Advancements in transfection technologies for Plasmodium

Malaria is a global problem that affects millions of people annually. A relatively poor understanding of the malaria parasite biology has hindered vaccine and drug development against this disease. Robust methods for genetic analyses in Plasmodium have been lacking due to the difficulties in its genetic manipulation. Introduction of transfection technologies laid the foundation for genetic dissection of Plasmodium and recent years have seen the development of novel tools for genetic manipulation that will help us delineate the intriguing biology of this parasite. This review focuses on such recent advances in transfection technologies for Plasmodium that have improved our ability to carry out more thorough genetic analyses of the biology of the malaria parasite.     

Novel strategy for microsphere-mediated DNA transfection

A new approach for microsphere-mediated delivery of plasmid DNA has been developed and successfully evaluated. Basic molecular biology techniques were used to linearize and functionalize plasmid DNA by aminomodification, enabling efficient conjugation to carboxy-functionalized microspheres. A T cell hybridoma line was successfully transfected as determined by the efficient expression of a biologically relevant YFP fusion protein. Moreover, our data identified microsphere-mediated delivery of plasmid DNA as a noninvasive, nontoxic, and efficient gene delivery method with the potential to be applied to transfection-resistant, nondividing primary cells, including na?ve T cells.     

DNA-mediated transfection as a model for oncogenesis

DNA transfer technology has greatly contributed to progress in understanding molecular biology and genetics. In recent years, great efforts have been expended to determine the oncogenic potential of single, defined genes or complex gene mixtures as a prelude to defining the role those genes may play in neoplastic transformation in vitro and tumor induction in vivo. This paper reviews the currently available DNA transfection techniques and their application toward understanding cancer initiation and progression, and how the in vitro and animal models may apply to human cancer.     

Novel selection marker for mammalian cell transfection

The availability of selectable markers suitable for use in mammalian cells has permitted the analysis of the influence of the stable overexpression of single or multiple genes on specific cell properties. This powerful technique has led directly to many fundamental advances in molecular biology and increased our overall understanding of cell growth and regulatory events. Although a variety of selectable markers are currently available, some cell lines continue to be naturally resistant to certain markers, making direct selection difficult or not feasible. Thus, the characterization of additional cell selectable markers continues to be of interest. We have developed a novel selectable marker based on mitomycin C resistance that is suitable for stable transfection of mammalian cells. This system is based on the ability of the mcrA gene, isolatedfrom Streptomyces lavendulae, to confer mitomycin C resistance to both bacterial and mammalian cells by expression of the MCRA protein. Here we demonstrate that mcrA can be used as a selectable gene marker in Chinese hamster ovary cells when cells transfected with the mcrA gene are either pulsed or cultured continuously with mitomycin C This unique selection system may be of use for transfection of cells that are resistant to currently available selectable markers.     

Localized transfection on arrays of magnetic beads coated with PCR products

High-throughput gene analysis would benefit from new approaches for delivering DNA or RNA into cells. Here we describe a simple system that allows any molecular biology laboratory to carry out multiple, parallel cell transfections on microscope coverslip arrays. By using magnetically defined positions and PCR product-coated paramagnetic beads, we achieved transfection in a variety of cell lines. Beads may be added to the cells at any time, allowing both spatial and temporal control of transfection. Because the beads may be coated with more than one gene construct, the method can be used to achieve cotransfection within single cells. Furthermore, PCR-generated mutants may be conveniently screened, bypassing cloning and plasmid purification steps. We illustrated the applicability of the method by screening combinatorial peptide libraries, fused to GFP, to identify previously unknown cellular localization motifs. In this way, we identified several localizing peptides, including structured localization signals based around the scaffold of a single C2H2 zinc finger.     

Serum starvation improves transient transfection efficiency in differentiating embryonic stem cells

