An epoch-making application of discharge plasma phenomenon to gene-transfer

We discovered an epoch-making gene transfer method utilizing discharge plasma. Although an electroporation method is commonly used in present gene transfer experiments, it cannot transfer genes into primary cells sufficiently. The atmospheric pressure discharge plasma employed in this study was originally used for surface treatment of non-biological materials. We hypothesized that it could provide a suitable effect on the surface of target cells and applied it to gene transfer into various types of cells. The plasma technology succeeded in the efficient transfer of green fluorescence protein (GFP) plasmid into post-mitotic neuronal cells obtained from cerebral cortices of rats, into which an electroporation with conventional equipment cannot transfer genes sufficiently, as the cells were attached. After the transfection of rat pheochromocytoma PC12 cells with the GFP gene by plasma treatment, the cells retained their function, that is, nerve growth factor-induced differentiation. Furthermore, gene transfer with the plasma technology was also applicable to other types of cell lines such as HeLa cells and Chinese hamster lung (CHL) cells as adherent cell lines, and Jurkat cells as a suspended cell line, and another type of primary cell, human umbilical vein endothelial cells (HUVEC). In conclusion, the plasma method is an epoch-making gene transfer technology which efficiently transfers genes into primary cells into which electroporation cannot transfer genes. Moreover, the method is able to universally transfer genes into various types of cells as the function of the cells was maintained.     

Nucleofection as an efficient nonviral transfection method for human monocytic cells

Despite some progress in the field of gene transfer into hard-to-transfect cells, so far an efficient nonviral method for monocytes has not been available. A comparison of plasmid DNA with capped and polyadenylated mRNA for enhanced green fluorescent protein gene delivery into the commonly used monocytic cell lines U937 and THP-1 suggested that limited DNA trafficking may be the underlying cause of poor transfection results. As Nucleofector technology delivers DNA (or mRNA) straight into the nucleus, we obtained nucleofection efficiencies of up to 80% without significant cell toxicity. Moreover, as the DNA quickly reaches the nucleus, nucleofected cells were ready for analysis after only 2–6 h. The technique is suitable not only for monocytes but also for other hard-to-transfect cells.     

Novel non-viral method for transfection of primary leukemia cells and cell lines

BACKGROUND: Tumor cells such as leukemia and lymphoma cells are possible targets for gene therapy. However, previously leukemia and lymphoma cells have been demonstrated to be resistant to most of non-viral gene transfer methods. METHODS: The aim of this study was to analyze various methods for transfection of primary leukemia cells and leukemia cell lines and to improve the efficiency of gene delivery. Here, we evaluated a novel electroporation based technique called nucleofection. This novel technique uses a combination of special electrical parameters and specific solutions to deliver the DNA directly to the cell nucleus under mild conditions. RESULTS: Using this technique for gene transfer up to 75% of primary cells derived from three acute myeloid leukemia (AML) patients and K562 cells were transfected with the green flourescent protein (GFP) reporter gene with low cytotoxicity. In addition, 49(+/- 9.7%) of HL60 leukemia cells showed expression of GFP. CONCLUSION: The non-viral transfection method described here may have an impact on the use of primary leukemia cells and leukemia cell lines in cancer gene therapy.     

Human somatic cell gene therapy

The prelude to successful human somatic gene therapy, i.e. the efficient transfer and expression of a variety of human genes into target cells, has already been accomplished in several systems. Safe methods have been devised to do this using non-viral and viral vectors. Potentially therapeutic genes have been transferred into many accessible cell types, including hematopoietic cells, hepatocytes and cancer cells, in several different approaches to ex vivo gene therapy. Successful in vivo gene therapy requires improvements in tissuetargeting and new vector design, which are already being sought. Gene-transfer protocols have been approved for human use in inherited diseases, cancer and acquired disorders. Althouth the results of these trials to date have been somewhat disappointing, human somatic cell gene therapy promises to be an effective addition to the arsenal of approaches to the therapy of many human diseases in the 21st century if not sooner.     

