Improved EBV shuttle vectors

Shuttle vectors based on Epstein-Barr virus (EBV) replicate autonomously in the nuclei of human cells. These vectors represent reasonable models for chromosomes, have low background mutation frequencies, and have been useful for studying induced mutation in human cells. Two improvements in the EBV vector system are discussed. Attempts are described to increase vector copy number per cell by using a limited period of replication driven by the simian virus 40 (SV40) origin of replication. Isolation of human sequences that can replace the viral origin of replication in providing for autonomous replication of the vectors is also described. These improvements are leading toward shuttle vectors that are more efficient and more closely resemble authentic chromosomes.     

Amplification of Epstein-Barr virus-based shuttle vectors by ultraviolet light in human cells.

In order to approach the mechanism of gene amplification, we have developed a model system in human cells based on the use of episomally-replicating shuttle vectors. Shuttle vectors carrying the replication origin of the Epstein-Barr virus can be stably maintained in human cells. These vectors replicate as an episome with a low copy number. We also constructed hybrid plasmids containing both the EBV and the SV40 replication origins. These molecules are able to replicate episomally either like an EBV vector or like SV40 if the SV40 large T antigen is provided at the same time. UV irradiation of both human adenovirus transformed 293 or SV40-transformed MRC5 host cells leads to vector amplification whatever the type of replication origin used for the episomal maintenance. Our result clearly shows that the EBV latent replication origin (OriP), in the presence of the Epstein-Barr nuclear antigen-1 (EBNA-1) and the SV40 large T antigen, is sensitive to over-replication in UV-irradiated human cells. Since the UV doses were small enough to induce very little damage, if any, on the plasmid sequences, this amplification should be mediated through a cellular factor acting in trans. The interest in using shuttle vectors for this kind of study lays in the easy analysis of the amplified vectors in rescued bacterial colonies. The accuracy of the amplification process can be monitored by studying restriction maps of individual plasmid molecules or more precisely the integrity of a target gene, such as the lacZ' sequence, carried by our vectors.     

Differences in human cell lines to support stable replication of Epstein-Barr virus-based vectors

Vectors carrying the origin of replication, ori-P, of the Epstein-Barr virus (EBV) are maintained extrachromosomally in human cells expressing the EBV nuclear antigen 1 (EBNA-1). We have studied the EBV vectors p201 and p292 in which both ori-P and EBNA-1 functions are present using the human cell lines A431 and HeLa. The two lines showed differences in their transfectability by the EBV vectors. Thousands of HeLa transfectants were obtained with either vector and these remained intact as episomes. A431 could only be efficiently transfected with p292 and a high ratio of chromosomal integrations and rearrangements were observed. The vector p292 expressed the EBNA-1 gene more efficiently than p201 and this was found to be associated with a harmful effect on the grown of both HeLa and A431 lines. These results indicate that EBV vectors behave differently, depending on the cell line and that over-expression of EBNA 1 from these vectors may be detrimental to the cells.     

Analysis of mutation in human cells by using an Epstein-Barr virus shuttle system.

We developed highly sensitive shuttle vector systems for detection of mutations formed in human cells using autonomously replicating derivatives of Epstein-Barr virus (EBV). EBV vectors carrying the bacterial lacI gene as the target for mutation were established in human cells and later returned to Escherichia coli for rapid detection and analysis of lacI mutations. The majority of the clonal cell lines created by establishment of the lacI-EBV vector show spontaneous LacI- frequencies of less than 10(-5) and are suitable for studies of induced mutation. The ability to isolate clonal lines represents a major advantage of the EBV vectors over transiently replicating shuttle vectors (such as those derived from simian virus 40) for the study of mutation. The DNA sequence changes were determined for 61 lacI mutations induced by exposure of one of the cell lines to N-nitroso-N-methylurea. A total of 33 of 34 lacI nonsense mutations and 26 of 27 missense mutations involve G X C to A X T transitions. These data provide support for the mutational theory of cancer.     

The Functional Role of S/MARs in Episomal Vectors as Defined by the Stress-Induced Destabilization Profile of the Vector Sequences

The scaffold/matrix attachment regions (S/MARs) are chromosomal elements that participate in the formation of chromatin domains and have origin of replication support functions. Because of all these functions, in recent years, they have been used as part of episomal vectors for gene transfer. The S/MAR of the human β-interferon gene has been shown to support efficient episome retention and transgene expression in various mammalian cells. In Jurkat and other cells, DNA plasmid vectors containing Epstein-Barr virus origin of replication (EBV OriP) and the EBV nuclear antigen-1 gene mediate prolonged episome retention in the host cell nucleus, which, however, diminishes over time. In order to enhance retention, we combined this system with an S/MAR element. Unexpectedly, this completely eliminated the capacity of episomes to replicate. Calculation of the stress-induced DNA duplex destabilization profile of the vectors suggested that the S/MAR element had created an increase in molecular stability at the OriP site that may have disturbed replicative potential. In contrast, introduction of an alternative initiation of replication region from the β-globin gene locus, instead of EBV OriP and the EBV nuclear antigen-1 gene, restored replicative capacity and enhanced episome retention mediated by the S/MAR. These effects were associated with a destabilization profile at the initiation of replication region. These data demonstrate a correlation between S/MAR-mediated vector retention and the presence of an unstable duplex at a replication origin, in this particular setting. We consider that the calculation of stress-induced duplex destabilization may be an informative first step in the design of units that replicate extrachromosomally, particularly as the latter present a safer and, therefore, attractive alternative to integrating viral vectors for gene therapy applications.     

