Rapid transport of plasmid DNA into the nucleolus via actin depolymerization using the HVJ envelope vector

BACKGROUND: Although nuclear transport of therapeutic genes is an essential requirement of human gene therapy, factors required for nuclear entry of DNA remain to be elucidated. Non-viral vector systems have led to numerous improvements in the efficiency of delivery of exogenous DNA into cells. However, nuclear transport of plasmid is difficult to achieve. METHODS: We examined nuclear translocation efficiency of Cy3-labeled plasmid DNA (Cy3-pDNA) delivered by the hemagglutinating virus of Japan envelope (HVJ-E) vector, Lipofectamine or microinjection. We also examined the effect of actin depolymerization on nuclear transport of Cy3-pDNA. RESULTS: Cy3-pDNA reached the nucleus, particularly in the nucleolus, in 30 min after fusion-mediated delivery using the HVJ-E vector, while the DNA was retained in the cytoplasm during the observed period after the delivery by cationic liposomes. HVJ-E treatment transiently depolymerized actin filaments, and acceleration of nucleolar entry of microinjected DNA was achieved when treated with either empty HVJ-E or cytochalasin D, an inhibitor of actin depolymerization, prior to microinjection. CONCLUSIONS: These results suggest that plasmid DNA can be transported rapidly from the cytoplasm to the nucleolus when actin filaments are depolymerized. Thus, the HVJ-E vector can accelerate the transport of DNA to the nucleolus by actin depolymerization.     

Enhanced cellular delivery and transfection efficiency of plasmid DNA using positively charged biocompatible colloidal gold nanoparticles

Efficient and safe nonviral gene delivery systems are a prerequisite for the clinical application of therapeutic genes. In this study, we report an enhancement of the transfection efficiency of plasmid DNA, via the use of positively charged colloidal gold nanoparticles (PGN). Plasmid DNA encoding for murine interleukin-2 (pVAXmIL-2) was complexed with PGN at a variety of ratios. The delivery of pVAXmIL-2 into C2C12 cells was dependent on the complexation ratios between PGN and the plasmid DNA, presented the highest delivery at a ratio of 2400:1. After complexation with DNA, PGN showed significantly higher cellular delivery and transfection efficiency than did the polyethylenimines (PEI) of different molecular weights, such as PEI25K (m.w. 25 kd) and PEI2K (m.w. 2 kd). PGN resulted in a cellular delivery of pVAXmIL-2 6.3-fold higher than was seen with PEI25K. The PGN/DNA complex resulted in 3.2- and 2.1-fold higher murine IL-2 protein expression than was seen in association with the PEI25K/DNA and PEI2K/DNA complexes, respectively. Following intramuscular administration, PGN/DNA complexes showed more than 4 orders of magnitude higher expression levels as compared to naked DNA. Moreover, the PGN/DNA complexes showed higher cell viability than other cationic nonviral vectors. Collectively, the results of this study suggest that the PGN/DNA complexes may harbor the potential for development into efficient and safe gene delivery vehicles.     

PEI-Et输送特异性shRNA对大鼠肝细胞AGT基因表达的影响

目的:研究交联小分子量聚乙烯亚胺衍生物PEI-Et对大鼠肝细胞(BRL-3A)的细胞毒性、转染效率和携带高血压相关基因血管紧张素原(AGT)短发卡RNA(shRNA)沉默AGT表达的能力。方法:MTT法检测PEI-Et/shRNA复合物对BRL-3A细胞的毒性,流式细胞术检测PEI-Et/shRNA复合物对BRL-3A细胞的转染效率,RT-PCR和Western blot检测PEI-Et/shRNA对AGT的基因沉默效果。结果:在相同质量比(w/w)时PEI-Et/shRNA的细胞毒性小于PEI 25kDa/shRNA(P0.01),PEI-Et/shRNA在w/w为30时达到最高转染效率,高于PEI 25 kDa(P0.01),PEI-Et/shRNA能高效沉默BRL-3A细胞中AGT基因的表达。结论:PEI-Et在BRL-3A细胞中是一种低细胞毒性、高转染效率的非病毒基因载体(与商业化的PEI 25kDa比较),能携带AGT shRNA高效沉默BRL-3A细胞中AGT基因的表达,通过用PEI-Et/AGT shRNA来抑制AGT的表达将为高血压的基因治疗提供一种新的思路。     

