The use of site-directed mutagenesis, transient transfection, and radioligand binding

Receptor-ligand interactions have traditionally been evaluated using a number of biochemical techniques including radioligand binding, photoaffinity labeling, crosslinking, and chemical modification. In modern biochemistry, these approaches have largely been superseded by site-directed mutagenesis in the study of protein function, owing in part to a better understanding of the chemical properties of oligonucleotides and to the ease with which mutant clones can now be generated. The Altered Sites II in vitro Mutagenesis System from the Promega Corporation employs oligonucleotides containing two mismatches to introduce specific nucleotide substitutions in the nucleic acid sequence of a target DNA. One of these mismatches will alter the primary sequence of a given protein, whereas the second will give rise to a silent restriction site that is used to screen for mutants. Transient transfection of tsA201 cells with mutant cDNA constructs using calcium phosphate as a carrier for plasmid DNA permits expression of recombinant receptors that can be characterized using radioligand binding assays. In this article, we focus on site-directed mutagenesis, heterologous expression in eukaryotic cells, and radioligand binding as a methodology to enable the characterization of receptor-ligand interactions.     

Gene transfection of multicellular spheroid of hepatocytes on an artificial substrate

The handling of hepatocytes, a major cell population in the liver, is an important technique in both liver tissue engineering and hepatology. However, these cells are so fragile that it has been impossible to harvest hepatocytes with high viability from tissue culture dishes after a period of culture in vitro. In this study, we employed an artificial substrate for transfection of multilayer hepatocytes and harvested these cells with high viability after transfection. Hepatocytes cultured on an amphiphilic artificial substrate form multilayer aggregates (spheroids) in the presence of growth factors during gene transfection with cation liposomes. Compared to cells cultured on a collagen-coated plate, these spheroids are easily harvested with high viability by pipetting in EDTA solution. In addition, these spheroids rapidly spread on collagen after transfer from the artificial substrate, demonstrating that hepatocytes in the center of the spheroids were viable. Epidermal growth factor (EGF) increased the transfection efficiency into hepatocytes while hepatocyte growth factor (HGF) alone did not increase the efficiency. However, HGF synergestically increased the effect of EGF on transfection. Interestingly, this transfection required the process of spheroid formation because the gene was not transfected once the spheroid formation completed or under conditions where hepatocytes did not form spheroids. This method using spheroidal hepatocytes for in vitro transfection is promising for the development of ex vivo gene therapy.     

Optimization of transient gene expression in mammalian cells and potential for scale-up using flow electroporation

The goals of this study were to identify mammalian cell lines which could be efficiently transiently-transfected and scaled-up for protein production. The transfection efficiencies of eight cell lines (NSO, NSO-TAg, CV-1, COS-7, CHO, CHO-TAg, HEK 293, and 293-EBNA) were measured using electroporation for DNA delivery and green fluorescent protein (Evans, 1996) as the reporter gene. In addition, we have evaluated the effects of stable expression of viral proteins, cell cycle manipulation, and butyrate post-treatment in small scale experiments. The cell lines varied widely in their GFP transfection efficiencies. Stable expression of simian virus 40 large T-antigen or Epstein Barr nuclear antigen failed to significantly increase transfection efficiency above that seen in the parental lines. Aphidicolin (a DNA polymerase inhibitor), which blocked cells from S or G2/M, brought about an increase in transfection efficiency in two cell lines. The primary effect of butyrate (a histone deacetylase inhibitor) post-treatment was an increased intensity of the fluorescent signal of green fluorescent protein, as measured by flow cytometry (1.0 to 4.2-fold, depending on the cell line). The combined use of aphidicolin pretreatment followed by butyrate treatment post- electroporation yielded increases in fluorescence intensities ranging from 0.9 to 6.8-fold. Based on their high transfection efficiencies in small scale experiments, rapid growth, and ability to grow in suspension culture, CHO, CHO-TAg, and 293-EBNA were selected to assess the feasibility of using flow electroporation for large-scale transfections. Using secreted placental alkaline phosphatase as a reporter, 293-EBNA cells produced the highest protein levels in both the presence and absence of butyrate. These data indicate that flow electroporation provides an efficient method of DNA delivery into large numbers of cells for mammalian protein production. This revised version was published online in August 2006 with corrections to the Cover Date.     

