Transfection of a DNA/protein complex into nuclei of mammalian cells using polyoma capsids and electroporation

We used empty capsids ofpolyoma virus to transfer DNA fragments and DNA/protein complexes into human cells. We encapsulated labeled and unlabeled single stranded DNA fragments by viral capsids. A complex of DNA with a DNA binding protein, recA, will also be taken up by the capsids, whereas the free protein is not incorporated. We further compared this gentle biological method of DNA transfection with a well-established physical method, electroporation. Electroporation also allows the transfer of DNA as well as protein into cells, although there is no proof that a DNA/protein complex can survive the procedure functionally. Whereas the viability of capsid transfected cells is unaffected (100%), electroporation reduces the viability to 90–95%. On the other hand, the amount of DNA found in the nucleus of electroporated cells is higher than for cells treated with loaded viral capsids.     

Electric shock-mediated transfection of cells. Characterization and optimization of electrical parameters.

The effect of various parameters on the electric shock-mediated permeabilization and transfection of CHO cells has been investigated. Up to 70% of the cells can be maintained transiently permeable to erythrosin B for periods of at least 1 h at 20 degrees C. Electrical conditions optimal for transient permeabilization were also optimal for efficient DNA transfection by pSV2neo. However, the DNA must be present during exposure to the electric field for efficient transformation. The same requirement existed for voltage-induced DNA toxicity. The results suggest that DNA moves into the cells by electrophoresis, not by simple diffusion. Based on these observations a simple, rapid procedure for optimizing the conditions for electric shock-mediated DNA transfer into cells has been developed.     

Purification of chloroplast DNA using hexadecyltrimethylammonium bromide

A simple and efficient method of extracting purified chloroplast DNA is described. Chloroplasts are isolated in a high-salt buffer, and lysed with hexadecyltrimethylammonium bromide. The DNA is extracted with chloroform and precipitated. This rapid procedure has been successful for a taxonomically diverse group of plants, and eliminates many of the time-consuming or expensive steps involved in other protocols. As a result, it may be a useful procedure to try prior to resorting to more complex alternatives.     

Baculovirus expression system for heterologous multiprotein complexes

The discovery of large multiprotein complexes in cells has increased the demand for improved heterologous protein production techniques to study their molecular structure and function. Here we describe MultiBac, a simple and versatile system for generating recombinant baculovirus DNA to express protein complexes comprising many subunits. Our method uses transfer vectors containing a multiplication module that can be nested to facilitate assembly of polycistronic expression cassettes, thereby minimizing requirements for unique restriction sites. The transfer vectors access a modified baculovirus DNA through Cre-loxP site-specific recombination or Tn7 transposition. This baculovirus has improved protein expression characteristics because specific viral genes have been eliminated. Gene insertion reactions are carried out in Escherichia coli either sequentially or concurrently in a rapid, one-step procedure. Our system is useful for both recombinant multiprotein production and multigene transfer applications.     

Polyhydroxybutyrate-enhanced transformation of log-phase Escherichia coli

Transformation of Escherichia coli plays an important role in recombinant DNA technology. Most current transformation protocols require that the cells be treated to attain a particular physiological state known as "competence," and this makes transformation procedures lengthy and arduous. Here we describe a protocol for transforming log-phase E. coli using dimethyl sulfoxide (DMSO) solutions of poly-(R)-3-hydroxybutyrate (PHB) to facilitate the transfer of plasmid DNA into cells, and certain reagents and temperature shocks to promote DNA uptake. The protocol was optimized using factorial design techniques across variables that included PHB molecular weight and concentration, DMSO concentration, monovalent and divalent salts, glucose, cold and heat shocks, cell density, and pH. Using 10 ng DNA, the optimized protocol produces approximately 1000 colony-forming units (CFUs) from 100 microL early log-phase cell culture or approximately 300 CFU from a 21-24 h single colony, sufficient for many applications. The total volume of the transformation reaction mixture is only 150 microL suggesting that the procedure may be adapted for use in microplates or automated transformation technologies.     