Receptor-Mediated Transfer of DNA–Galactosylated Poly-L-lysine Complexes into Mammalian Cells in vitro and in vivo

With the goal of developing non-viral techniques for exogenous gene delivery into mammalian cells, we have studied receptor-mediated gene transfer using complexes of plasmid DNA and galactosylated poly-L-lysine, poly(L-Lys)Gal. To evaluate the optimal parameters for efficient gene transfer into human hepatoma HepG2 cells by the DNA–poly(L-Lys)Gal complexes, the bacterial reporter genes lacZ and cat were used. Examination of the reporter gene expression level showed that the efficiency of DNA delivery into the cells depends on the structure of DNA–poly(L-Lys)Gal complexes formed at various ionic strength values. The efficiency of DNA transfer into the cells also depends on DNA/poly(L-Lys)Gal molar ratio in the complexes. Plasmid vector carrying human apolipoprotein A-I (apoA-I) gene was injected as its complex with poly(L-Lys)Gal into rat tail vein. Some level of ApoA-I was detected in the serum of the injected rats. Also, the human apoA-I-containing plasmid was found to be captured specifically by the rat liver cells and transported into the cell nuclei, where it can persist as an episome-like structure for at least a week. After repeated injections of DNA–poly(L-Lys)Gal complexes, the level of human ApoA-I in rat serum increases, probably, due to accumulation of functional human apoA-I gene in the liver cell nuclei. The data seem to be useful for the development of non-viral approaches to gene therapy of cardiovascular diseases.     

Extended and stable gene expression via nucleofection of MIDGE construct into adult human marrow mesenchymal stromal cells

Human mesenchymal stromal cell (hMSC) is a potential target for cell and gene therapy-based approaches against a variety of different diseases. Whilst cationic lipofection has been widely experimented, the Nucleofector technology is a relatively new non-viral transfection method designed for primary cells and hard-to-transfect cell lines. Herein, we compared the efficiency and viability of nucleofection with cationic lipofection, and used the more efficient transfection method, nucleofection, to deliver a construct of minimalistic, immunologically defined gene expression encoding the erythropoietin (MIDGE-EPO) into hMSC. MIDGE construct is relatively safer than the viral and plasmid expression systems as the detrimental eukaryotic and prokaryotic gene and sequences have been eliminated. Using a plasmid encoding the luciferase gene, we demonstrated a high transfection efficiency using the U-23 (21.79 ± 1.09%) and C-17 (5.62 ± 1.09%) pulsing program in nucleofection. The cell viabilities were (44.93 ± 10.10)% and (21.93 ± 5.72)%, respectively 24 h post-nucleofection. On the other hand, lipofection treatment only yielded less than 0.6% efficiencies despite showing higher viabilities. Nucleofection did not affect hMSC renewability, immunophenotype and differentiation potentials. Subsequently, we nucleofected MIDGE-EPO using the U-23 pulsing program into hMSC. The results showed that, despite a low nucleofection efficiency with this construct, the EPO protein was stably expressed in the nucleofected cells up to 55 days when determined by ELISA or immunocytochemical staining. In conclusion, nucleofection is an efficient non-viral transfection approach for hMSC, which when used in conjunction with a MIDGE construct, could result in extended and stable transgene expression in hMSC.     

Transfecting human neural stem cells with the Amaxa Nucleofector

Transfection of primary mammalian neural cells, such as human neural stem/precursor cells (hNSPCs), with commonly used cationic lipid transfection reagents has often resulted in poor cell viability and low transfection efficiency. Other mechanical methods of introducing a gene of interest, such as a "gene gun" or microinjection, are also limited by poor cell viability and low numbers of transfected cells. The strategy of using viral constructs to introduce an exogenous gene into primary cells has been constrained by both the amount of time and labor required to create viral vectors and potential safety concerns. We describe here a step-by-step protocol for transfecting hNSPCs using Amaxa's Nucleofector device and technology with electrical current parameters and buffer solutions specifically optimized for transfecting neural stem cells. Using this protocol, we have achieved initial transfection efficiencies of ~35% and ~70% after stable transfection. The protocol entails combining a high number of hNSPCs with the DNA to be transfected in the appropriate buffer followed by electroporation with the Nucleofector device.     