Use of simian virus 40 replication to amplify Epstein-Barr virus shuttle vectors in human cells.

We have increased the copy number of Epstein-Barr virus vectors that also carry the origin of replication of simian virus 40 (SV40) by providing a transient dose of SV40 T antigen. T antigen was supplied in trans by transfection of a nonreplicating plasmid which expresses T antigen into cells carrying Epstein-Barr virus-SV40 vectors. A significant increase in vector copy number occurred over the next few days. We also observed a high frequency of intramolecular recombination when the vector carried a repeat segment in direct orientation, but not when the repeat was in inverted orientation or absent. Furthermore, by following the mutation frequency for a marker on the vector after induction of SV40 replication, it was determined that SV40 replication generates a detectable increase in the deletion frequency but no measurable increase in the frequency of point mutations.     

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.     

Construction of Epstein-Barr virus-based expression vector containing mini-oriP.

Epstein-Barr virus (EBV)-based vectors are extrachromosomal vectors carrying a replicational origin, oriP (about 2200 bp) and a replication initiation factor (EBNA-1) which are sufficient for autonomous replication. Because one disadvantage of these vectors is their large sizes, we examined the effect of partial deletion of oriP on the effectiveness of the EBV-based vectors, using an enhanced green fluorescent protein (EGFP) as a reporter to monitor gene expression. Results indicated that 954 bp-deleted mini-oriP is useful in primate cells since the vector showed high efficiency of stable transfection, a high ratio of EGFP-positive cells, and high recovery of intact plasmid DNA from transfected cells.     

Epstein-Barr virus vectors provide prolonged robust factor IX expression in mice

We demonstrate that vectors incorporating components from Epstein-Barr virus (EBV) for retention and from human genomic DNA for replication greatly enhance the level and duration of marker gene expression in dividing cultured cells. The same types of vectors were tested in vivo by high-pressure tail vein injection of naked DNA in mice, resulting in liver delivery and expression. The therapeutic gene was a human factor IX (hFIX) minigene comprising genomically derived 5', 3', and intronic sequences that provided relatively good gene expression in vivo. We demonstrated that addition of the EBV EBNA1 gene and its family of repeats binding sites provided a 10- to 100-fold increase in prolonged hFIX expression in mouse liver. A single 25-microg dose of vector DNA generated normal (>5 microg/mL) levels of hFIX throughout the 8 month duration of the experiment. Vector DNA with or without the EBV sequences was retained in liver cells, and vector replication was not a factor in these nondividing liver cells. Instead, it appears that enhancement of stable hFIX expression by the EBV components was responsible for the increased level and duration of therapeutic gene expression. The EBV sequences also significantly enhanced stable expression of a vector carrying the full genomic hFIX gene delivered to mouse liver. These results underline the crucial importance of appropriate gene expression signals on gene therapy vectors and the utility of EBV sequences in particular for increasing stable gene expression.     

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.     

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.     

An efficient gene transfer system for hematopoietic cell line using transient and stable vectors

The hematopoietic system represents an interesting model for gene transfer protocols. Here, we have evaluated the efficiency of a gene transfer system using the polycationic compound SuperFect (Qiagen) and the K562 hematopoietic cell line. Transient and stable vectors carrying the enhanced green fluorescent protein (EGFP) reporter gene were employed. The stable vector was constructed based on Epstein-Barr virus sequences such as EBV oriP (origin of replication) and EBNA (EBV nuclear antigen)-1, both for DNA replication. The transfection efficiency of the viable cells was estimated by flow cytometry at approximately 98% for transient and stable vectors. Transiently transfected cells presented optimal EGFP expression until day 2 when fluorescence started to decrease. In contrast, stable transfectants continuously expressed the marker gene product for 10 weeks in the presence of G418. Our results represent an efficient gene transfer method for K562 hematopoietic cells and may be used as an alternative approach for further gene transfer studies involving hematopoietic cells.     

Packaging Cells Based on Inducible Gene Amplification for the Production of Adeno-Associated Virus Vectors

Although vectors based on adeno-associated virus (AAV) offer several unique advantages, their usage has been hampered by the difficulties encountered in vector production. In this report, we describe a new AAV packaging system based on inducible amplification of integrated helper and vector constructs containing the simian virus 40 (SV40) replication origin. The packaging and producer cell lines developed express SV40 T antigen under the control of the reverse tetracycline transactivator system, which allows inducible amplification of chromosomal loci linked to the SV40 origin. Culturing these cells in the presence of doxycycline followed by adenovirus infection resulted in helper and vector gene amplification as well as higher vector titers. Clonal producer cell lines generated vector titers that were 10 times higher than those obtained by standard methods, with approximately 10⁴ vector particles produced per cell. These stocks were free of detectable replication-competent virus. The lack of a transfection step combined with the reproducibility of stable producer lines makes this packaging method ideally suited for the large-scale production of vector stocks for human gene therapy.     

