Polyplex-embedding in polyelectrolyte multilayers for gene delivery

In this work, incorporation of plasmid DNA, pre-complexed with PEI, into polyelectrolyte multilayers has been studied to further develop platforms for local gene delivery. Polyplex embedding in synthetic and naturally degradable architectures was efficient for transfection of human hepato-cellular carcinoma cells.     

Polymer gene delivery vectors encapsulated in thermally sensitive bioreducible shell

Stable, nanosized polyelectrolyte complexes between rationally designed thermally sensitive block copolymers and plasmid DNA (polyplexes) were formed and their in vitro transfection efficiency was tested. The polyplexes were further stabilized through encapsulation into a biodegradable polymer shell. Although reduced as compared to that of the corresponding polyplexes, the encapsulated systems still show acceptable transfection efficiency. That opens the possibility to tune the balance between the safe transport and efficient delivery of DNA into the cells.     

核酸载体lipopolyplex 的制备及细胞毒性研究

目的：为降低聚阳离子基因载体polyplex 的正电荷和毒性,在其表面构建中性磷脂膜制备lipopolyplex,并测定lipopolyplex 对小鼠结肠癌细胞CT26 和人乳腺癌细胞MCF-7 的细胞毒性。方法：采用PEI25KDa与DNA 复合制备polyplex,在polyplex 体系 中加入中性脂质体和SADGE 制备lipopolyplex。采用琼脂糖凝胶电泳考察lipopolyplex 对质粒DNA的包裹能力;采用激光粒度 仪和zeta 电位分析仪测定lipopolyplex 的粒径与zeta 电位;采用透射电镜观察lipopolyplex 的形态;采用CCK-8 试剂盒考察 lipopolyplex 对CT26和MCF-7 的细胞毒性。结果：琼脂糖凝胶电泳显示lipopolyplex 可以完全包裹质粒DNA;lipopolyplex 的粒 径在200 nm 左右,电位在-20 mV 左右;透射电镜下为较为规则的球状颗粒;lipopolyplex 在CT26 和MCF-7 细胞中的毒性明显 低于聚阳离子基因载体polyplex。结论：在polyplex 表面成功构建中性磷脂膜制备的lipopolyplex,可以完全的包裹DNA 并且细 胞毒性明显低于polyplex,在基因输送载体领域具有潜在应用价值。     

PEGylation significantly affects cellular uptake and intracellular trafficking of non-viral gene delivery particles

In vitro studies of non-viral gene delivery vectors are typically not performed at physiological conditions, and thus may not provide meaningful results for in vivo investigations. We determine if polycation-plasmid DNA complexes (polyplexes) exploited for in vitro studies behave similarly to variants more applicable to in vivo use by examining their cellular uptake and trafficking. Branched polyethylenimine (25 kDa) or a linear beta-cyclodextrin-containing polymer are each used to formulate polyplexes, which can be PEGylated (PEG: poly(ethylene glycol)) to create particles stable in physiological salt concentrations. Particle size, cellular uptake, intracellular trafficking, and reporter gene expression are reported for polyplexes and for their PEGylated variants. PEGylation confers salt stability to particles but produced a reduction in luciferase expression. Examination of in vitro particle internalization by transmission electron microscopy shows unmodified polyplexes entering cells as large aggregates while PEGylated particles remain small and discrete, both outside and within cells. Unmodified and PEGylated particles enter cells through the endocytic pathway and accumulate in a perinuclear region. Immunolabeling reveals unpackaged exogenous DNA in the cytoplasm and nuclei. It appears all particle types traffic towards the nucleus within vesicles and undergo degradation in vesicles and/or cytoplasm, and eventually some exogenous DNA enters the nucleus, where it is transcribed. In comparing polyplexes and their PEGylated variants, significant differences in particle morphology, cellular uptake, and resultant expression suggest that in vitro studies should be conducted with particles prepared for physiological conditions if the results are to be relevant to in vivo performance.     

Amine terminated G-6 PAMAM dendrimer and its interaction with DNA probed by Hoechst 33258

Fluorescence characteristics of Hoechst 33258 bound to G-6 dendrimer, to the DNA-G-6 dendrimer complex, and to DNA were compared with that in an aqueous solution. The spectral properties including fluorescence emission spectrum, accessibility of anionic quencher, as well as the fluorescence decay time of the Hoechst 33258 are different for all three conditions, indicating that the environments in these conditions are different. Close analysis of the fluorescence properties led us to suggest that Hoechst 33258 located at or near the contact area of the dendrimer and DNA in the DNA-G-6 complex. In the complex, in the absence of Hoechst 33258, the shape of the circular dichroism in the DNA absorption region remained, indicating that DNA is in B form in the complex. On the other hand, the magnitude of linear dichroism (LD) decreased upon DNA-G-6 dendrimer complex formation. The decrease in LD magnitude reflects the shortening of the DNA contour length, which is expected from the fact that a large part of linear DNA is required to wrap the surface of G-6 dendrimer.