交联型聚乙烯亚胺智能基因载体的制备及PEG化影响

使用胱胺双丙烯酰胺(CBA)对低分子量聚乙烯亚胺(PEI)进行交联反应制备智能降解型聚阳离子基因载体.通过与聚乙二醇(PEG)反应得到不同程度PEG化的聚阳离子载体.利用核磁、黏度测试、粒度仪、zeta电位仪和凝胶电泳对聚阳离子载体及其与DNA的复合物进行了表征.研究表明随着PEG含量的增加,聚阳离子载体/DNA复合物颗粒粒径变小、表面正电荷降低,PEG具有明显的屏蔽作用,但过多的PEG也使载体与DNA复合能力下降.通过MTT细胞毒性测试和荧光素酶质粒转染实验得出,含二硫键的交联型阳离子聚合物在测试范围内显示了非常低的细胞毒性,最佳转染效率是PEI25k的4倍,PEG化后其细胞毒性得到进一步改善,转染效率却明显降低.     

六氯环三磷腈交联寡聚乙烯亚胺的制备及基因载体应用

将六氯环三磷腈与分子量为600的超支化寡聚乙烯亚胺在干燥氯仿中反应,合成了可降解的交联型聚合物.利用1HNMR表征了聚合物的结构,并用GPC测试了聚合物的分子量.研究了其作为非病毒基因载体的性能,聚合物载体与DNA形成的复合物颗粒粒径为150nm,Zeta电位为30～40mV,凝胶阻滞电泳显示聚合物/DNA在质量比为0.4时能够将DNA完全阻滞.体外转染实验结果表明,载体对HeLa细胞的最佳转染效率为PEI-25K的3倍;聚合物浓度为20μg/mL时,细胞存活率仍然大于80%,材料的细胞毒性低,生物相容性好,具有良好的生物医学应用前景.     

聚苯丙氨酸修饰低分子量聚乙烯亚胺制备高效基因载体

分别制备了以支化小分子量聚乙烯亚胺(PEI-1.8k)为引发剂,引发苯丙氨酸-NCA开环聚合得到聚乙烯亚胺-聚苯丙氨酸(PEI1.8k-g-PPhe)以及聚乙烯亚胺接枝苯丙氨酸单体(PEI1.8k-g-Phe)的系列基因载体材料.利用核磁、粒度、zeta电位仪、荧光光度计、流式细胞仪以及激光共聚焦显微镜对PEI1.8k-g-PPhe,PEI1.8k-g-Phe以及PEI1.8k-g-PPhe/DNA和PEI1.8k-g-Phe/DNA复合物颗粒进行了系统的表征.研究结果表明,最佳转染条件下,PEI1.8k-g-PPhe10/DNA复合物颗粒的粒径约为150 nm,表面电位约为16 m V.在人源宫颈癌(He La)和人源乳腺癌(MCF-7)2种细胞系中均具有较高的基因转染效率,且最佳转染效率可达到PEI-25k的12倍.MTT细胞毒性实验分别比较了PEI1.8k-g-PPhe和PEI1.8k-g-Phe对He La细胞毒性的大小.从实验结果可见,苯丙氨酸引入的方式及数量决定着其细胞毒性的大小.PEI1.8k-g-PPhe和PEI1.8k-g-Phe都具有较低的细胞毒性(材料在较高浓度1 mg/m L时的细胞存活率大于70%).内吞实验结果表明,PEI1.8k-g-PPhe由于接入了具有规则聚合链的聚苯丙氨酸,而易于被He La细胞内吞.PEI1.8k-g-PPhe10/DNA复合物颗粒相比于PEI-25k/DNA,PEI-1.8k/DNA和PEI1.8k-g-PPhe/DNA具有更高的细胞内吞效率.     