Control of genetic expression is a critical issue in the field of stem cell biology, where determining a cell fate or reprogramming adult somatic cells into pluripotent cells has become a common experimental practice. In turn, for these cells to have therapeutic clinical potential, techniques for controlling gene expression are needed that minimizes or eliminates the risk of oncogenesis and mutagenesis. Possible routes for achieving this outcome could come in the form of a transient nonviral gene delivery system. In this study, we improved the efficiency of transient gene delivery to differentiating murine embryonic stem (ES) cells via serum starvation for 3 days before transfection. The transient expression of a constitutively‐controlled plasmid increased from ～50% (replated control) to ～83% when transfected after 3 days of serum starvation but decreased to ～28% when transfected after 3 days in normal high serum‐containing media. When probed with a liver‐specific reporter, Cyp7A1, expression increased from ～1.4% (replated control) to ～3.7% when transfected after 3 days of serum starvation but decreased to ～0.7% when transfected after 3 days in high serum‐containing media. Cy3‐tagged oligonucleotides were used to rapidly quantify DNA uptake and predict ultimate transfection efficiency. This study suggests that modifications in media serum levels before transfection can have a profound effect on improving nonviral gene delivery. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Highly efficient transfection system for functional gene analysis in adult amphibian lens regeneration

The analysis of newt lens regeneration has been an important subject in developmental biology. Recently, it has been reported that the genes involved in the normal eye development are also expressed in the regenerative process of lens regeneration in the adult newt. However, functional analysis of these genes has not been possible, because there is no system to introduce genes efficiently into the cells involved in the regeneration. In the present study, lipofection was used as the method for gene transfer in cultured pigmented iris cells that can transdifferentiate into lens cells in newt lens regeneration. Positive expression of a reporter gene was obtained in more than 70% of cells. In addition, the aggregate derived from gene-transfected cells maintained its expression at a high level for a long time within the host tissue. To verify the effectiveness of this model system with a reporter gene in lens regeneration, Pax6, which is suggested to be involved in normal eye development and lens regeneration, was transfected. Ectopic expression of lens-specific crystallins was obtained in cells that show no such activity in normal lens regeneration. These results made it possible for the first time to analyze the molecular mechanism of lens regeneration in the adult newt.     

Efficiency of two different transfection reagents for use with human NTERA2 cells

The teratocarcinoma cell line NTERA2 is recently used in a wide range of researches (from developmental biology to toxicology, for their ability to be induced to neural differentiation. In order to study the genetic potential of these cells, it is needed to use methods for gene silencing and/or mRNA interference, allowing cell viability and further differentiation. To check these features, we simultaneously tested the transfection efficiency of NTERA2, A549 and HeLa cells with Metafectene PRO (Biontex, Germany) and another optimal transfection reagent currently used in our Laboratory, using as a reporter gene the DsRed2 vector (Clontech, Mountain View, CA). Under our culture conditions for NTERA2 and HeLa cells, Metafectene PRO transfection method was found to possess high throughput performance, that allows low concentration rate and low exposure time to excitation light source, thus reducing both toxicity and phototoxicity.     

Stable transfection of Eimeria tenella: constitutive expression of the YFP-YFP molecule throughout the life cycle

The obligate intracellular apicomplexan parasite Eimeria tenella, one of seven species of Eimeria that infect chickens, elicits protective cell-mediated immunity against challenge infection. For this reason, recombinant E. tenella parasites could be utilised as an effective vaccine vehicle for expressing foreign antigens and inducing immunity against heterologous intracellular microbes. A stable line of E. tenella expressing foreign genes is a prerequisite, and in this work an in vivo stable transfection system has been developed for this parasite using restriction enzyme-mediated integration (REMI). Two transgenic populations of E. tenella have been obtained that express YFP-YFP constitutively throughout the parasite life cycle. Southern blotting and plasmid rescue analyses show that the introduced exogenous DNA was integrated at random into the parasite genome. Although the life cycle of the transgenic populations was delayed by at least 12 h and the output of oocysts was reduced 4-fold relative to the parental BJ strain of E. tenella, the transgenic parasites were sufficiently immunogenic to protect chickens against challenge with either transgenic or parental parasites. These results are encouraging for the development of transgenic E. tenella as a vaccine vector and for more detailed investigation of the biology of the genus Eimeria.     