High cooperativity of the SV40 major capsid protein VP1 in virus assembly

SV40 is a small, non enveloped DNA virus with an icosahedral capsid of 45 nm. The outer shell is composed of pentamers of the major capsid protein, VP1, linked via their flexible carboxy-terminal arms. Its morphogenesis occurs by assembly of capsomers around the viral minichromosome. However the steps leading to the formation of mature virus are poorly understood. Intermediates of the assembly reaction could not be isolated from cells infected with wt SV40. Here we have used recombinant VP1 produced in insect cells for in vitro assembly studies around supercoiled heterologous plasmid DNA carrying a reporter gene. This strategy yields infective nanoparticles, affording a simple quantitative transduction assay. We show that VP1 assembles under physiological conditions into uniform nanoparticles of the same shape, size and CsCl density as the wild type virus. The stoichiometry is one DNA molecule per capsid. VP1 deleted in the C-arm, which is unable to assemble but can bind DNA, was inactive indicating genuine assembly rather than non-specific DNA-binding. The reaction requires host enzymatic activities, consistent with the participation of chaperones, as recently shown. Our results demonstrate dramatic cooperativity of VP1, with a Hill coefficient of approximately 6. These findings suggest that assembly may be a concerted reaction. We propose that concerted assembly is facilitated by simultaneous binding of multiple capsomers to a single DNA molecule, as we have recently reported, thus increasing their local concentration. Emerging principles of SV40 assembly may help understanding assembly of other complex systems. In addition, the SV40-based nanoparticles described here are potential gene therapy vectors that combine efficient gene delivery with safety and flexibility.     

Detection of circular and linear herpesvirus DNA molecules in mammalian cells by gel electrophoresis.

A simple gel technique is described for the detection of large, covalently closed, circular DNA molecules in eucaryotic cells. The procedure is based on the electrophoretic technique of Eckhardt (T. Eckhardt, Plasmid 1:584-588, 1978) for detecting bacterial plasmids and has been modified for the detection of circular and linear extrachromosomal herpesvirus genomes in mammalian cells. Gentle lysis of suspended cells in the well of an agarose gel followed by high-voltage electrophoresis allows separation of extrachromosomal DNA from the bulk of cellular DNA. Circular viral DNA from cells which carry the genomes of Epstein-Barr virus, Herpesvirus saimiri, and Herpesvirus ateles can be detected in these gels as sharp bands which comigrate with bacterial plasmid DNA of 208 kilobases. Epstein-Barr virus producer cell lines also show a sharp band of linear 160-kilobase DNA. The kinetics of the appearance of this linear band after induction of viral replication after temperature shift parallels the known kinetics of Epstein-Barr virus production in these cell lines. Hybridization of DNA after transfer to filters shows that the circular and linear DNA bands are virus specific and that as little as 0.25 Epstein-Barr virus genome per cell can be detected. The technique is simple, rapid, and sensitive and requires relatively low amounts of cells (0.5 X 10(6) to 2.5 X 10(6)).     

Simultaneous purification of DNA and RNA from small numbers of eukaryotic cells

An extraction procedure for the simultaneous isolation of RNA and DNA from tissue culture cells is described. The procedure is a variation of the guanidium/lithium chloride method for RNA isolation which is rapid, simple, and avoids costly ultracentrifugation equipment. The genomic DNA yielded by this procedure is greater than 50 kb in length and may be readily cleaved by restriction endonucleases. Sufficient DNA for Southern blot analysis, and RNA for Northern blot or nuclease protection analysis, can be obtained from as few as 2 x 10(6) cells, making this method particularly suitable for the genetic screening of large numbers of individual, stably transfected cell clones.     

Characterization of the functional sites in the oriT region involved in DNA transfer promoted by sex factor plasmid R100.

We have previously identified three sites, named sbi, ihfA, and sbyA, specifically recognized or bound by the TraI, IHF, and TraY proteins, respectively; these sites are involved in nicking at the origin of transfer, oriT, of plasmid R100. In the region next to these sites, there exists the sbm region, which consists of four sites, sbmA, sbmB, sbmC, and sbmD; this region is specifically bound by the TraM protein, which is required for DNA transfer. Between sbmB and sbmC in this region, there exists another IHF-binding site, ihfB. The region containing all of these sites is located in the proximity of the tra region and is referred to as the oriT region. To determine whether these sites are important for DNA transfer in vivo, we constructed plasmids with various mutations in the oriT region and tested their mobilization in the presence of R100-1, a transfer-proficient mutant of R100. Plasmids with either deletions in the sbi-ihfA-sbyA region or substitution mutations introduced into each specific site in this region were mobilized at a greatly reduced frequency, showing that all of these sites are essential for DNA transfer. By binding to ihfA, IHF, which is known to bend DNA, may be involved in the formation of a complex (which may be called oriT-some) consisting of TraI, IHF, and TraY that efficiently introduces a nick at oriT. Plasmids with either deletions in the sbm-ihfB region or substitution mutations introduced into each specific site in this region were mobilized at a reduced frequency, showing that this region is also important for DNA transfer. By binding to ihfB, IHF may also be involved in the formation of another complex (which may be called the TraM-IHF complex) consisting of TraM and IHF that ensures DNA transfer with a high level of efficiency. Several-base-pair insertions into the positions between sbyA and sbmA affected the frequency of transfer in a manner dependent upon the number of base pairs, indicating that the phasing between sbyA and sbmA is important. This in turn suggests that both oriT-some and the TraM-IHF complex should be in an appropriate position spatially to facilitate DNA transfer.     