ATRP法制备聚(甲基丙烯酸氨乙酯-co-甲基丙烯酸N,N-二乙基氨乙基酯)基因载体

为得到低毒、高效的聚阳离子基因载体,以甲基丙烯酸氨乙酯(AMA)和甲基丙烯酸N,N-二乙基氨乙基酯(DEAEMA)为单体,以2-溴代异丁酸乙酯(EBIB)为引发剂,通过原子转移自由基聚合(ATRP)制备了两种聚(甲基丙烯酸氨乙酯-co-甲基丙烯酸N,N-二乙基氨乙基酯)阳离子无规共聚物(P(AMA-co-DEAEMA),简称P).琼脂糖凝胶电泳实验结果表明聚合物P作为阳离子载体可以有效地络合DNA,通过粒径仪测定的复合物粒子的尺寸在400 ～ 600 nm之间.扫描电镜观察的P/DNA复合物形貌是分散均匀的球形颗粒.以25kDa PEI为阳性参照,利用MTT比色法考察了聚合物P对HEK293T细胞的毒性.结果表明,聚合物P的细胞毒性低于25 kDa PEI的细胞毒性.以25 kDa PEI和裸质粒DNA作为参照,我们进一步考察了聚合物P与DNA形成的复合物在HEK293T细胞中的转染效率.结果表明P/DNA复合物在HEK293T细胞中的转染效率远远高于裸质粒DNA的转染效率,并且接近于25 kDa PEI/DNA复合物的转染效率.     

基于门舒特金反应的酶触发自降解高分子载体及其在基因输送中的应用

用邻位苄基溴与双胺进行门舒特金反应,合成了2种线性的季铵盐阳离子聚合物.其中,含有酚基酯键的阳离子聚合物,一旦进入细胞后,可以在细胞内的酯酶催化下快速水解,使得聚合物自降解断裂为不带电的非季铵盐小分子,从而快速释放DNA,最终达到提高转染效率的目的.通过对复合物纳米颗粒的粒径和电势测定,证明了这2种阳离子聚合物都能够有效地结合DNA形成表面带正电的复合物纳米颗粒.凝胶阻滞电泳实验表明,所合成的阳离子聚合物都能稳定地包裹DNA.而在酯酶条件下,含有酚基酯键的阳离子聚合物可以发生降解,使得纳米复合物释放出DNA.同时,含有酚基酯键的阳离子聚合物由于其独特的可降解性,相比于PEI,降低了细胞毒性.在体外细胞转染实验中,2种阳离子聚合物都有较好的转染效果.其中酯酶响应的载体在高N/P下依然表现出较高的转染效率,说明该阳离子载体能够在细胞内有效降解并释放出DNA.     

微流控可控分步组装制备透明质酸/聚乙烯亚胺/DNA纳米复合物

阳离子聚合物/DNA形成的复合物纳米颗粒呈正电性,因此表面必须遮盖一层电中性或负电性的聚合物才能在体内应用,但如何控制遮蔽层在复合物纳米颗粒上组装,形成结构可控、尺寸均一的基因输送系统是关键.本文以基因输送系统中常见的透明质酸(HA)/聚乙烯亚胺(PEI)/DNA系统为例,探索了利用微流控芯片进行可控分步的层层自组装,制备尺寸大小均一、表面电势为负的HA/PEI/DNA纳米复合物的方法.将PEI与DNA通过第一个微流控芯片自组装得到PEI/DNA纳米复合物,该复合物颗粒在第二个微流控芯片内与HA再次组装得到HA/PEI/DNA纳米复合物.考察了微流控芯片管道的尺寸、溶液流速及流速比R、PEI与DNA氮磷比(N:P)、HA与DNA质量比(HA:DNA)等参数与所形成的纳米复合物的尺寸、均一性及表面电势的关系,并与涡旋振荡法制备的复合物进行比较.结果表明,传统的涡旋振荡法制备的HA/PEI/DNA纳米复合物尺寸偏大(340～490 nm)、均一度低(PDI,0.506～0.863);而用微流控法制备的复合物尺寸较小(190 nm)、分布更为均一(PDI=0.316).     

