Nanoparticles for Gene Delivery

Nanocarriers are a new type of nonviral gene carriers, many of which have demonstrated a broad range of pharmacological and biological properties, such as being biodegradable in the body, stimulus‐responsive towards the surrounding environment, and an abiltiy to specifically targeting certain disease sites. By summarizing some main types of nanocarriers, this Concept considers the current status and possible future directions of the potential clinical applications of multifunctional nanocarriers, with primary attention on the combination of such properties as biodegradability, targetability, transfection ability, and stimuli sensitivity.     

Silicon-Nanotube-Mediated Intracellular Delivery Enables Ex Vivo Gene Editing

Engineered nano–bio cellular interfaces driven by vertical nanostructured materials are set to spur transformative progress in modulating cellular processes and interrogations. In particular, the intracellular delivery—a core concept in fundamental and translational biomedical research—holds great promise for developing novel cell therapies based on gene modification. This study demonstrates the development of a mechanotransfection platform comprising vertically aligned silicon nanotube (VA-SiNT) arrays for ex vivo gene editing. The internal hollow structure of SiNTs allows effective loading of various biomolecule cargoes; and SiNTs mediate delivery of those cargoes into GPE86 mouse embryonic fibroblasts without compromising their viability. Focused ion beam scanning electron microscopy (FIB-SEM) and confocal microscopy results demonstrate localized membrane invaginations and accumulation of caveolin-1 at the cell–NT interface, suggesting the presence of endocytic pits. Small-molecule inhibition of endocytosis suggests that active endocytic process plays a role in the intracellular delivery of cargo from SiNTs. SiNT-mediated siRNA intracellular delivery shows the capacity to reduce expression levels of F-actin binding protein (Triobp) and alter the cellular morphology of GPE86. Finally, the successful delivery of Cas9 ribonucleoprotein (RNP) to specifically target mouse Hprt gene is achieved. This NT-enhanced molecular delivery platform has strong potential to support gene editing technologies.     

Polymeric Materials for Gene Delivery and DNA Vaccination

Gene delivery holds great potential for the treatment of many different diseases. Vaccination with DNA holds particular promise, and may provide a solution to many technical challenges that hinder traditional vaccine systems including rapid development and production and induction of robust cell‐mediated immune responses. However, few candidate DNA vaccines have progressed past preclinical development and none have been approved for human use. This Review focuses on the recent progress and challenges facing materials design for nonviral DNA vaccine drug delivery systems. In particular, we highlight work on new polymeric materials and their effects on protective immune activation, gene delivery, and current efforts to optimize polymeric delivery systems for DNA vaccination.     

壳聚糖/基因传递系统的制备及性能

利用壳聚糖制备了不同N/P(氮/磷)物质的量比的壳聚糖/基因传递系统。通过凝胶电泳、激光粒度分析和原子力显微分析技术研究了壳聚糖分子量、N/P物质的量比对传递系统结合性能、平均粒径、Zeta-电位和颗粒形貌的影响;通过体外模拟考察了传递系统的抗消化的能力和控释行为。结果显示,壳聚糖分子量越大、N/P物质的量比越大,对基因的保护能力越强,形成的传递系统在模拟环境中越稳定,抗DNaseⅠ和溶菌酶消化的能力越强。pH值的降低使壳聚糖显示出"质子海绵"效应,pH值增大使传递系统结构松散,导致基因的释放。     

介入性心血管内药物和基因纳米控释体系

通过介入导管将药物和基因载运到血管内病灶部位,并在血管组织中长期释放。以生物可降解聚合物PLGA为基材,采用超声乳化／溶剂挥发法分别制备包载药物和基因的纳米粒子,对纳米粒子进行了表面修饰提高血管吸收性;用载反义MCP-1基因的纳米粒子转染平滑肌细胞,对平滑肌细胞基因组DNA进行PCR扩增;用兔髂总动脉和颈总动脉血管损伤模型进行灌注实验。体外释放实验表明均具有缓慢释放作用,凝胶电泳实验证明基因的结构未遭破坏。说明纳米粒子是非常理想的血管内导向定位药物和基因控释的载体。     

A Highly Emissive Conjugated Polyelectrolyte Vector for Gene Delivery and Transfection

An intrinsically fluorescent cationic polyfluorene ( CCP ) has been designed, synthesized, characterized, and examined as a plasmid DNA (pDNA) delivery vector. This material facilitates nucleic acid binding, encapsulation and efficient cellular uptake. CCP can effectively protect pDNA against nuclease degradation, which is necessary for gene carriers. Green fluorescent protein (GFP) expression experiments reveal that CCP can achieve efficient delivery and transfection of pDNA encoding GFP gene with 92% efficiency, which surpasses that of commercial transfection agents, lipofectamine 2000 (Lipo) and polyethylenimine (PEI). CCP is also highly fluorescent, with 43% quantum yield in water, and exhibits excellent photostability, which allows for real‐time tracking the location of gene delivery and transfection. These features and capabilities represent a major step toward designing and applying conjugated polymers that function in both imaging and therapeutic applications.     