Differential intracellular distribution of DNA complexed with polyethylenimine (PEI) and PEI-polyarginine PTD influences exogenous gene expression within live COS-7 cells

Background

Polyethylenimine (PEI) is one of the most efficient and versatile non-viral vectors available for gene delivery. Despite many advantages over viral vectors, PEI is still limited by lower transfection efficiency compared to its viral counterparts. Considerable investigation is devoted to the modification of PEI to incorporate virus-like properties to improve its efficacy, including the incorporation of the protein transduction domain (PTD) polyarginine (Arg); itself demonstrated to facilitate membrane translocation of molecular cargo. There is, however, limited understanding of the underlying mechanisms of gene delivery facilitated by both PEI and PEI-bioconjugates such as PEI-polyarginine (PEI-Arg) within live cells, which once elucidated will provide valuable insights into the development of more efficient non-viral gene delivery vectors.

Methods

PEI and PEI-Arg were investigated for their ability to facilitate DNA internalization and gene expression within live COS-7 cells, in terms of the percentage of cells transfected and the relative amount of gene expression per cell. Intracellular trafficking of vectors was investigated using fluorescent microscopy during the first 5 h post transfection. Finally, nocodazole and aphidicolin were used to investigate the role of microtubules and mitosis, respectively, and their impact on PEI and PEI-Arg mediated gene delivery and expression.

Results

PEI-Arg maintained a high cellular DNA uptake efficiency, and facilitated as much as 2-fold more DNA internalization compared to PEI alone. PEI, but not PEI-Arg, displayed microtubule-facilitated trafficking, and was found to accumulate within close proximity to the nucleus. Only PEI facilitated significant gene expression, whereas PEI-Arg conferred negligible expression. Finally, while not exclusively dependant, microtubule trafficking and, to a greater extent, mitotic events significantly contributed to PEI facilitated gene expression.

Conclusion

PEI polyplexes are trafficked by an indirect association with microtubules, following endosomal entrapment. PEI facilitated expression is significantly influenced by a mitotic event, which is increased by microtubule organization center (MTOC)-associated localization of PEI polyplexes. PEI-Arg, although enhancing DNA internalization per cell, did not improve gene expression, highlighting the importance of microtubule trafficking for PEI vectors and the impact of the Arg peptide to intracellular trafficking. This study emphasizes the importance of a holistic approach to investigate the mechanisms of novel gene delivery vectors.     

Preparation and characterization of heparinized multi-walled carbon nanotubes

The characteristics of heparinized multiwalled carbon nanotubes (MWNTs) were investigated in terms of the activated partial thromboplastin time (APTT) to verify the heparin activity, a carbazole assay was done to measure the content of the immobilized heparin, and the octanol-water partition coefficient was assessed to determine the lipophilicity. Two heparin-immobilized MWNTs were prepared to evaluate their differences. The first preparation method involved polymer-coated MWNTs with heparin indirectly center-point-attached. In the second approach, heparin was directly end-point-attached through its reducing end onto acid-treated MWNTs. The blood compatibility of MWNTs to which heparin was end-point-attached through its reducing end was greatly enhanced compared to that of the MWNTs onto which heparin was center-point-attached. The APTT and carbazole assay results demonstrated that heparinized MWNTs prepared through end-point attachment result in prolonged plasma-based anticoagulant activity. The blood compatibility of MWNTs heparinized by end-point attachment was not decreased up to the fourth pasteurization. Heparinized MWNTs were also studied using octanol-water partition, which should be useful for exploring heparinized MWNTs as drug carriers including delivery systems. The results of octanol/water partition on the design of heparinized MWNTs prepared by end-point attachment with a specific binding can facilitate the design of drug delivery carriers with high blood compatibility.     

Covalent functionalization of multiwalled carbon nanotubes with a low molecular weight chitosan

Covalent functionalization of shortened multiwalled carbon nanotubes (MWNTs) with a natural low molecular weight chitosan (LMCS) was accomplished by a nucleophilic substitution reaction. Amino and primary hydroxyl groups of the LMCS contributed mainly to the formation of MWNT-LMCS conjugates. The LMCS content in the MWNT-LMCS is approximately 58 wt %, and approximately four molecular chains of the LMCS are attached to 1000 carbon atoms of the nanotube sidewalls. Most interestingly, the amorphous packing structure of the LMCS changed dramatically when it attached to the MWNTs. The MWNTs might induce the crystalline character of the LMCS. As a novel derivative of MWNTs, the MWNT-LMCS is soluble in dimethylformamide, dimethyl acetamide, dimethylsulfoxide, and acetic acid aqueous solution. The confirmation of the chitosan-based covalent functionalization route might lead to further studies aiming for potential applications in catalysis and environmental protection.     