半乳糖胺修饰阳离子型刷形嵌段共聚物的合成与表征

利用两步原子转移自由基聚合（ATRP）和聚合物后修饰反应,制备半乳糖胺修饰的阳离子型刷形嵌段共聚物P（PEGMEMA-co-PEGMA_-Gal）-b-PDMAEMA. 首先,通过ATRP法引发单体聚乙二醇单甲醚甲基丙烯酸酯（PEGMEMA）和聚乙二醇甲基丙烯酸酯（PEGMA）聚合,得到末端含氯基的无规共聚物P（PEGMEMA-co-PEGMA）;再利用其作为大分子引发剂,引发水溶性单体甲基丙烯酸-2-（N,N-二甲氨基）乙酯（DMAEMA）进行ATRP反应,获得三组分两嵌段刷形共聚物P（PEGMEMA-co-PEGMA）-b-PDMAEMA;最后,利用PEGMA结构单元中的侧链羟基,经聚合物反应,键合具有肝靶向功能的半乳糖分子（Gal）,成功获得P（PEGMEMA-co-PEGMA_-Gal）-b-PDMAEMA. 其中,PDMAEMA侧基的二甲氨基[-N（CH₃）₂]在中性和弱酸性介质中可发生质子化,形成聚阳离子链段,能够缩合DNA,用作基因载体. 通过核磁共振氢谱（¹H NMR）、红外光谱（FT-IR）和凝胶渗透色谱（GPC）,对聚合物的化学结构、分子量及分子量分布进行表征. 利用凝胶阻滞电泳研究阳离子型嵌段共聚物与DNA的结合能力、利用动态激光光散射仪（DLS）测试聚阳离子/DNA复合物的表面zeta电位值、粒径及粒径分布. 通过细胞毒性试验（MTT法）表征载体的生物相容性,并分别研究复合物对宫颈癌（HeLa）细胞和肝癌（HepG2）细胞的转染能力. 实验结果表明,这种半乳糖胺修饰的阳离子型刷形共聚物具有较低的细胞毒性,在肝靶向基因输送中具有潜在的应用.     

聚谷氨酸为骨架的梳状基因载体的合成及生物学性能评价

以聚谷氨酸为骨架, 用低分子量聚乙烯亚胺胺解聚谷氨酸苄酯, 得到聚谷氨酸-g-聚乙烯亚胺, 用异佛尔酮二异氰酸酯将聚乙二醇单甲醚偶联到聚谷氨酸-g-聚乙烯亚胺上, 合成了梳状聚阳离子基因载体聚谷氨酸-g-(聚乙烯亚胺-b-聚乙二醇). 利用核磁共振氢谱、 激光粒度分析仪、 Zeta电位仪和凝胶电泳对聚阳离子载体及其与质粒脱氧核糖核酸(pDNA)形成的复合物进行了表征. 通过噻唑蓝(MTT)细胞毒性测试、 绿色荧光蛋白质粒pEGFP-C1及荧光素酶质粒pGL3体外转染实验考察了载体的细胞毒性及基因转染效率. 结果表明, 当聚乙烯亚胺中N原子和DNA中P原子的摩尔比(N/P)大于5时, 载体能很好地包裹DNA, 载体与DNA形成的复合物粒径约为130 nm, Zeta电位约为28 mV; 通过MTT实验和体外质粒转染实验显示出载体在测量范围内具有极低的细胞毒性和较高的转染效率.     

PEI基因载体靶向遮蔽体系的制备和表征

将RGD短肽接枝到聚谷氨酸(PGA)上,制备了一种靶向性的基因载体遮蔽材料PGA-RGD.通过凝胶电泳实验及体外转染实验证明得出RGD的引入增加了载体材料与细胞表面受体的特异性作用,在载体表面正电荷得到遮蔽的同时,转染效率还得到了一定程度的增加.同时,对转染了48h的三元复合物进行MTT细胞毒性测试表明,PGA遮蔽的基因载体体系(PGA/PEI/DNA)和PGA-RGD遮蔽的基因载体体系(PGA-RGD/PEI/DNA)的细胞毒性均低于PEI/DNA复合物体系.本文开发的基因载体改性方法不仅可以对复合物颗粒表面的正电荷进行遮蔽,从而降低复合物体系对非目标组织的非特性异作用;同时引入的RGD靶向短肽还可以提高载体的靶向性,这一改性策略对推动阳离子聚合物基因载体在体内的应用具有重要意义.     