Intracellular fate of liposome-encapsulated DNA in mouse liver. Analysis using electron microscope autoradiography and subcellular fractionation

Transient expression of liposome-encapsulated DNA in liver after intravenous injection to rats and mice has raised questions concerning the intracellular fate of this DNA. Electron microscope autoradiography shows that at 10 min after injection the highest concentration of liposomal DNA which is taken up by the liver is associated with lysosomes and vesicles. The proportion of DNA associated with the mitochondria steadily increases for 1 h after injection, up to 48% of the exogenous DNA found in the tissue. Part of this DNA follows the subcellular fractionation profile of the mitochondrial matrix marker, malate dehydrogenase. In contrast, 14% of the liposomal DNA taken up by the liver is found in the nuclei at 3 min after injection, and this percentage decreases over a period of 1 h. These results permit us to establish the distribution of liposome-encapsulated DNA among subcellular organelles in liver at different times after injection.     

TNFalph 和 IL-1bet 靶点抗炎药物筛选细胞模型的构建

目的:构建两个高表达人TNFα和IL-1β细胞系,建立抗炎药物筛选细胞模型。方法:运用PCR的方法从载体pCMVSport-TNFα和p CMVSport-IL1β上扩增目的基因,以亚克隆方法将目的基因分别插入真核表达载体pcDNA3.1和pFLAG-CMV中,用单酶切、PCR扩增和基因测序的方法鉴定重组效果,然后将重组成功的质粒转入HEK293细胞系内,挑选能够稳定表达并遗传的单克隆细胞株,用蛋白免疫印迹(Western blot)法分析其表达效果。结果:三种鉴定方法均显示重组质粒构建成功。Western blot结果显示,细胞株T3、T4均能较高表达炎症因子TNF-α;细胞株I2、I3、I5均能较高表达炎症因子IL-1β。结论:成功构建了TNFα和IL-1β靶标的药物筛选细胞模型,为筛选具有抗炎作用的中药提供了一个新平台。     

Effect of chitosan‐alginate nanoparticles and ultrasound on the efficiency of gene transfection of human cancer cells

Background

Gene therapy has been used to treat a variety of health problems, but transfection inefficiency and the lack of safe vectors have limited clinical progress. Fabrication of a vector that is safe and has high transfection efficiency is crucial for the development of successful gene therapy. The present study aimed to synthesize chitosan‐alginate nanoparticles that can be used as carriers of the pAcGFP1‐C1 plasmid and to use these nanoparticles with an ultrasound protocol to achieve high efficiency gene transfection.

Methods

Chitosan was complexed with alginate and the pAcGFP1‐C1 plasmid at different charge ratios to create chitosan‐alginate‐DNA nanoparticles (CADNs). The average particle size and loading efficiency were measured. Plasmid DNA retardation and integrity were analysed on 1% agarose gels. The effect of CADNs and ultrasound on the efficiency of transfection of cells and subcutaneous tumors was evaluated.

Results

In the CADNs, the average size of incorporated plasmid DNA was 600–650 nm and the loading efficiency was greater than 90%. On the basis of the results of the plasmid DNA protection test, CADNs could protect the transgene from DNase I degradation. The transgene product expression could be enhanced efficiently if cells or tumor tissues were first given CADNs and then treated with ultrasound.

Conclusions

The use of CADNs combined with an ultrasound regimen is a promising method for safe and effective gene therapy. Copyright © 2009 John Wiley & Sons, Ltd.

     

Surface adsorption of protein corona controls the cell internalization mechanism of DC-Chol-DOPE/DNA lipoplexes in serum

Serum has often been reported as a barrier to efficient lipid-mediated transfection. Here we found that the transfection efficiency of DC-Chol-DOPE/DNA lipoplexes increases in serum. To provide insight into the mechanism of lipoplex-serum interaction, several state-of-the-art methodologies have been applied. The nanostructure of DC-Chol-DOPE/DNA lipoplexes was found to be serum-resistant as revealed by high resolution synchrotron small angle X-ray scattering, while dynamic light scattering measurements showed a marked size increase of complexes. The structural stability of DC-Chol-DOPE/DNA lipoplexes was confirmed by electrophoresis on agarose gel demonstrating that plasmid DNA remained well protected by lipids. Proteomics experiments showed that serum proteins competed for the cationic surface of lipid membranes leading to the formation of a rich a ‘protein corona’. Combining structural results with proteomics findings, we suggest that such a protein corona can promote large aggregation of intact lipoplexes. According to a recently proposed size-dependent mechanism of lipoplex entry within cells, protein corona-induced formation of large aggregates most likely results in a switch from a clathrin-dependent to caveolae-mediated entry pathway into the cells which is likely to be responsible for the observed transfection efficiency boost. As a consequence, we suggest that surface adsorption of protein corona can have a high biological impact on serum-resistant cationic formulations for in vitro and in vivo lipid-mediated gene delivery applications.