Electroporation: parameters affecting transfer of DNA into mammalian cells

Electroporation, the reversible breakdown of cell membranes caused by a high-voltage discharge, is a rapid, simple, and efficient method for introducing DNA into mammalian cells. An instrument for electroporation which permits the high-voltage discharge waveform to be varied with respect to rise time, peak voltage, and fall time is described. The uptake and expression of SV40 DNA following electroporation of two cell types, a human carcinoma-derived cell line, HEp-2, and a human lymphoblastoid cell line, 721, depended on the peak voltage and the fall time of the voltage discharge. The electronic parameters which produced optimum DNA transfer, however, differed for the two cell types. DNA as large as 150 kb was introduced into cells by electroporation. Cells can be electroporated in either phosphate-buffered saline or culture medium containing fetal bovine serum, and the efficiency of DNA transfer does not vary with cell densities from 10(6) to 2 X 10(7)/0.5 ml. Exposing the cells to multiple voltage discharges did not improve DNA transfer. DNA has been introduced by electroporation into all cell types tested, including human carcinoma-derived cell lines, human lymphoblastoid cell lines, human fibroblast strains, and primary human lymphocytes. To obtain maximal DNA transfer by this method, however, one must optimize the peak voltage and fall time of the discharge waveform for each cell type.     

A novel peptide, THALWHT, for the targeting of human airway epithelia

Targeting gene vectors to human airway epithelial cells may help to overcome the current inefficiency of gene transfer as the major problem confronting cystic fibrosis gene therapy. To elucidate novel ligands targeting abundant, apically located receptors on airway epithelial cells, a phage display library was screened for peptides binding with high affinity to such cells. This screening yielded a selectively enriched amino acid sequence, Thr-His-Ala-Leu-Trp-His-Thr (THALWHT). Subsequent binding studies confirmed that THALWHT-displaying phages bound much stronger than phages displaying control peptides to human airway epithelial cells. In contrast, no significant binding differences were observed on a variety of non-airway-derived human cell lines suggesting selective binding of the THALWHT motif to airway epithelia. Confocal microscopy of such cells after exposure to labelled synthetic THALWHT peptide indicated that its binding is followed by specific internalisation via endocytosis. A synthetic peptide comprising a cyclic CTHALWHTC domain and a DNA binding moiety enabled efficient targeted gene delivery into human airway epithelial cells. Competition assays with free THALWHT peptide confirmed the specificity of gene delivery. Thus, the THALWHT motif may prove a useful targeting moiety for both non-viral and viral gene therapy vectors.     

Expression of exogenous proteins and short hairpin RNAs in human primary thyrocytes

Recently, it has been shown that commercial human thyroid lines were in fact derived from colon, mammary carcinoma, or melanoma. Others have demonstrated the absence of a common pattern of gene expression between available thyroid cancer cell lines and tumors from patients. Thus, it is important to use several primary cells with a common pathological origin to achieve reproducible results, and it is necessary to find common methods for manipulation of protein expression in such various cultures. We have standardized a transfection method for efficient expression of exogenous proteins in human primary thyroid cultures. We compared lipid-based techniques with three electroporation systems (Electroporator PulseAgile [PA]-4000, Microporator MP-100, and Nucleofector II). Nucleofection was unquestionably the most efficient even for promoter regulation studies, and it was effective in cultures from different origins as normal thyroid, papillary carcinoma, or lymphoid node metastasis. We also standardized, through lentiviral infection, the short hairpin RNA downregulation of protein expression generating human thyrocytes with low levels of p27KIP1 as a model system.     