聚(3,4-乙撑二氧噻吩)/木质素磺酸导电复合物的结构与性能

3,4-乙撑二氧噻吩(EDOT)以木质素磺酸(LS)作载体,通过化学氧化法聚合形成了聚(3,4-乙撑二氧噻吩)/木质素磺酸(PEDOT/LS)导电复合物.该导电复合物的结构与性能分别采用紫外可见分光光度计、红外光谱仪、zeta电位及粒度分析仪、原子力显微镜、X-射线光电子能谱仪、X-射线衍射仪、四探针测试仪、电泳仪,以及表面电阻仪来表征.结果表明,EDOT能在LS水溶液中氧化聚合,得到水分散性PEDOT/LS导电颗粒.该颗粒是一种聚电解质复合物,等量电荷配比的PEDOT/LS位于内核而富余的亲水性LS包在外层.LS与PEDOT两者之间存在较强的作用力,无法通过电泳分开.X-射线衍射仪结果表明该复合物是无定型的.当LS与EDOT单体质量比从0.7∶1升高至3.0∶1时,复合物的粒径从673 nm降低至348 nm,涂膜表面变得均匀,同时表面电阻从1.9 kΩ/sq上升至87.2 kΩ/sq.用PEDOT/LS配置得到的抗静电剂,可以使玻璃片表面电阻从1012Ω/sq减小至107Ω/sq.     

A facile approach to construct hyaluronic acid shielding polyplexes with improved stability and reduced cytotoxicity

A facile approach for polymer gene carriers was used to construct hyaluronic acid (HA) shielding polyplexes due to the electrostatic interaction. By adding HA to PEI/DNA complexes, the ξ-potential of ternary polyplexes was changed from positive to negative. Spherical particles with diameter about 250nm were observed. Ethidium bromide exclusion assay indicated that the electrostatic complexation was loosened after addition of HA. However, DNA disassembly did not occur. The proper reason was that the intensity of negative charges was not strong enough to release DNA from the complexes in our experiment. The stability of PEI/DNA/HA polyplexes in physiological condition was improved and the cytotoxicity was reduced. Comparing with PEI/DNA polyplexes, the uptake and transfection efficiency of HA shielding polyplexes was lower for HEK293T cells probably due to the reduced adsorptive endocytosis, whereas it was higher for HepG2 cells due to HA receptor mediated endocytosis. This facile approach to constructing HA shielding polyplexes might have great potential application in non-viral gene delivery research and tumor therapy.     

Bioreducible crosslinked low molecular weight branched PEI-PBLG as an efficient gene carrier

Low molecular weight polyethylenimine-poly(gamma-benzyl L-glutamate) (PEI-PBLG) was crosslinked by N,N′-cystamine-bisacrylamide (CBA) to get the polymer named as CBA-PEI-PBLG (CPP). CPP not only inherits PEI-PBLG’s amphiphilic advantages, but also possesses reducible properties. CPP can complex with DNA to form nanoparticles. CPP/DNA complex particles were characterized by particle size and zeta potential analysis. The result showed that the complex particles have suitable size and surface charges for gene delivery. And gel retardation assay also prove CBA-PEI-PBLG has proper condensing ability for DNA. CPP has good reducible property, and also has good biocompatibility because of introducing PBLG segment. The cytotoxicity of CPP was evaluated using MTT assay, and the results showed CPP has lower cytotoxicity compared with PEI 25 K. The transfection properties were characterized in different cells by using plasmid DNA as a reporter. CPP showed higher transfection efficiencies and lower cytotoxicity in HeLa cells. This was attributed to bioreducible and biocompatibility properties of the CPP. These results suggested that CPP is a promising low-toxic, highly effective non-viral gene carrier.     