Direct gene transfer to protoplasts: Fate of the transferred genes

Direct gene transfer to protoplasts is one of several methods developed for the production of transgenic plants. This method utilizes the efficient uptake of DNA from the surrounding medium by protoplasts (cell wall-less plant cells). Where a suitable protoplast system exists large numbers of transformant clones can be efficiently produced and often regenerated to normal fertile plants. This review concentrates on the fate of the DNA which is taken up into the protoplasts. Particular emphasis is given to the factors which can influence the integration and form of the transferred DNA, the expression of transferred genes, and the inheritance in further generations of those genes. The information available suggests (1) that DNA is taken up by a large proportion of the cells in a transformation mixture, (2) that this DNA forms complexes sometimes involving carrier DNA, (3) that fewer cells actually take up DNA into the nucleus, and (4) that the complex may be rearranged and/or amplified and then integrated into the genome. If the DNA is arranged in such a way that a gene can be expressed it does so in a normal manner and is stably inherited both mitotically and meiotically.     

Utilization of the Rhs core region of tc‐sepC orthologues as a degenerate system for the rapid amplification of insecticidal genes

We have developed a rapid procedure to identify the DNA sequence of candidate insecticidal genes belonging to the toxin complex (Tc) family. Using degenerate primers designed to the conserved core region of a component of the toxin complexes, we obtained consistent amplification of a ～910 bp DNA segment of the tc‐sepC gene from various bacterial genomes. This technique not only defines whether a putative insecticidal bacterium is a member of the Tc family, but will facilitate the isolation of neighbouring genes that may encode the full compliment of tc‐like genes.     

The chick embryo fibroblast cytosolic DNA complex--a possible cell-cell messenger

1. The uptake of [3H]thymidine and [3H]uridine labelled DNA-RNA cytosol complex has been studied in chick embryo fibroblast cells. 2. The complex appears to be cleaved into DNA and RNA containing fragments in the recipient cell nucleus: both then enter the cell cytosol fraction, but the RNA fragment in particular is rapidly degraded. 3. Although [3H]thymidine labelled material present in the nucleus co-extracts with bulk nuclear DNA, caesium gradienting shows little or no evidence that integration of host and imported DNA has occurred. 4. It is suggested that the cytosolic/extruded DNA complex may be a "messenger" DNA, capable of the transfer of regulatory information between cells on a transient basis.     

Alkaline transfer of DNA to plastic membrane

DNA forms a stable complex with Gene Screen Plus membrane at alkaline pH. Based on this, a method of alkaline transfer of DNA from agarose gel to Gene Screen Plus membrane was elaborated. The procedure entails the use of 0.4 M NaOH for both, the DNA denaturation and DNA transfer steps. The alkaline transfer offers a higher hybridization efficiency and simplifies the transfer procedure as compared with the standard method of DNA transfer at neutral pH. In addition, it can be used to remove RNA contamination from the transferred DNA.     

Conjugal transfer of chromosomal DNA contributes to genetic variation in the oral pathogen Porphyromonas gingivalis

Porphyromonas gingivalis is a major oral pathogen that contributes to the development of periodontal disease. There is a significant degree of genetic variation among strains of P. gingivalis, and the population structure has been predicted to be panmictic, indicating that horizontal DNA transfer and recombination between strains are likely. The molecular events underlying this genetic exchange are not understood, although a putative type IV secretion system is present in the genome sequence of strain W83, implying that DNA conjugation may be responsible for genetic transfer in these bacteria. In this study, we provide in vitro evidence for the horizontal transfer of DNA using plasmid- and chromosome-based assays. In the plasmid assays, Bacteroides-derived shuttle vectors were tested for transfer from P. gingivalis strains into Escherichia coli. Of the eight strains tested, five were able to transfer DNA into E. coli by a mechanism most consistent with conjugation. Additionally, strains W83 and 33277 tested positive for the transfer of chromosomally integrated antibiotic resistance markers. Ten chimeras resulting from the chromosomal transfer assay were further analyzed by Southern hybridization and were shown to have exchanged DNA fragments of between 1.1 and 5.6 kb, but the overall strain identity remained intact. Chimeras showed phenotypic changes in the ability to accrete into biofilms, implying that DNA transfer events are sufficient to generate measurable changes in complex behaviors. This ability to transfer chromosomal DNA between strains may be an adaptation mechanism in the complex environment of the host oral cavity.     

