High recombination rate of an Epstein-Barr virus-simian virus 40 hybrid shuttle vector in human cells

The stability of an Epstein-Barr virus (EBV)-simian virus 40 (SV40) hybrid shuttle vector, the p205-GTI plasmid, was analyzed in human cells during EBV- or SV40-type replication mode. When the p205-GTI plasmid was maintained as an episomal EBV vector in the human 293 cell line, no rearrangement was detected. To induce the SV40 replication mode, cells containing the episomal p205-GTI plasmid were either transfected with vectors carrying the T antigen gene or infected with SV40. Surprisingly, we observed both production and amplification of different classes of recombinant molecules. Particular types of modifications were found in most of the recombinants. The most striking rearrangement was a duplication of the promoter and enhancer regions of SV40 which was inserted in the thymidine kinase (TK) promoter. This recombination process involved a few bases of homology, and one of the recombination junctions implicated the GC boxes which constitute the essential components of the TK and SV40 early promoters. Our results suggest that a combination of a low level of base homology and a specific DNA sequence function (promoter and enhancer sites) leads to a very high level of recombinational activity during T-antigen-dependent plasmid replication.     

Histone acetylation and reactivation of Epstein-Barr virus from latency

Induction of the viral BZLF1 gene has previously been shown to be one of the first steps in the reactivation of Epstein-Barr virus (EBV). Using an EBV oriP episomal vector system, we have reconstituted the regulation of the promoter for BZLF1 on stably transfected episomes, mapped promoter elements required for that regulation, and investigated mechanisms that may control the switch between latency and the lytic cycle. Changes in histone acetylation at the promoter for the BZLF1 gene appear to be a key part of the reactivation mechanism of this herpesvirus.     

Development of a novel helper-dependent adenovirus-Epstein-Barr virus hybrid system for the stable transformation of mammalian cells

Epstein-Barr virus (EBV) episomes are stably maintained in permissive proliferating cell lines due to EBV nuclear antigen 1 (EBNA-1) protein-mediated replication and segregation. Previous studies showed the ability of EBV episomes to confer long-term transgene expression and correct genetic defects in deficient cells. To achieve quantitative delivery of EBV episomes in vitro and in vivo, we developed a binary helper-dependent adenovirus (HDA)-EBV hybrid system that consists of one HDA vector for the expression of Cre recombinase and a second HDA vector that contains all of the sequences for the EBV episome flanked by loxP sites. Upon coinfection of cells, Cre expressed from the first vector recombined loxP sites on the second vector. The resulting circular EBV episomes expressed a transgene and contained the EBV-derived family of repeats, an EBNA-1 expression cassette, and 19 kb of human DNA that functions as a replication origin in mammalian cells. This HDA-EBV hybrid system transformed 40% of cultured cells. Transgene expression in proliferating cells was observed for over 20 weeks under conditions that selected for the expression of the transgene. In the absence of selection, EBV episomes were lost at a rate of 8 to 10% per cell division. Successful delivery of EBV episomes in vivo was demonstrated in the liver of transgenic mice expressing Cre from the albumin promoter. This novel gene transfer system has the potential to confer long-term episomal transgene expression and therefore to correct genetic defects with reduced vector-related toxicity and without insertional mutagenesis.     

Construction of an EBNA-producing line of well-differentiated human hepatoma cells and of appropriate Epstein-Barr virus-based shuttle vectors

Using cloned Epstein-Barr nuclear antigen 1 (EBNA) and oriP elements from the Epstein-Barr virus (EBV) in conjunction with liver-specific growth media, we have constructed an EBNA-producing line of well-differentiated human hepatoma cells (Hep-EBNA-2) and appropriate EBV-oriP vectors. These vectors, pBEDC1 and pBEUG1, were maintained as free extrachromosomal elements only in cells that expressed the trans-acting EBNA protein. They were readily rescued from transfected Hep-EBNA-2 cells upon transformation of recA- Escherichia coli with cellular low-Mr DNA. They are true shuttle vectors in that they can propagate as free closed circular elements in both human Hep-EBNA-2 cells and E. coli. Finally, we have demonstrated the vector capability of our shuttle system by inserting into the SV40 expression cassette of pBEUG1 a large full-length cDNA encoding coagulation factor VIII. Our data clearly show that EBV-oriP episomes are able to stably propagate in an hepatic background and that neither high levels of EBNA protein nor multiple copy episomes significantly interfere with the expression of the set of hepatic functions that have been analyzed. These results are discussed in terms of gene amplification and cloning of genes that program liver differentiation.     

Expression of human erythropoietin cDNA in human lymphoblastoid Namalwa cells: the inconsistency of a stable expression level with transient expression efficiency

Recombinant plasmids for the expression of human erythropoietin (EPO) cDNA in Namalwa cells were constructed. From the results of the EPO expression efficiency in transiently transfected cells, it was found that the simian virus 40 (SV40) early promoter directs EPO synthesis more efficiently in Namalwa cells than does the long terminal repeat promoter of Rous sarcoma virus and that the 3'-noncoding sequence including splice junction and polyadenylation site derived from the rabbit beta-globin gene are more effective than those of the SV40 early gene. However, in stable transformants, no simple relationship was found between the expression level of EPO cDNA and the structure of the introduced expression vectors.     

Maintenance of Epstein-Barr virus-derived episomal vectors in the murine Sp2/0 myeloma cell line is dependent upon exogenous expression of human EBP2.