High-molecular-weight polyethyleneimine conjuncted pluronic for gene transfer agents

In order to enhance the gene delivery efficiency and decrease cytotoxicity of polyplexes, copolymers consisting of branched polyethyleneimine (PEI) 25 kDa grafted with Pluronic (F127, F68, P105) were successfully synthesized using a simple two-step procedure. The copolymers were tested for cytotoxicity and DNA condensation and complexation properties. Their polyplexes with plasmid DNA were characterized in terms of DNA size and surface charge and transfection efficiency. The complex sizes were below 300 nm, which implicated their potential for intracellular delivery. The Pluronic-g-PEI exhibited better condensation and complexation properties than PEI 25 kDa. The cytotoxicity of PEI was strongly reduced after copolymerization. The Pluronic-g-PEI showed lower cytotoxicity in three different cell lines (Hela, MCF-7, and HepG2) than PEI 25 kDa. pGL3-lus was used as a reporter gene, and the transfection efficiency was in vitro measured in HeLa cells. Compared with unmodified PEI 25 kDa Pluronic-g-PEI showed much higher transfection efficiency. These results demonstrate that polyplexes prepared using a combined strategy of surface crosslinking and grafted with Pluronic seem to provide promising properties as stable, high transfection efficiency vectors.     

阳离子基因载体的pH敏感遮蔽体系的制备及表征

合成了一种pH敏感的遮蔽体系-谷氨酸苄酯/谷氨酸共聚物(PBLG-co-PGA), 用于对DNA/阳离子基因载体复合物颗粒表面正电荷的遮蔽, 以提高其在体内的稳定性. 研究表明, PBLG-co-PGA (PGA(x), x为PGA占共聚物中摩尔百分数)具有pH敏感性. 并以pH敏感点接近生理pH值的PGA(60)为遮蔽体系进行研究. PGA(60)能够对DNA/PEI(1:1)复合物颗粒表面正电荷进行有效遮蔽. 凝胶阻滞电泳显示, 用PGA(60)对DNA/PEI复合物进行不同比例遮蔽, 没有发生与DNA的链交换作用. MTT细胞毒性测试表明, PGA(60)和三元复合物DNA/PEI/PGA(60) 在测试范围内几乎没有细胞毒性. 荧光素酶转染实验表明, 部分遮蔽后转染效率有所提高; 用PGA(60)对DNA/PEI复合物完全遮蔽为负电后, 由于同细胞表面的电荷排斥作用, 三元复合物不易被细胞内吞, 导致不发生细胞转染. 因其合适的pH响应性, PGA(60)将可能成为一种能随pH值的变化, 实现对聚阳离子基因载体进行电荷遮蔽/智能释放的遮蔽材料.     

细胞核靶向聚乙烯亚胺-地塞米松偶联物的制备及作为基因载体的应用

采用地塞米松(Dex)和低分子量聚乙烯亚胺(PEI)经酰胺化反应, 合成了一种新型靶向基因载体PEI-Dex偶联物. 研究结果表明, PEI-Dex可结合DNA形成复合物, 在最佳制备条件下(N/P=12), PEI-Dex/DNA复合物粒径为(162±1.90) nm, 电位为(12.8±0.11) mV, 适用于基因转染. PEI-Dex的细胞毒性较低, 可促进复合物的细胞核转运, 从而显著提高转染效率.     

Hydrogen bonds in polycation improve the gene delivery efficiency in the serum-containing environment

Cationic polymers with high charge density could effectively condense the DNA and achieve gene transfection; however, it often brings non-negligible cytotoxicity. Notably, the high charge density gene vector fails in the serum environment, limiting further application in vivo. In this paper, an efficient and reliable non-viral gene vector of poly (amidoamine) (PAA) was designed by introducing diacryolyl-2,6-diaminopyridine (DADAP) onto the PAA backbone through Michael-addition polymerization, which provides high transfection efficiency in a serum-containing environment. Diacryolyl-2,6-diaminopyridine and cationic parts provided multiple interactions between gene vectors and DNA, including hydrogen bond and electrostatic interactions. The introduction of hydrogen bonding can effectively reduce the charge density of polyplexes without reducing the DNA condensing ability, incorporating the diaminopyridine group and cationic part in PAA chains successfully consolidated cellular uptake, endosome destabilization, and transfection efficiency for the PAA/DNA complexes with low cytotoxicity. The constructed vector with multiple interactions presented 6 times higher transfection efficiency in serum-free and 9 times in serum-containing environment than that of branched polyethyleneimine (PEI 25K) in 293T cells in vitro. Therefore, introducing the hydrogen band to form low charge density polyplexes with high transfection efficiency and low cytotoxicity has a great potential in gene delivery.     

