, we plan to address basic biological questions that will be important for rational design of vectors for gene therapy applications. Given the dangers inherent in the use of viral vectors, our strategy will enable us to access the favorable aspects of viral vectors while providing the safety and pharmaceutical qualities inherent in non-viral gene delivery systems. Towards this goal, we are working on developing new non-viral vectors for gene transfer to ocular tissues and establishing the cellular and molecular mechanisms involved in gene transduction. Three aims are proposed to optimize, mechanistically assess, and test our nanoparticle technology. Aim 1 will generate and compare the efficiency and longevity of EGFP expression between standard circular plasmid vectors and linear or minicircle constructs lacking the vector backbone sequence. The aim will also combine two novel gene therapy technologies, compacted DNA nanoparticles and pEPI-1 vector containing S/MAR sequence to develop an efficient and persistent gene transfer strategy in vivo. The effect of different vector sequences on promoter specificity will be assessed with two commonly used promoters in retinal gene therapy trials. To direct specific rod photoreceptor expression we will use the mouse opsin promoter (MOP) and to direct expression in the retinal pigment epithelium, we will use the vitelliform macular dystrophy 2 (VMD2) promoter. The constructs will be compacted and subretinally injected into WT mice during development at postnatal day 5 (P5) and in adults (P30). Injections at P5 will evaluate the efficacy of the nanoparticles in transfecting dividing retinal progenitor cells, and results will be relevant for the treatment of early onset eye diseases. Injections in adults will evaluate the efficacy of the nanoparticles in post-mitotic cells which is an appropriate experimental paradigm for treating late onset ocular diseases. Aim 2 will assess potential barriers to clinical vector application by evaluating particles uptake, trafficking, mechanisms of vector silencing, and in vivo safety. Aim 3 will test the efficacy of the vectors in rescuing the phenotypes in two well-known disease models: RPE65-/- (Leber's congenital amaurosis) and ABCR-/- (Stargardt's macular dystrophy).

描述（由申请人提供）：这个项目的目标是推进当前基于压缩DNA纳米颗粒的基因治疗技术，使基因能够有效和持久地传递到分裂和非分裂细胞。该项目将整合OUHSC、斯坦福大学和哥白尼治疗公司具有分子生物工程、物理、化学和计算机科学背景的专家，以加快有效的非病毒基因治疗的基本临床前步骤。该计划是设计DNA载体，使其能够有效地通过质膜吸收和运输，从而提供持久的转基因表达而没有毒性。该技术可以将赖氨酸聚合物与聚乙二醇（PEG）取代的DNA单分子紧密结合成半径小于18纳米的中性电荷纳米颗粒。这些颗粒可以通过核蛋白受体相关的内吞作用穿透细胞膜，并在15分钟内穿过核膜孔到达细胞核。DNA浓缩配方将压缩线性或圆形DNA，使我们能够消除已知在抑制基因表达中起重要作用的质粒骨干序列。这些增强的潜在科学和临床益处是巨大的。虽然我们的最终目标是利用基因转移治疗人类眼部疾病，但我们计划解决基本的生物学问题，这些问题对于基因治疗应用的载体的合理设计非常重要。鉴于使用病毒载体的固有危险，我们的策略将使我们能够获得病毒载体的有利方面，同时提供非病毒基因传递系统固有的安全性和药物质量。为了实现这一目标，我们正在开发新的非病毒载体，用于基因转移到眼组织，并建立基因转导的细胞和分子机制。提出了优化、机械评估和测试纳米颗粒技术的三个目标。目的1将生成并比较标准圆形质粒载体与缺乏载体骨干序列的线性或小圆形质粒载体之间EGFP表达的效率和寿命。该研究还将结合两种新的基因治疗技术，即压缩DNA纳米颗粒和含有S/MAR序列的pEPI-1载体，开发一种高效、持久的体内基因转移策略。不同载体序列对启动子特异性的影响将以视网膜基因治疗试验中常用的两种启动子进行评估。为了指导特异性杆状光感受器的表达，我们将使用小鼠视蛋白启动子（MOP），而为了指导视网膜色素上皮的表达，我们将使用卵黄样黄斑营养不良2 （VMD2）启动子。这些构建体将被压实，并在出生后第5天（P5）和成年小鼠（P30）的发育期间通过视网膜下注射到WT小鼠体内。注射P5将评估纳米颗粒转染分裂的视网膜祖细胞的效果，结果将与早发性眼病的治疗相关。成人注射将评估纳米颗粒在有丝分裂后细胞中的疗效，这是治疗晚发型眼部疾病的适当实验范例。目标2将通过评估颗粒摄取、运输、媒介沉默机制和体内安全性来评估临床媒介应用的潜在障碍。目的3将测试载体在拯救两种著名疾病模型(RPE65-/- （Leber's congenital amaurosis)和ABCR-/- (Stargardt's macular dystrophy)）中表型的功效。