Self-assemble gene delivery system for molecular targeting using nucleic acid aptamer

We have developed a novel vector constructed with pDNA, polyethylenimine (PEI), and mucin 1 (MUC1) aptamer for tumor-targeted gene delivery. The MUC1 aptamer and non-specific aptamer were employed to coat the pDNA/PEI complexes electrostatically and stable nanoparticles were formed. The addition of a non-specific aptamer to the pDNA/PEI complex decreased gene expression in the human lung cancer cell line, A549 cells expressing MUC1 regularly. At the same time, the pDNA/PEI/MUC1 aptamer complex showed higher gene expression than pDNA/PEI/non-specific aptamer complex. Furthermore, the pDNA/PEI/MUC1 aptamer complex showed markedly high gene expression in tumor-bearing mice; thus, pDNA/PEI/MUC1 aptamer complexes are useful as a tumor-targeted gene delivery system with high transfection efficiency.     

Amperometric sensor based on ferrocene-modified multiwalled carbon nanotube nanocomposites as electron mediator for the determination of glucose

A kind of nanocomposite with good dispersion in water was prepared through covalent adsorption of ferrocenecarboxaldehyde on multiwalled carbon nanotubes (MWNTs) for electrical communication between glucose oxidase (GOD) and electrode. The ferrocene-modified multiwalled carbon nanotube nanocomposites (MWNTs-Fc) could be conveniently cast on electrode surfaces. With the aid of chitosan, GOD was then immobilized on the nanostructure film to form a reagentless amperometric sensor for glucose determination. FTIR spectra and cyclic voltammetry were used to characterize the nanocomposites. The presence of both ferrocene as mediator of electron transfer and MWNTs as conductor enhanced greatly the enzymatic response to the oxidation of glucose. The novel biosensor exhibited a fast response toward glucose with a detection limit of 3.0 × 10⁻⁶ mol/L and the linear range extended up to 3.8 × 10⁻³ mol/L.     

交联聚乙烯亚胺衍生物的构建及其转染COS-7 细胞的研究

目的:优化构建交联聚乙烯亚胺(Polyethylenemine,PEI)衍生物PEI-Bu,研究其对非洲绿猴肾成纤维细胞系(COS-7)的转染活性和细胞毒性。方法:以PEI 800Da为骨架,1,4-丁二醇二氯甲酸酯为连接剂制备聚合物PEI-Bu,琼脂糖凝胶电泳考察其复合质粒DNA的能力,MTT法检测PEI-Bu对COS-7的毒性,以荧光素酶质粒作为报告基因,测定PEI-Bu/DNA复合物在COS-7细胞的转染活性。结果:凝胶电泳表明PEI-Bu/DNA在质量比大于1时即具有复合DNA的能力,PEI-Bu的细胞毒性随浓度增大而增大,在同一浓度下PEI-Bu的细胞毒性小于PEI 25kDa,(P<0.05),PEI-Bu/DNA在质量比为5时达到最高转染活性,高于PEI 25kDa(P<0.01),并与Lipofectamine2000相当(P>0.05)。结论:PEI-Bu在COS-7细胞中是一种低细胞毒性、高转染活性的非病毒基因载体(与商业化的PEI 25kDa比较),其在基因治疗领域中具有潜在的应用前景。     

Bacterial magnetic particles (BMPs)-PEI as a novel and efficient non-viral gene delivery system