侧链含咪唑取代基聚(L-天冬酰胺)高效基因载体研究

通过氨基引发聚丁二酰亚胺( PSI)开环反应,制备了系列侧链含氨乙基和咪唑丙基的聚(L-天冬酰胺)共聚物(P1 ～ P5).该系列聚合物不仅具有极低的细胞毒性,而且随侧链中咪唑取代基含量的增加,聚合物在pH 5 ～8范围内缓冲能力显著提高.通过凝胶电泳、粒径和电位分析等研究了聚合物与质粒DNA的相互作用.结果表明,所有...     

阳离子聚合物基因转染载体的研究进展

安全有效的基因载体是实现基因治疗的必要条件,由于阳离子聚合物易于合成和改性,无免疫原性,可以方便地与DNA形成紧密的超分子复合物,保护DNA免受核酸酶的降解,并促进其进入细胞,从而成为非病毒基因载体中的一个重要类型;但阳离子聚合物基因载体,对细胞具有电荷相关的毒性,转染效率低于病毒载体,这成为限制其进入临床使用的瓶颈.本文从提高阳离子聚合物作为基因载体时的转染效率及降低其毒性方面综述了阳离子聚合物基因载体的研究进展,归纳了改善阳离子聚合物基因载体转染特性的八种方法,预测了阳离子聚合物基因载体的发展前景.     

Diol glycidyl ether-bridged cyclens: preparation and their applications in gene delivery

Polymeric 1,4,7,10-tetraazacyclododecanes (cyclens) using diol glycidyl ether with different chain length as bridges (5a-e) were designed and synthesized from various diols, 1,7-diprotected cyclen and epichlorohydrin. The molecular weights of the title polymers were measured by GPC with good polydispersity. Agarose gel retardation and fluorescent titration using ethidium bromide showed good DNA-binding ability of 5. They could retard plasmid DNA (pDNA) at an N/P ratio of 4-6 and form polyplexes with sizes around 100-250 nm from an N/P ratio of 10 to 60 and relatively low zeta-potential values (5-22 mV). The cytotoxicity of 5 assayed by MTT is much lower than that of 20 kDa PEI. In vitro transfection against A549 and 293 cells showed that the transfection efficiency (TE) of 5c/DNA polyplexes is close to that of 20 kDa PEI at an N/P ratio of 5. Structure-activity relationship (SAR) of 5 was discussed in their DNA-binding, cytotoxicity, and transfection studies. The TE of 5c/DNA polyplexes could be improved by the introduction of 50 μM of chloroquine, the endosomolytic agents, to pretreated cells. These studies may extend the application areas of macrocyclic polyamines, especially for cyclen.     

High transfection efficiency of cationic lipids with asymmetric acyl-cholesteryl hydrophobic tails

The ability of a nonviral gene delivery system to overcome extra- and intracellular barriers is a critical issue for the future clinical applications of gene therapy. In recent years much effort has been focused on the development of a variety of DNA carriers, and cationic liposomes have become the most common nonviral gene delivery system. One hundred and eighty novel cationic lipids with asymmetric acyl-cholesteryl hydrophobic tails were synthesized by parallel solid-phase chemistry. The liposomes were prepared and gel retardation assays were used to study the binding efficiency between the prepared liposome and the DNA. Transfection efficiencies of the lipids were evaluated against various mammalian cells, such as human embryonic kidney (HEK293), human cervical adenocarcinoma (HeLa), canine osteosarcoma (D17), colorectal adenocarcinoma (COLO 205), and human prostate adenocarcinoma (PC3) cells. The lipids with an acyl portion at the terminal part of the polyamine backbone exhibited higher transfection efficiency than those with the acyl portion as an internal part of the backbone. These compounds also showed higher transfection efficiency and lower cytotoxicity than the commercially available agents, Effectene, DOTAP, and DC-Chol.