Graphene for improved femtosecond laser based pluripotent stem cell transfection

Pluripotent stem cells are hugely attractive in the tissue engineering research field as they can self‐renew and be selectively differentiated into various cell types. For stem cell and tissue engineering research it is important to develop new, biocompatible scaffold materials and graphene has emerged as a promising material in this area as it does not compromise cell proliferation and accelerates specific cell differentiation. Previous studies have shown a non‐invasive optical technique for mouse embryonic stem (mES) cell differentiation and transfection using femtosecond (fs) laser pulses. To investigate cellular responses to the influence of graphene and laser irradiation, here we present for the first time a study of mES cell fs laser transfection on graphene coated substrates. First we studied the impact of graphene on Chinese Hamster Ovary (CHO‐K1) cell viability and cell cytotoxicity in the absence of laser exposure. These were tested via evaluating the mitochondrial activity through adenosine triphosphates (ATP) luminescence and breakages on the cell plasma membrane assessed using cytosolic lactate dehydrogenase (LDH) screening. Secondly, the effects of fs laser irradiation on cell viability and cytotoxicity at 1064 and 532 nm for cells plated and grown on graphene and pure glass were assessed. Finally, optical transfection of CHO‐K1 and mES cells was performed on graphene coated versus plain glass substrates. Our results show graphene stimulated cell viability whilst triggering a mild release of intracellular LDH. We also observed that compared to pure glass substrates; laser irradiation at 1064 nm on graphene plates was less cytotoxic. Finally, in mES cells efficient optical transfection at 1064 (82%) and 532 (25%) nm was obtained due to the presence of a graphene support as compared to pristine glass. Here we hypothesize an up‐regulation of cell adhesion promoting peptides or laminin‐related receptors of the extracellular matrix (ECM) in cell samples grown and irradiated on graphene substrates. By bringing together advances in optics and nanomaterial sciences we demonstrate pathways for enhancement of pluripotent stem cell biology. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Electroporation by nucleofector is the best nonviral transfection technique in human endothelial and smooth muscle cells

BACKGROUND: The aim of this study was to determine the optimal non-viral transfection method for use in human smooth muscle cells (SMC) and endothelial cells (EC). METHODS: Coronary Artery (CoA) and Aortic (Ao) SMC and EC were transfected with a reporter plasmid, encoding chloramphenicol acetyltransferase type 1 (CAT), with seven different transfection reagents, two electroporation methods and a photochemical internalization (PCI) method. CAT determination provided information regarding transfection efficiency and total protein measurement was used to reflect the toxicity of each method. RESULTS: Electroporation via the nucleofector machine was the most effective method tested. It exhibited a 10 to 20 fold (for SMC and EC, respectively) increase in transfection efficiency in comparison to the lipofection method combined with acceptable toxicity. FuGene 6 and Lipofectamine PLUS were the preferred transfection reagents tested and resulted in 2 to 60 fold higher transfection efficiency in comparison to the PCI which was the least effective method. CONCLUSION: This study indicates that electroporation via the nucleofector machine is the preferred non-viral method for in vitro transfection of both human aortic and coronary artery SMC and EC. It may be very useful in gene expression studies in the field of vascular biology. Through improved gene transfer, non-viral transfer techniques may also play an increasingly important role in delivering genes to SMC and EC in relevant disease states.     

Effect of lysogeny on transfection and transfection enhancement in Bacillus subtilis.

Strains of Bacillus subtilis 168 lysogenic for bacteriophage phi105 transfer with deoxyribonucleic acid (DNA) isolated from bacteriophage SPO2 at a higher efficiency than non-lysogenic strains. This enhancement of transfection was not the result of recombination between bacteriophages SPO2 and phi105. Superinfection marker rescue increased transfection with DNA from bacteriophage phi105 occurred simultaneously with the addition of the transfecting DNA. Again, this enhancement of transfection was not the result of recombination but rather a protection of the transfecting DNA by the superinfecting bacteriophage. The ability of the superinfecting bacteriophage to protect the transfecting DNA from inactivation was maximal when the bacteria were just becoming competent. Bacteriophage phi1 cannot replicate after the transfection of competent bacteria lacking a functional DNA replication system, whereas bacteriophage phi1 was able to replicate after infection of competent bacteria grown under comparable conditions. These observations support the hypothesis that GAPase and an inducible repair system play an important role in the development of competence.     

Dendrimers in gene transfection

Dendrimers are a new class of nanocomposite materials. They are branching polymers whose structure is formed by monomeric subunit branches diverging to all sides from a central nucleus. The type of nucleus, attached monomers, and functional groups can be chosen during synthesis, which produces dendrimers of definite size, shape, density, polarity, branch mobility, and solubility. This review deals with problems of dendrimer molecular structures and capability of in vitro, in vivo, ex vivo, and in situ transfection of genetic material. Advantages and shortcomings of different types of dendrimers in this respect are discussed.     