Simian virus 40-based replication of catalytically inactive human immunodeficiency virus type 1 integrase mutants in nonpermissive T cells and monocyte-derived macrophages

Integrase function is required for retroviral replication in most instances. Although certain permissive T-cell lines support human immunodeficiency virus type 1 (HIV-1) replication in the absence of functional integrase, most cell lines and primary human cells are nonpermissive for integrase mutant growth. Since unintegrated retroviral DNA is lost from cells following cell division, we investigated whether incorporating a functional origin of DNA replication into integrase mutant HIV-1 might overcome the block to efficient gene expression and replication in nonpermissive T-cell lines and primary cells. Whereas the Epstein-Barr virus (EBV) origin (oriP) did little to augment expression from an integrase mutant reporter virus in EBV nuclear antigen 1-expressing cells, simian virus 40 (SV40) oriT dramatically enhanced integrase mutant infectivity in T-antigen (Tag)-expressing cells. Incorporating oriT into the nef position of a full-length, integrase-defective virus strain yielded efficient replication in Tag-expressing nonpermissive Jurkat T cells without reversion to an integration-competent genotype. Adding Tag to integrase mutant-oriT viruses yielded 11.3-kb SV40-HIV chimeras that replicated in Jurkat cells and primary monocyte-derived macrophages. Real-time quantitative PCR analyses of Jurkat cell infections revealed that amplified copies of unintegrated DNA likely contributed to SV40-HIV integrase mutant replication. SV40-based HIV-1 integrase mutant replication in otherwise nonpermissive cells suggests alternative approaches to standard integrase-mediated retroviral gene transfer strategies.     

piggyBac Transposon System Modification of Primary Human T Cells

The piggyBac transposon system is naturally active, originally derived from the cabbage looper moth^1,2. This non-viral system is plasmid based, most commonly utilizing two plasmids with one expressing the piggyBac transposase enzyme and a transposon plasmid harboring the gene(s) of interest between inverted repeat elements which are required for gene transfer activity. PiggyBac mediates gene transfer through a "cut and paste" mechanism whereby the transposase integrates the transposon segment into the genome of the target cell(s) of interest. PiggyBac has demonstrated efficient gene delivery activity in a wide variety of insect^1,2, mammalian^3-5, and human cells6 including primary human T cells^7,8. Recently, a hyperactive piggyBac transposase was generated improving gene transfer efficiency^9,10.Human T lymphocytes are of clinical interest for adoptive immunotherapy of cancer¹¹. Of note, the first clinical trial involving transposon modification of human T cells using the Sleeping beauty transposon system has been approved¹². We have previously evaluated the utility of piggyBac as a non-viral methodology for genetic modification of human T cells. We found piggyBac to be efficient in genetic modification of human T cells with a reporter gene and a non-immunogenic inducible suicide gene⁷. Analysis of genomic integration sites revealed a lack of preference for integration into or near known proto-oncogenes¹³. We used piggyBac to gene-modify cytotoxic T lymphocytes to carry a chimeric antigen receptor directed against the tumor antigen HER2, and found that gene-modified T cells mediated targeted killing of HER2-positive tumor cells in vitro and in vivo in an orthotopic mouse model¹⁴. We have also used piggyBac to generate human T cells resistant to rapamycin, which should be useful in cancer therapies where rapamycin is utilized¹⁵.Herein, we describe a method for using piggyBac to genetically modify primary human T cells. This includes isolation of peripheral blood mononuclear cells (PBMCs) from human blood followed by culture, gene modification, and activation of T cells. For the purpose of this report, T cells were modified with a reporter gene (eGFP) for analysis and quantification of gene expression by flow cytometry.PiggyBac can be used to modify human T cells with a variety of genes of interest. Although we have used piggyBac to direct T cells to tumor antigens¹⁴, we have also used piggyBac to add an inducible safety switch in order to eliminate gene modified cells if needed⁷. The large cargo capacity of piggyBac has also enabled gene transfer of a large rapamycin resistant mTOR molecule (15 kb)¹⁵. Therefore, we present a non-viral methodology for stable gene-modification of primary human T cells for a wide variety of purposes.     