Cellular Deformations Induced by Conical Silicon Nanowire Arrays Facilitate Gene Delivery

Engineered cell–nanostructured interfaces generated by vertically aligned silicon nanowire (SiNW) arrays have become a promising platform for orchestrating cell behavior, function, and fate. However, the underlying mechanism in SiNW‐mediated intracellular access and delivery is still poorly understood. This study demonstrates the development of a gene delivery platform based on conical SiNW arrays for mechanical cell transfection, assisted by centrifugal force, for both adherent and nonadherent cells in vitro. Cells form focal adhesions on SiNWs within 6 h, and maintain high viability and motility. Such a functional and dynamic cell–SiNW interface features conformational changes in the plasma membrane and in some cases the nucleus, promoting both direct penetration and endocytosis; this synergistically facilitates SiNW‐mediated delivery of nucleic acids into immortalized cell lines, and into difficult‐to‐transfect primary immune T cells without pre‐activation. Moreover, transfected cells retrieved from SiNWs retain the capacity to proliferate—crucial to future biomedical applications. The results indicate that SiNW‐mediated intracellular delivery holds great promise for developing increasingly sophisticated investigative and therapeutic tools.     

Biodegradable DNA Nanoparticles that Provide Widespread Gene Delivery in the Brain

Successful gene therapy of neurological disorders is predicated on achieving widespread and uniform transgene expression throughout the affected disease area in the brain. However, conventional gene vectors preferentially travel through low‐resistance perivascular spaces and/or are confined to the administration site even with the aid of a pressure‐driven flow provided by convection‐enhanced delivery. Biodegradable DNA nanoparticles offer a safe gene delivery platform devoid of adverse effects associated with virus‐based or synthetic nonbiodegradable systems. Using a state‐of‐the‐art biodegradable polymer, poly(β‐amino ester), colloidally stable sub‐100 nm DNA nanoparticles are engineered with a nonadhesive polyethylene glycol corona that are able to avoid the adhesive and steric hindrances imposed by the extracellular matrix. Following convection enhanced delivery, these brain‐penetrating nanoparticles are able to homogeneously distribute throughout the rodent striatum and mediate widespread and high‐level transgene expression. These nanoparticles provide a biodegradable DNA nanoparticle platform enabling uniform transgene expression patterns in vivo and hold promise for the treatment of neurological diseases.     

Photothermally Controlled Gene Delivery by Reduced Graphene Oxide–Polyethylenimine Nanocomposite

Externally stimuli‐triggered spatially and temporally controlled gene delivery can play a pivotal role in achieving targeted gene delivery with maximized therapeutic efficacy. In this study, a photothermally controlled gene delivery carrier is developed by conjugating low molecular‐weight branched polyethylenimine (BPEI) and reduced graphene oxide (rGO) via a hydrophilic polyethylene glycol (PEG) spacer. This PEG–BPEI–rGO nanocomposite forms a stable nano‐sized complex with plasmid DNA (pDNA), as confirmed by physicochemical studies. For the in vitro gene transfection study, PEG–BPEI–rGO shows a higher gene transfection efficiency without observable cytotoxicity compared to unmodified controls in PC‐3 and NIH/3T3 cells. Moreover, the PEG–BPEI–rGO nanocomposite demonstrates an enhanced gene transfection efficiency upon NIR irradiation, which is attributed to accelerated endosomal escape of polyplexes augmented by locally induced heat. The endosomal escaping effect of the nanocomposite is investigated using Bafilomycin A1, a proton sponge effect inhibitor. The developed photothermally controlled gene carrier has the potential for spatial and temporal site‐specific gene delivery.     

Self-Assemble Silk Fibroin Microcapsules for Cartilage Regeneration through Gene Delivery and Immune Regulation

Effective treatments for cartilage defects are currently lacking. Gene delivery using proper delivery systems has shown great potential in cartilage regeneration. However, the inflammatory microenvironment generated by the defected cartilage severely affects the system's delivery efficiency. Therefore, this study reports a silk fibroin microcapsule (SFM) structure based on layer-by-layer self-assembly, in which interleukin-4 (IL-4) is modified on silk by click chemistry and loaded with lysyl oxidase plasmid DNA (LOX pDNA). The silk microcapsules display good biocompatibility and the release rate of genes can be adjusted by controlling the number of self-assembled layers. Moreover, the functionalized SFMs mixed with methacrylated gelatin (GelMA) exhibit good injectability. The IL-4 on the outer layer of the SFM can regulate macrophages to polarize toward the M2 type, thereby promoting cartilage matrix repair and inhibiting inflammation. The LOX pDNA loaded inside can be effectively delivered into cells to promote extracellular matrix generation, significantly promoting cartilage regeneration. The results of this study provide a promising biomaterial for cartilage repair, and this novel silk-based microcapsule delivery system can also provide strategies for the treatment of other diseases.     

季铵盐壳聚糖及其纳米粒子作为基因载体的研究

评价N,N,N-三甲基壳聚糖盐酸盐(TMC)及其纳米粒子对质粒DNA(pDNA)的负载及保护能力,考察了其纳米复合物对人类肝癌细胞株(HepG 2细胞)的转染能力。通过复凝聚法制备TMC/pDNA纳米粒子,并采用透射电镜及原子力显微镜表征粒子形态和粒径;采用凝胶阻滞分析观察其对pDNA的保护情况;采用四噻氮唑盐(MTT)比色法测定细胞毒性;以Lipofectamine 2000转染试剂作为阳性对照,检测其对HepG 2细胞的转染活性;采用荧光倒置显微镜观察转染情况。结果表明负载pDNA的TMC纳米粒子多呈球形,粒径为100～300nm,能有效地包裹和保护基因不被DNaseⅠ酶消化;当TMC与pDNA的质量比为10∶1时,在48h达到最高的转染效率。