Cost-effective gene transfection by DNA compaction at pH 4.0 using acidified,long shelf-life polyethylenimine

Introduction of genetic material into cells is an essential prerequisite for current research in molecular cell biology. Although transfection with commercially available reagents results in excellent gene expression, their high costs are obstacles to experimentation with a large number or large scales of transfection. The cationic polymer linear-polyethylenimine (MW 25,000) (PEI), one of the most cost-effective vehicles, facilitates DNA compaction by polyplex formation, which leads to efficient delivery of DNA into cells by endocytosis. However, the use of PEI is still limited because of substantial cytotoxicity and intolerable deterioration in transfection efficiency by its low stability. Here, we show that acidification of PEI is important for its transfection activity. Dissolving PEI powder in 0.2N HCl confers a long shelf-life for PEI storage at 4 and −80 °C, and the polyplex formation of plasmid DNA with PEI is optimized in lactate-buffered saline at pH 4.0. Furthermore, changing the culture medium at 8–12 h posttransfection can minimize the cytotoxicity of PEI without sacrificing the high transfection efficiency comparable to that of commercial reagents. The cost per test using acidified PEI is drastically reduced to approximately 1:10,000, compared with commercial reagents. Thus, we conclude that acidification of PEI satisfactorily accomplishes cost-effective, high-efficiency transfection.     

Bead transfection of adherent cells

Bead transfection is a simple, rapid, efficient, and cost-effective method of gene transfer into adherent mammalian cells. It involves a brief incubation of the cells with glass beads in a solution containing the DNA to be transferred. We have optimized this technique using COS-7 (an SV40 transformed monkey kidney cell line) and a transient expression assay for chloramphenicol acetyl transferase (CAT). Stable transfection efficiency assessed using the selectable marker gene neomycin phosphotransferase (NEO^R) was 27% in COS-7 cells. As this technique delivers high transfection efficiency with little manipulation of the exogenous DNA and does not require the use of any viral sequences, it may be a useful alternative method of gene delivery in the development of gene therapy protocols.     

Optimization of Babesia bovis transfection methods

The tick borne Babesia parasites remain an important limitation for development of cattle industries worldwide. A stable transfection of Babesia bovis will be useful for functional analysis of the recently sequenced B. bovis genome and to design improved methods to control Babesia infections. In this study, we describe a novel system for nucleofection of B. bovis infected erythrocytes and we optimize methods to introduce plasmids encoding the luciferase reporter gene into Babesia infected erythrocytes or free merozoites using either a BioRad GenePulser II electroporation system or nucleofection technology (Amaxa) A comparative study among four different transfection methods: transfection of infected erythrocytes and purified merozoites with 2 or 100 microg of plasmid, using electroporation (BioRad GenePulser II) or nucleofection (Amaxa) indicates that electroporation of infected erythrocytes with 100 microg of plasmid or nucleofection with 2 microg of plasmid are the most efficient ways to transfect B. bovis parasites. The data also indicate that nucleofection is more efficient than electroporation for transfecting small quantities of plasmids (2 microg range), whereas the inverse is true for transfection of larger quantities (100 microg range). This information will facilitate further development of efficient stable transfection systems.     

Transduction and transfection of difficult-to-transfect cells: Systematic attempts for the transfection of protozoa Leishmania

Cell-penetrating peptides (CPPs) are used to internalize different cargoes, including DNA, into live mammalian and plant cells. Despite many cells being easily transfected with this approach, other cells are rather “difficult” or “hard to transfect,” including protist cells of the genus Leishmania. Based on our previous results in successfully internalizing proteins into Leishmania tarentolae cells, we used single CPPs and three different DNA-binding proteins to form protein-like complexes with plasmids covered with CPPs. We attempted magnetofection, electroporation, and transfection using a number of commercially available detergents. While complex formation with negatively charged DNA required substantially higher amounts of CPPs than those necessary for mostly neutral proteins, the cytotoxicity of the required amounts of CPPs and auxiliaries was thoroughly studied. We found that Leishmania cells were indeed susceptible to high concentrations of some CPPs and auxiliaries, although in a different manner compared with that for mammalian cells. The lack of successful transfections implies the necessity to accept certain general limitations regarding DNA internalization into difficult-to-transfect cells. Only electroporation allowed reproducible internalization of large and rigid plasmid DNA molecules through electrically disturbed extended membrane areas, known as permeable membrane macrodomains.     