Internalization of isolated functional mitochondria: involvement of macropinocytosis

In eukaryotic cells, mitochondrial dysfunction is associated with a variety of human diseases. Delivery of exogenous functional mitochondria into damaged cells has been proposed as a mechanism of cell transplant and physiological repair for damaged tissue. We here demonstrated that isolated mitochondria can be transferred into homogeneic and xenogeneic cells by simple co‐incubation using genetically labelled mitochondria, and elucidated the mechanism and the effect of direct mitochondrial transfer. Intracellular localization of exogenous mitochondria was confirmed by PCR, real‐time PCR, live fluorescence imaging, three‐dimensional reconstruction imaging, continuous time‐lapse microscopic observation, flow cytometric analysis and immunoelectron microscopy. Isolated homogeneic mitochondria were transferred into human uterine endometrial gland‐derived mesenchymal cells in a dose‐dependent manner. Moreover, mitochondrial transfer rescued the mitochondrial respiratory function and improved the cellular viability in mitochondrial DNA‐depleted cells and these effects lasted several days. Finally, we discovered that mitochondrial internalization involves macropinocytosis. In conclusion, these data support direct transfer of exogenous mitochondria as a promising approach for the treatment of various diseases.     

DNA-mediated gene transfer without carrier DNA

DNA-mediated gene transfer is a procedure which uses purified DNA to introduce new genetic elements into cells in culture. The standard DNA-mediated gene transfer procedure involves the use of whole cell DNA as carrier DNA for the transfer. We have modified the standard DNA-mediated gene transfer procedure to transfer the Herpes simplex virus type 1 thymidine kinase gene (TK) into TK- murine recipient cells in the absence of whole cell carrier DNA. The majority (8/10) of carrier-free transformant lines expressed the TK+ phenotype stably, in sharp contrast to our results with carrier-containing DNA-mediated gene transfer. There was a wide range in donor DNA content among independent transformants. Further analysis on one transformant line using DNA restriction digests and in situ hybridization provided evidence that, in the absence of whole cell carrier DNA, multiple donor DNA sequences became integrated at a single chromosomal site.     

In Vitro Packaging of Adeno-Associated Virus DNA

We have developed an in vitro procedure for packaging of recombinant adeno-associated virus (AAV). By using AAV replicative-form DNA as the substrate, it is possible to synthesize an infectious AAV particle in vitro that can be used to transfer a marker gene to mammalian cells. The packaging procedure requires the presence of both the AAV Rep and capsid proteins. Two kinds of in vitro products can be formed which facilitate DNA transfer. Both are resistant to heat and have a density in cesium chloride gradients that is indistinguishable from that of the in vivo-synthesized wild-type virus. This indicates that the particles formed have the appropriate protein-to-DNA ratio and a structure that shares the heat resistance of mature AAV particles. The two types of particles can be distinguished by their sensitivity to chloroform and DNase I treatment. The chloroform-resistant product is, by several criteria, an authentic AAV particle. In addition to having the correct density and being resistant to treatment with chloroform, DNase I, and heat, this particle is efficiently synthesized only if the AAV genome contains intact terminal repeats, which are known to be required for AAV packaging. It is also precipitated by a monoclonal antibody that recognizes mature virus particles but not bound by an antibody that recognizes monomeric or denatured capsid proteins. The chloroform-resistant species is not made when aphidicolin is present in the reaction mixture, suggesting that active DNA replication is required for in vitro packaging. In contrast, the chloroform-sensitive product has several features that suggest it is an incompletely assembled virus particle. It is sensitive to DNase I, does not require the presence of AAV terminal repeats, and is capable of transferring DNA that is theoretically too large to package. Sucrose gradient centrifugation of the in vitro-synthesized products reveals that the particles have sedimentation values between 60S and 110S, which is consistent with partially assembled and mature AAV particles. The in vitro packaging procedure should be useful for studying the mechanism by which a human icosahedral DNA virus particle is assembled, and it may be useful for producing recombinant AAV for gene therapy. The chloroform-sensitive particle may also be useful for transferring DNA that is too large to be packaged in mature recombinant AAV.