Vectors carrying the origin of replication (oriP) and driving expression of the EBNA-1 protein from Epstein-Barr virus (EBV) replicate as extrachromosomal episomes in human cells. Whether these vectors can be maintained as episomes in murine cells is still controversial. Here we demonstrate that EBNA-1 expression alone was unable to maintain episomal expression of an EBV-based vector in the murine Sp2/0 cell line. However, we were able to obtain long-term episome maintenance in Sp2/0 cells after exogenously expressing human EBP2 by genetic engineering. Our results provide further evidence for the fundamental role of human EBP2 in episomal maintenance of EBV-based vectors. Moreover, we demonstrate that EBV-based vectors can be successfully used in cells presumably incompetent for episomal maintenance.     

Demethylation and expression of methylated plasmid DNA stably transfected into HeLa cells.

In vitro methylation at CG dinucleotides (CpGs) in a transfecting plasmid usually greatly inhibits gene expression in mammalian cells. However, we found that in vitro methylation of all CpGs in episomal or non-episomal plasmids containing the SV40 early promoter/enhancer (SV40 Pr/E) driving expression of an antibiotic-resistance gene decreased the formation of antibiotic-resistant colonies by only approximately 30-45% upon stable transfection of HeLa cells. In contrast, when expression of the antibiotic-resistance gene was driven by the Rous sarcoma virus long terminal repeat or the herpes simplex virus thymidine kinase promoter, this methylation decreased the yield of antibiotic-resistant HeLa transfectant colonies approximately 100-fold. The low sensitivity of the SV40 Pr/E to silencing by in vitro methylation was probably due to demethylation upon stable transfection. This demethylation may be targeted to the promoter and extend into the gene. By genomic sequencing, we showed that four out of six of the transfected SV40 Pr/E's adjacent Sp1 sites were hotspots for demethylation in the HeLa transfectants. High frequency demethylation at Sp1 sites was unexpected for a non-embryonal cell line and suggests that DNA demethylation targeted to certain aberrantly methylated regions may function as a repair system for epigenetic mistakes.     

The gene S promoter of hepatitis B virus confers constitutive gene expression.

The properties of the promoter of the hepatitis B surface antigen (HBsAg) were studied using recombinants containing either this promoter or the SV40 early promoter. Mouse L cells were transfected with these recombinants and the levels of gene expression obtained with the two promoters were compared. The level of expression of a cellular gene, the human fibroblast interferon gene, obtained with the HBsAg promoter was comparable to that obtained with the SV40 early promoter. Similarly when the HBsAg gene was controlled by the SV40 early promoter the level of HBsAg synthesis is in the same range as that observed with its own promoter. Together these results suggest that although the HBsAg gene codes for a structural viral protein, its expression is constitutive as for an early gene. The implications of these observations on the synthesis of HBV particles in vivo are discussed.     

Vectors for efficient expression in mammalian fibroblastoid, myeloid and lymphoid cells via transfection or infection

We have constructed two related types of multi-cloning mammalian expression vectors. The first, pMPSVEH/HE, carries the promoter of the myeloproliferative sarcoma virus (MPSV). This promoter was found to be stronger than both the SV40 early and the trans-activated human immunodeficiency virus promoters in many cell lines including human and rodent fibroblastoid, lymphoid or myeloid cells. The other, pBEH/HE, carries the simian virus 40 (SV40) early promoter and origin of replication. This offers the possibility of encapsidation in SV40 pseudovirions and subsequent gene transfer into, e.g., hemopoietic cells, via infection. The usefulness of the expression systems was tested with a number of genes and cell lines.     

Stable expression of human tissue-type plasminogen activator regulated by beta-actin promoter in three human cell lines: HeLa, WI-38 VA13 and KMS-5

A high-level and stable expression system of human tissue-type plasminogen activator (t-PA) was accomplished in human cells by selecting a promoter and a host cell line. First, we have constructed two types of t-PA expression plasmids containing 3 kb of the human beta-actin promoter region or 0.3 kb of SV40 early promoter region and these plasmids were transfected into HeLa cells, respectively, and the resulting transfectants were found to secrete various amounts of t-PA derived from the plasmids to the culture media. Southern blot analysis revealed that the beta-actin promoter was more efficient than the SV40 early promoter with regard to the expression level per single copy of the t-PA gene in the transfected HeLa cells. Next, the t-PA expression plasmid containing the beta-actin promoter was also transfected into WI-38 VA13 cells, a human fibroblastic cell line, and KMS-5 cells, a human lymphoid cell line, in order to compare the expression ability of the promoter among these three cell lines. Some of the transfectants from both cell lines were also found to produce t-PA. It was also found that the expression levels in HeLa and WI-38 VA13 seemed to be more efficient than that in KMS-5.     

Long-term stability of large insert genomic DNA episomal shuttle vectors in human cells

We have constructed an episomal shuttle vector which can transfer large (>100 kb) human genomic DNA inserts back and forth between bacteria and human cells and which can be tracked in rapidly dividing human cells using a live cell assay. The vector (p5170) is based on the F factor-derived bacterial artificial chromosome cloning vector used in Escherichia coli, with the addition of the family of repeats element from the Epstein-Barr virus (EBV) latent origin of replication. This element provides nuclear retention in cells expressing the EBV protein EBNA-1. We have subcloned a series of genomic DNA inserts into p5170 and transfected the constructs into an EBNA-1(+) human cell line. Episomal mitotic stability was quantitatively analysed using flow cytometry. The episomes were also tracked by time course photography of expanding colonies. A 117 kb episome was retained at approximately 2 copies/cell and could be shuttled unrearranged from the human cells into bacterial cells after 15 months of continuous cell growth. Furthermore, the episome could still be rescued from human cells cultured in the absence of selection for 198 days. Such a trackable E.coli /human cell line shuttle vector system capable of carrying >100 kb of genomic DNA in human cells could prove a valuable tool in gene expression studies.