Targeting of gene expression by siRNA in CML primary cells

Development of array methods contributes to elucidation of many genes expressed during oncogenesis. Our array-based analyses of gene expression in patients with chronic myeloid leukemia (CML) revealed several genes (MMP8, MMP9, PCNA, JNK2, MAPK p38) with significant increased expression. We suppose that the genes may be implicated in the disease development and a siRNA-suppression can elucidate their functions in leukemogenesis. One of the crucial requirements for this purpose is a high efficiency of siRNA delivery into CML primary cells. Using fluorescein-labeled siRNAs we systematically tested a variety of physical and chemical non-vector based transfection methods in order to evaluate which of them gave the most suitable transfer. Chemically synthesized siRNAs against mentioned genes were transfected into the cells and level of knockdown was determined by real time RT-PCR. Chemical transfection reagents (Oligofectamine, Metafectene, siPORT Amine) commonly used to transfect siRNAs in CML cell lines showed very low siRNA delivery in CML primary cells—mRNA levels decreased at the most to 76%. Electroporation achieved better results (suppression to 63%) but it was associated with high degree of cell death (more than 60%). In the study we obtained the best transfection efficiency using nucleofector technology. Gene expressions ranged 22–37% that remained from original levels. According to our results, nucleofection appears to be the only suitable non-viral method for siRNA delivery into the hard-to-transfect CML primary cells.     

Ultrasound-mediated microbubble destruction facilitates gene transfection in rat C6 glioma cells

The goal of this study was to determine whether ultrasound (US) exposure combined with microbubble destruction could be used to enhance non-viral gene delivery in rat C6 glioma cells. Microbubbles were prepared and gently mixed with plasmid DNA. The mixture of the DNA and microbubbles was administered to cultured C6 cells under different US/microbubble conditions. Transfection efficiency and cell viability were assessed by FACS analysis, confocal laser scanning microscopy, and Trypan blue staining. The results demonstrate that microbubble with US exposure could significantly enhance the reporter gene expression as compared with other groups. No statistical significant difference was observed in the glioma cell viability between different groups. Our in vitro findings suggest that US-mediated microbubble destruction has the potential to promote safe and efficient gene transfer into C6 cells. This non-invasive gene transfer method may be useful for safe clinical gene therapy of brain cancer without a viral vector system.     

Melittin enables efficient vesicular escape and enhanced nuclear access of nonviral gene delivery vectors

Entry of exogenously applied DNA into the cytoplasm and subsequent transport into the nucleus are major cellular barriers for nonviral gene delivery vectors. To overcome these barriers, we have covalently attached the cationic peptide melittin to poly(ethylenimine) (PEI). This conjugate condensed DNA into small, discrete particles (<100 nm in diameter), and the membrane lytic activity of melittin enabled efficient release of the DNA into the cytoplasm, as monitored by fluorescence microscopy and flow cytometry. Compared with PEI, the transfection activity was strongly increased within a broad range of cell lines and types tested, including different tumor cell lines but also primary hepatocytes and human umbilical vein endothelial cells. The early onset of gene expression (within 4 h, reaching maximal values after 12 h) and the high reporter gene expression achieved in slowly dividing or confluent cells suggested a further role of melittin after releasing the DNA into the cytoplasm. Intracytoplasmic microinjection of melittin-containing PEI.DNA complexes into fibroblasts produced 40% cellular frequency of reporter gene expression that was inhibitable by co-injection of wheat germ agglutinin, whereas simple PEI.DNA complexes showed only 10%. These data suggest that melittin enables release of nonviral gene transfer particles into the cytoplasm and also enhances their transport into the nucleus, possibly via the cationic cluster KRKR near the C terminus of the peptide.     