BACKGROUND: Non-viral methods of gene delivery, especially using polyethylenimine (PEI), have been widely used in gene therapy or DNA vaccination. However, the PEI system has its own drawbacks, which limits its applications. METHODS: We have developed a novel non-viral delivery system based on PEI coated on the surface of bacterial magnetic nanoparticles (BMPs). The ability of BMPs-PEI complexes to bind DNA was determined by retardation of plasmid DNA in agarose gel electrophoresis. The transfection efficiency of BMPs-PEI/DNA complexes into eukaryotic cells was determined by flow cytometric analysis. The MTT assay was invited to investigate the cytotoxicity of BMPs-PEI/DNA complexes. The expression efficiency in vivo of BMPs-PEI bound to the plasmid pCMVbeta encoding beta-galactosidase was evaluated intramuscularly inoculated into mice. The immune responses of in vivo delivery of BMPs-PEI bound plasmid pcD-VP1 were determined by MTT assay for T cell proliferation and ELISA for detecting total IgG antibodies. RESULTS: BMPs-PEI complexes could bind DNA and provide protection from DNase degradation. The transfection efficiency of BMPs-PEI/DNA complexes was higher than that in PEI/DNA complexes. Interestingly, in contrast to PEI, the BMPs-PEI complex was less cytotoxic to cells in vitro. We further demonstrated that the BMPs-PEI system can deliver an exogenous gene to animals and allow it to be expressed in vivo. Such expression resulted in higher levels of humoral and cellular immune responses against the target antigen compared to controls. CONCLUSIONS: We have developed a novel BMPs-PEI gene delivery system with a high transfection efficiency and low toxicity, which presents an attractive strategy for gene therapy and DNA vaccination.     

Fabrication of bienzyme nanobiocomposite electrode using functionalized carbon nanotubes for biosensing applications

Mediated biosensors consisting of an oxidase and peroxidase (POx) have attracted increasing attention because of their wider applicability. This work presents a novel approach to fabricate nanobiocomposite bienzymatic biosensor based on functionalized multiwalled carbon nanotubes (MWNTs) with the aim of evaluating their ability as sensing elements in amperometric transducers. Electrochemical behavior of the bienzymatic nanobiocomposite biosensor is investigated by Faradaic impedance spectroscopy and cyclic voltammetry. The results indicate that glucose oxidase (GOD) and horseradish peroxidase (HRP) are strongly adsorbed on the surface of the thionin (TH) functionalized MWNTs and demonstrate a facile electron transfer between immobilized GOD/HRP and the electrode via the functionalized MWNTs in a Nafion film. The functionalized carbon nanotubes act as molecular wires to allow efficient electron transfer between the underlying electrode and the redox centres of enzymes through TH. Linear ranges for these electrodes are from 10 nM to 10 mM for glucose and 17 nM to 56 mM for hydrogen peroxide with the detection limit of 3 and 6 nM, respectively. A remarkable feature of the bienzyme electrode is the possibility to determine glucose and hydrogen peroxide at a very low applied potential where the noise level and interferences from other electroactive compounds are minimal. Performance of the biosensor is evaluated with respect to response time, detection limit, selectivity, temperature and pH as well as operating and storage stability.     

Bienzyme system for the biocatalyzed deposition of polyaniline templated by multiwalled carbon nanotubes: a biosensor design

A novel method based on covalent attachment of two enzymes, glucose oxidase (GOD) and horseradish peroxide (HRP), onto carboxylic-derived multiwalled carbon nanotubes (MWNTs) for the deposition of electroactive polyaniline (PANI) under ambient conditions is described. Ultraviolet-visible spectroscopy, Fourier-transform infrared (FTIR) spectroscopy, and transmission electron microscopy were used to characterize the assembling of bienzyme and the morphology of PANI|MWNTs. Under the bienzyme biocatalytic condition, a head-to-tail structure of PANI templated by MWNTs was formed. The voltammetric characteristics of the resulting biosensor were investigated by cyclic voltammetry in the presence of glucose. The current response of PANI was linearly related to glucose concentration between 0.05 and 12.0mM with a correlation coefficient of 0.994. The synergistic performance of bienzyme, highly efficient polymerization, and templated deposition provide a general platform for the synthesis of nanowires and nanocircuits, the construction of bioelectronic devices, and the design of novel biosensors.     