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.     

Protein blotting: principles and applications

Extensive studies on the DNA tumor virus Simian Virus 40 (SV40) have provided a wealth of information regarding the genome organization, regulation of viral gene expression, and the mechanism of DNA replication. SV40 can grow lytically in permissive monkey cells or the viral DNA can integrate into the host genome of nonpermissive rodent cells causing morphological transformation. The viral DNA exists as a minichromosome within the nuclei of lytically infected cells and, as a consequence of DNA replication, there is a significant amplification of the viral genome during infection. These properties suggested that SV40 could be developed as a transducing vector to introduce exogenous DNA into mammalian cells and to express this foreign DNA during the SV40 infectious cycle. In this article the properties of SV40 virus vectors and SV40 hybrid plasmid vectors are described and contrasted.     

The affinity of EBNA1 for its origin of DNA synthesis is a determinant of the origin's replicative efficiency

Epstein-Barr virus (EBV) replicates its genome as a licensed plasmid in latently infected cells. Although replication of this plasmid is essential for EBV latent infection, its synthesis still fails for 16% of the templates in S phase. In order to understand these failures, we sought to determine whether the affinity of the initiator protein (EBNA1) for its binding sites in the origin affects the efficiency of plasmid replication. We have answered this question by using several engineered origins modeled upon the arrangement of EBNA1-binding sites found in DS, the major plasmid origin of EBV. The human TRF2 protein also binds to half-sites in DS and increases EBNA1's affinity for its own sites; we therefore also tested origin efficiency in the presence or absence of these sites. We have found that if TRF2-half-binding sites are present, the efficiency of supporting the initiation of DNA synthesis and of establishing a plasmid bearing that origin directly correlates with the affinity of EBNA1 for that origin. Moreover, the presence of TRF2-half-binding sites also increases the average level of EBNA1 and ORC2 bound to those origins in vivo, as measured by chromatin immunoprecipitation. Lastly, we have created an origin of DNA synthesis from high-affinity EBNA1-binding sites and TRF2-half-binding sites that functions severalfold more efficiently than does DS. This finding indicates that EBV has selected a submaximally efficient origin of DNA synthesis for the latent phase of its life cycle. This enhanced origin could be used practically in human gene vectors to improve their efficiency in therapy and basic research.     

Tamplicon-7, a Novel T-Lymphotropic Vector Derived from Human Herpesvirus 7

We describe the derivation of a novel T-cell-defective virus vector employing the human herpesvirus 7 (HHV-7). The new vector, designated Tamplicon-7, replicates in CD4(+) T cells. The system is composed of a helper virus and defective virus genomes derived by the replication of the input Tamplicon vector. There are two cis-acting functions required for the replication and packaging of the defective virus genomes in the presence of the helper virus: the viral DNA replication origin and the composite cleavage and packaging signal, which directs the cleavage and packaging of defective virus genomes. Viral DNA replication is compatible with the rolling circle mechanism, producing large head-to-tail concatemers of the Tamplicon vector. Thus, in the presence of the helper virus, the replicated vectors are packaged and secreted into the medium. Furthermore, we have shown that the vector can be employed to express a foreign gene, encoding the green fluorescent protein, in the T cells infected with the HHV-7 helper virus. We predict that the Tamplicon-7 vector might be potentially useful for gene therapy of diseases affecting the human CD4(+) T cells, including autoimmune diseases, T-cell lymphomas, and AIDS.     

New host cell system for regulated simian virus 40 DNA replication.

Transformed monkey cell lines (CMT and BMT) that inducible express simian virus 40 (SV40) T antigen from the metallothionein promoter have been isolated and characterized. Immunoprecipitation of pulse-labeled T antigen demonstrates a 5- to 12-fold increase in the rate of synthesis on addition of heavy-metal inducers to the culture medium. Radioimmunoassay of cell extracts indicates the accumulation of three- to fourfold more total T antigen after 2 days of induction by comparison with uninduced controls. A direct correlation was found between the level of T-antigen synthesis and the extent of SV40 DNA replication in inducible cells. Inducible BMT cells expressing a low basal level of T antigen were efficiently transformed by a vector carrying the neomycin resistance marker and an SV40 origin of replication. These vector sequences were maintained in an episomal form in most G418-resistant cell lines examined and persisted even in the absence of biochemical selection. Extensive rearrangements were observed only if the vector contained bacterial plasmid sequences. Expression of a protein product under the control of the SV40 late promoter in such vectors was increased after heavy-metal-dependent amplification of the template. These results demonstrate the ability of BMT cells to maintain a cloned eucaryotic gene in an amplifiable episomal state.