Recombinant mussel adhesive protein as a gene delivery material

Efficient target gene delivery into eukaryotic cells is important for biotechnological research and gene therapy. Gene delivery based on proteins, including histones, has recently emerged as a powerful non-viral DNA transfer technique. Here, we investigated the potential use of a recombinant mussel adhesive protein, hybrid fp-151, as a gene delivery material, in view of its similar basic amino acid composition to histone proteins, and cost-effective and high-level production in Escherichia coli. After confirming DNA binding affinity, we transfected mammalian cells (human 293T and mouse NIH/3T3) with foreign genes using hybrid fp-151 as the gene delivery carrier. Hybrid fp-151 displayed comparable transfection efficiency in both mammalian cell lines, compared to the widely used transfection agent, Lipofectamine 2000. Our results indicate that this mussel adhesive protein may be used as a potential protein-based gene-transfer mediator.     

Pig transgenesis by Sleeping Beauty DNA transposition

Modelling of human disease in genetically engineered pigs provides unique possibilities in biomedical research and in studies of disease intervention. Establishment of methodologies that allow efficient gene insertion by non-viral gene carriers is an important step towards development of new disease models. In this report, we present transgenic pigs created by Sleeping Beauty DNA transposition in primary porcine fibroblasts in combination with somatic cell nuclear transfer by handmade cloning. Göttingen minipigs expressing green fluorescent protein are produced by transgenesis with DNA transposon vectors carrying the transgene driven by the human ubiquitin C promoter. These animals carry multiple copies (from 8 to 13) of the transgene and show systemic transgene expression. Transgene-expressing pigs carry both transposase-catalyzed insertions and at least one copy of randomly inserted plasmid DNA. Our findings illustrate critical issues related to DNA transposon-directed transgenesis, including coincidental plasmid insertion and relatively low Sleeping Beauty transposition activity in porcine fibroblasts, but also provide a platform for future development of porcine disease models using the Sleeping Beauty gene insertion technology.     

Structure of viral DNA in a rat cell line transformed by the cloned EcoRI-C fragment of adenovirus 12.

A DNA segment carrying viral DNA was cloned from a rat cell line transformed by the cloned EcoRI-C fragment (0 to 16.4 map units) of human adenovirus type 12(Ad12), and the viral sequence in the clone was analysed. The cloned segment contained the region from nucleotide positions 118 to 3520 of the Ad12 genome in the middle. No unique structure was found at the viral and non-viral DNA junctions. When examined the transforming activity, the conserved viral sequence was able to transform rat 3Y1 cells efficiently. Southern blotting analysis of the viral sequence in five re-transformed cell lines showed that the viral sequence was inserted at different sites of cellular DNA. These results indicate that (I) the Ad12 DNA moiety from the enhancer-promoter region of the E1A gene to the end of the E1B gene contains enough information for efficient transformation of the rat cell, and (II) integration of the viral sequence at unique cellular sites is not prerequisite for transformation.     

Designing gene delivery vectors for cardiovascular gene therapy

Genetic therapy in the cardiovascular system has been proposed for a variety of diseases ranging from prevention of vein graft failure to hypertension. Such diversity in pathogenesis requires the delivery of therapeutic genes to diverse cell types in vivo for varying lengths of time if efficient clinical therapies are to be developed. Data from extensive preclinical studies have been compiled and a certain areas have seen translation into large-scale clinical trials, with some encouraging reports. It is clear that progress within a number of disease areas is limited by a lack of suitable gene delivery vector systems through which to deliver therapeutic genes to the target site in an efficient, non-toxic manner. In general, currently available systems, including non-viral systems and viral vectors such as adenovirus (Ad) or adeno-associated virus (AAV), have a propensity to transduce non-vascular tissue with greater ease than vascular cells thereby limiting their application in cardiovascular disease. This problem has led to the development and testing of improved vector systems for cardiovascular gene delivery. Traditional viral and non-viral systems are being engineered to increase their efficiency of vascular cell transduction and diminish their affinity for other cell types through manipulation of vector:cell binding and the use of cell-selective promoters. It is envisaged that future use of such technology will substantially increase the efficacy of cardiovascular gene therapy.