Efficient and rapid uptake of magnetic carbon nanotubes into human monocytic cells: implications for cell-based cancer gene therapy

Monocyte-based gene therapies in cancer have been hampered by either the resistance of these cells to non-viral molecular delivery methods or their poor trafficking to the tumor site after their ex vivo manipulations. Magnetic nanoparticles (MNP)-loaded genetically engineered monocytes can efficiently delivered to tumor site by external magnetic field, but they are not ideal delivery tools due to their spherical shape. Hence, we have investigated the cellular uptake efficiency and cytotoxicity of fluorescein isothiocyanate (FITC)-labelled magnetic carbon nanotubes (FITC-mCNT) in human monocytic leukemia cell line THP-1 for application in cell-based gene therapy against cancer. Uptake of FITC-mCNT into THP-1 cells reached 100% only 1 h after the delivery. Confocal imaging confirmed that FITC-mCNT entered the cell cytoplasm and even into the nucleus. FITC-mCNT uptake did not compromise cell viability. This delivery system might therefore enhance cell-based cancer gene therapies.     

Preparation and mechanical properties of chitosan/carbon nanotubes composites

Biopolymer chitosan/multiwalled carbon nanotubes (MWNTs) nanocomposites have been successfully prepared by a simple solution-evaporation method. The morphology and mechanical properties of the chitosan/MWNTs nanocomposites have been characterized with field emission scanning electron microscopy (SEM), bright field transmission electron microscopy (TEM), optical microscopy (OM), wide-angle X-ray diffraction (XRD), and tensile as well as nanoindentation tests. The MWNTs were observed to be homogeneously dispersed throughout the chitosan matrix. When compared with neat chitosan, the mechanical properties, including the tensile modulus and strength, of the nanocomposites are greatly improved by about 93% and 99%, respectively, with incorporation of only 0.8 wt % of MWNTs into the chitosan matrix.     

Low molecular weight polyethylenimine for efficient transfection of human hematopoietic and umbilical cord blood-derived CD34+ cells

With the emerging role of hematopoietic stem cells as potential gene and cell therapy vehicles, there is an increasing need for safe and effective nonviral gene delivery systems. Here, we report that gene transfer and transfection efficiency in human hematopoietic and cord blood CD34+ cells can be enhanced by the use of low molecular weight polyethylenimine (PEI). PEIs of various molecular weights (800-750,000) were tested, and our results showed that the uptake of plasmid DNA by hematopoietic TF-1 cells depended on the molecular weights and the N/P ratios. Treatment with PEI 2K (m.w. 2000) at an N/P ratio of 80/1 was most effective, increasing the uptake of plasmid DNA in TF-1 cells by 23-fold relative to Lipofectamine 2000. PEI 2K-enhanced transfection was similarly observed in hematopoietic K562, murine Sca-1+, and human cord blood CD34+ cells. Notably, in human CD34+ cells, a model gene transferred with PEI 2K showed 21,043- and 513-fold higher mRNA expression levels relative to the same construct transfected without PEI or with PEI 25 K, respectively. Moreover, PEI 2K-treated TF-1 and human CD34+ cells retained good viability. Collectively, these results indicate that PEI 2K at the optimal N/P ratio might be used to safely enhance gene delivery and transfection of hematopoietic and human CD34+ stem cells.     

LDL coating pVEGF/polyethylenimine complex enhances vascular endothelial growth factor expression

The major limitations to non-viral gene delivery are relatively low efficiency and cytotoxicity, which need to be addressed in the design of new vectors. In this study, negatively charged low density lipoproteins (LDL) were coated onto positively charged pVEGF/PEI complexes to form pVEGF/PEI/LDL terplexes by a two-step procedure. The biocompatible LDL was introduced to reduce the cytotoxicity of the gene delivery system and increase its affinity to cells. The successful formation of pVEGF/PEI/ LDL terplexes was confirmed by their near-neutral and slightly negative surface charges. The pVEGF/PEI/LDL terplexes were well-defined sub-micron spherical particles. On the cell viability assay, both of the PEI/LDL combined vector and pVEGF/PEI/LDL terplexes exhibited much lower cytotoxicity to HeLa cells and HUVE cells than those of PEI and pVEGF/PEI complexes, attributed to the shielding effect of the LDL. pEGFP/PEI/LDL terplexes showed significantly higher transfection efficiency in comparison to pEGFP/PEI complexes in serum-containing medium. pVEGF/PEI/LDL terplexes at their optimal N/P ratio and LDL/PEI weigh ratio induced higher expression levels of VEGF protein in HUVE cells than those of pVEGF/PEI complexes. Therefore, the pVEGF/PEI/LDL terplexes could be used as a promising gene delivery system to enhance VEGF protein expression.     