Serum-free transfection of CHO cells with chemically defined transfection systems and investigation of their potential for transient and stable transfection

The generation of transgenic cell lines is acquired by facilitating the uptake and integration of DNA. Unfortunately, most of the systems generating stable expression systems are cost and time-consuming and transient expression is optimized to generate milligram amounts of the recombinant protein. Therefore we improved and compared two transfection systems, one based on cationic liposomes consisting of DOTAP/DOPE and the second one on polyethylenimine (PEI). Both systems have been used as chemically defined transfection systems in combination with serum-free cultivated host cell line. At first we had determined the toxicity and ideal ratio of DNA to PEI followed by determination of the optimal transfection conditions in order to achieve maximum transfection efficiency. We then directly compared DOTAP/DOPE and PEI in transient transfection experiments using enhanced green fluorescence protein (EGFP) and a human monoclonal antibody, mAb 2F5, as a model protein. The results which were achieved in case of EGFP were more than 15% transfectants at a viability of 85%. Despite the fact that expression of the mAb was found negligible we used both techniques to generate stable mAb 2F5 expressing cell lines that underwent several cycles of screening and amplification with methotrexate, and resulted in cell lines with similar volumetric production titers. These experiments serve to demonstrate the potential of stable cell lines even in case where the transient systems did not show satisfying results.     

Efficient non-viral gene delivery mediated by nanostructured calcium carbonate in solution-based transfection and solid-phase transfection

Among different non-viral gene delivery methods, the technique of co-precipitation of Ca(2+) with DNA in the presence of inorganic anions is an attractive option because of the biocompatibility and biodegradability. In this study, nano-sized CaCO(3)/DNA co-precipitates for gene delivery were prepared. The effect of Ca(2+)/CO(3)(2-) molar ratio on the gene delivery was investigated. The mechanism of the transfection mediated by CaCO(3)/DNA co-precipitates was studied by treatment of the cells with chloroquine, wortmannin and cytochalasin D, respectively. The in vitro gene transfections in different cells were carried out for both solution-based transfection and solid-phase transfection. The gene expression of the calcium carbonate based approach is strongly affected by the Ca(2+)/CO(3)(2-) ratio because the size of CaCO(3)/DNA co-precipitates is mainly determined by the Ca(2+)/CO(3)(2-) ratio. In addition, the encapsulation efficiency of DNA increases with decreasing Ca(2+)/CO(3)(2-) ratio. With a suitable Ca(2+)/CO(3)(2-) ratio, CaCO(3)/DNA co-precipitates could effectively mediate gene transfection with the expression levels higher than that of Lipofectamine 2000 in the presence of serum. The mechanism study shows that CaCO(3)/DNA co-precipitates are internalized via endocytosis of the cells and macropinocytosis is the main route of internalization. Compared with the solution-based transfection, CaCO(3)/DNA co-precipitates in the solid-phase transfection exhibit a lower gene expression level. The calcium carbonate based approach has great potential in gene delivery.     

Stimulatory effect of polyethylene glycol (PEG) on gene expression in mouse liver following hydrodynamics-based transfection

BACKGROUND: Rapid intravenous injection of a large volume of plasmid DNA (pDNA), i.e. a transfection procedure based on hydrodynamics, is known to be an efficient and liver-specific method of in vivo gene delivery. However, the gene expression is transient. METHODS: We investigated the effect of addition of polyethylene glycol (PEG) to a solution of naked pDNA (luciferase) on the expression of the gene in mouse liver following transfection by the hydrodynamics-based technique. In addition, the mechanism leading to the enhancement of the gene expression was studied. RESULTS: The addition of 1% (w/v) PEG2000 to the pDNA solution enhanced the resulting gene expression in the liver. Increasing the PEG2000 concentration to more than 1 and up to 10% (w/v) rather diminished the gene expression level. By contrast, increasing the molecular weight of PEG to over 2000 up to 10 000 did not affect the level of gene expression. Histopathological and serum-chemistry examinations indicated that hydrostatic or osmotic pressure increased tissue and hepatocellular damage in a PEG-concentration-dependent manner, and resulted in a decrease in gene expression. Quantitative evaluation showed that the enhanced gene expression resulted from stabilization of the pDNA introduced into the hepatocytes and an enhancement of the transport of intact pDNA to the nucleus. CONCLUSIONS: For most gene therapy applications and gene function studies, sustained expression of the introduced gene(s) is necessary. This simple method to achieve enhanced gene expression in liver may have a great potential for a wide variety of laboratory studies in molecular and cellular biology as well as possibly for future clinical applications in humans.