Characterization of Ku70(2)-NLS as bipartite nuclear localization sequence for non-viral gene delivery

Several barriers have to be overcome in order to achieve gene expression in target cells, e.g. cellular uptake, endosomal release and translocation to the nucleus. Nuclear localization sequences (NLS) enhance gene delivery by increasing the uptake of plasmid DNA (pDNA) to the nucleus. So far, only monopartite NLS were analysed for non-viral gene delivery. In this study, we examined the characteristics of a novel bipartite NLS like construct, namely NLS Ku70. We synthesized a dimeric structure of a modified NLS from the Ku70 protein (Ku70(2)-NLS), a nuclear transport active mutant of Ku70(2)-NLS (s1Ku70(2)-NLS) and a nuclear transport deficient mutant of Ku70(2)-NLS (s2Ku70(2)). We examined the transfection efficiency of binary Ku70(2)-NLS/DNA and ternary Ku70(2)-NLS/PEI/DNA gene vector complexes in vitro by using standard transfection protocols as well as the magnetofection method. The application of Ku70(2)-NLS and s1Ku70(2)-NLS increased gene transfer efficiency in vitro and in vivo. This study shows for the first time that the use of bipartite NLS compounds alone or in combination with cationic polymers is a promising strategy to enhance the efficiency of non-viral gene transfer.     

Biodegradable cross-linked poly(amino alcohol esters) based on LMW PEI for gene delivery

Polyethylenimine (PEI, especially with M(w) of 25,000) has been known as an efficient gene carrier and a gold standard of gene transfection due to its high transfection efficiency (TE). However, high concomitant cytotoxicity limited the application of PEI. In this report, several cationic polymers derived from low molecular weight (LMW) PEI (M(w) 600) linked with diglycidyl adipate (DA-PEI) or its analogs (diglycidyl succinate, DS-PEI and diglycidyl oxalate, DO-PEI; D-PEIs for all 3 polymers) were prepared and characterized. GPC gave M(w)s of DA-PEI, DS-PEI and DO-PEI as 6861, 16,015 and 35,281, respectively. Moreover, degradation of the ester-containing DS-PEI was also confirmed by GPC. In addition, hydroxyls in these polymers could improve their water solubility. These polymers exhibited good ability to condense plasmid DNA into nanoparticles with the size of 120-250 nm. ζ-potentials of the polyplexes were found to be around +10-20 mV under weight ratios (polymer/DNA) from 0.5 to 32. Agarose gel retardation showed that DNA could be released from the polyplexes after being pre-incubated for 30 h. In vitro experiments were carried out and it was found that DS-PEI showed about 5 times of TE compared to that of the PEI/DNA polyplex under a weight ratio of 1 in A549 cells. Meanwhile, the cytotoxicity of D-PEIs assayed by MTT is lower than that of 25 kDa PEI in HEK293 cells. These results suggested that this series of PEI derivatives would be promising non-viral biodegradable vectors for gene delivery.     

PEG修饰的聚阳离子基因载体PEG-Polycarbam-SP在COS-7细胞中转染和毒性的研究

目的：寻找一种转染效率高,细胞毒性低的非病毒基因载体,研究以人体内源性精胺为单体,以乙二醇二氯甲酸酯作为连接剂,以聚乙二醇（PEG）作为亲水基团连接剂合成亲水修饰聚阳离子载体PEG-Polycarbam-SP的基因担载效率,以及对非洲绿猴肾癌细胞COS-7的转染活性和细胞毒性的影响。方法：琼脂糖凝胶电泳方法考察复合物的基因担载效率,检测基因复合物的粒径和电位,以荧光素酶质粒为报告基因,研究PEG-Polycarbam-SP/DNA的复合物在COS-7细胞的转染活性,用MTT方法研究PEG-Polycarbam-SP对COS-7细胞的毒性。结果：聚合物与质粒在质量比5以后形成的复合物粒径稳定在50nm左右,Zate电位在20mV左右。COS-7细胞实验显示PEG-Polycarbam-SP具有低于PEI 25kDa的细胞毒性,同时也具有高效输送DNA的能力。结论：PEG-Polycarbam-SP是一种新型的高效、低毒,在基因治疗领域有潜在应用价值的非病毒基因输送载体。