SV40-based Escherichia coli shuttle vectors infectious for monkey cells

Use of an infectious Simian virus 40-based shuttle vector to analyse UV-induced mutagenesis in monkey cells

SV40 based shuttle vectors able to be packaged as pseudovirions have been used either as naked DNA or as pseudovirus to analyse the mutation frequency and the UV-induced mutation spectra obtained after transfection or infection of COS7 monkey cells. The frequency of supF spontaneous mutants was similar whatever the state of the vector, indicating that the transfection step is not responsible for the high spontaneous mutation frequency when using shuttle vectors. Nevertheless the UV-induced mutation frequency of the supF gene was higher when transfected DNA was replicated into COS7 cells than when pseudovirus infection was performed. The UV induced mutation spectra was basically similar in both situations but a new hot-spot at nucleotide 110 was obtained after pseudovirus infection. UV-pretreated and control COS7 cells were infected with untreated or UV-damaged pi SVPC7 shuttle virus and the survival and the supF mutation frequency were analysed in the progeny. The survival of UV-damaged pseudovirus replicated in 10 J/m2 UV-pretreated cells was 2-fold higher than in untreated cells. This increase in the survival was accompanied by a slight enhancement in the number of supF mutants.

Molecular analysis of DNA junctions produced by illegitimate recombination in human cells

In a human HeLa derived-cell line carrying permanently a single integrated copy of an SV40 shuttle vector, the transient expression of the SV40 T-antigen led to the production of heterogeneous populations of circular DNA molecules which retained both integrated vector and its surrounding cellular sequences. Comparison between the integrated copy and the linear maps of 80 different plasmids rescued in bacteria suggested that the formation of circular DNA was the result of bidirectional replication from the SV40 origin of replication followed by a single intramolecular joining leading to the cyclization of the replicated molecules. Sequence analysis of 45 recombinational junctions demonstrated that the cyclization occurred via illegitimate recombination process which did not require preferential nucleotide sequence at the joining sites. However, extensive characterization of recombination junctions revealed that the sequences involved in the recombination at each side of the SV40 origin of replication were not randomly distributed, suggesting the presence of regions which were more prone to be involved in the illegitimate recombination process in human cells. Search of common features usually implied in illegitimate recombination in mammalian cells revealed some association of these regions with palindromes, A + T-rich DNA segments, alternating purine/pyrimidine sequences and Alu family repeats.

Singlet oxygen induced DNA damage and mutagenicity in a single-stranded SV40-based shuttle vector

The effects of singlet oxygen (1O2), generated by the thermal decomposition of water soluble NDPO2 (endoperoxide of the disodium 3,3'-(1,4-naphthylidene) dipropionate), on a single-stranded shuttle vector were analysed. 1O2 induces a much higher level of breaks in the phosphodiester backbone of single-stranded than double-stranded DNA. This may be due to a higher accessibility of guanine residue, primarily damaged by 1O2. The damaged vector was transfected into monkey COS7 cells where single-stranded DNA was converted to the double-stranded replicative form DNA. After 3 days, extrachromosomal DNA was extracted and the plasmids rescued in E. coli to study mutagenesis. There is a significant increase in mutation frequency of damaged single-stranded DNA in comparison to untreated DNA. It is concluded that 1O2 induces breaks in the backbone of single-stranded DNA and that the 1O2-damaged molecules are mutated after passage through mammalian cells.

Comparison of spontaneous and ultraviolet-induced mutagenesis on naked SV40 DNA and SV40 virus

Molecular aspects of mutagenesis in mammalian cells have been essentially analyzed using biological probes such as viruses and shuttle vectors. Although the main data concerning the specificity of carcinogen-induced mutations are similar, the observed spontaneous mutation frequencies are significantly different when using one or the other model. This frequency is considerably higher with shuttle vectors than with viruses. We have performed an analysis of mutagenesis in order to determine if the obligatory transfection step associated with shuttle vector technology was responsible for the high mutation frequency found with these molecules. For this purpose simian virus 40 (SV40) genome used as virus or as naked DNA was introduced into permissive cells by viral infection or DNA transfection respectively. Our results show that transfection alone does not induce a higher mutation frequency on SV40 DNA than virus infection. Moreover, we have shown that the ultraviolet-light induced mutation spectrum was similar on the SV40 VP1 gene after viral infection or DNA transfection.

Polyomavirus-based shuttle vectors for studying mechanisms of mutagenesis in rodent cells

We have constructed a series of polyomavirus-based shuttle vectors for analyzing mechanisms of mutagenesis in rodent cell systems. These vectors contain the supF suppressor tRNA gene which serves as the mutagenesis target; the pBR327 replication functions and ampr gene for replication and selection in bacteria; and the polyomavirus genome which permits replication in rodent cells. The polyoma genomes used in these vectors vary in their enhancer regions, causing varying efficiencies of replication in different types of rodent cells. One of the vectors (pPySLPT-2) which replicates particularly well in several different rodent cell types (i.e., Chinese hamster ovary, mouse hepatoma and mouse lymphoma) was used to compare mutation induction by UV radiation in UV repair-deficient mouse lymphoma L5178Y-R cells with mutagenesis in the related UV repair-proficient line, L5178Y-S. In both cell types, UV-induced mutants could be recovered at frequencies up to 50-fold higher than that of the spontaneous background. At a given UV fluence the L5178Y-R cells were more highly mutable than the L5178Y-S cells. Our results indicate that these new polyomavirus-based vectors should be useful for analysis of the molecular mechanisms of mutation induction in rodent cell systems, and in particular should allow detailed analysis of mutagenesis in the well characterized rodent somatic cell mutants.

Singlet molecular oxygen induced mutagenicity in a mammalian SV40-based shuttle vector

We have determined the deleterious effects of singlet oxygen (1O2), generated by thermal decomposition of the water-soluble endoperoxide 3,3'-(1,4-naphthylidene)dipropionate (NDPO2), on plasmid DNA. By following the electrophoretic mobility of DNA on agarose gels, we detected single and double strand breaks induced by treatment with NDPO2. The vector employed was a mammalian shuttle vector and the mutagenic consequences of these damages were investigated, using as mutation target the supF suppressor tRNA gene. A high increase of the mutation frequency, over the background, was observed in plasmids transfected in bacteria or after passage through mammalian cells. Trapping agents and quencher effects and other controls confirm the involvement of 1O2 in DNA damage and mutagenicity. These findings indicate that 1O2 can induce DNA lesions which are repaired by an error-prone process in prokaryotic and eukaryotic cells.

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.

Shuttle vectors for studying mutagenesis in mammalian cells

Shuttle vectors are DNA plasmids able to replicate in both mammalian cells and bacteria. They have been used to examine rapidly various aspects of DNA repair, recombination and mutagenesis. Three main classes of shuttle vector have been developed. The transiently replicating vectors are usually based on Simian Virus 40 replication origin. The episomal vectors based on the Epstein-Barr virus replication replicate almost permanently in host cells. Different biological systems, including retroviral vectors, allow the integration of a target gene into the chromosomal structure of the infected cells. In all cases, low molecular weight DNA can be recovered from mammalian cells and shuttled back to bacteria for mutagenesis screening. The advantages and disadvantages of these different types of shuttle vectors are discussed with a special emphasis on their use for a rapid analysis of mutation spectra in mammalian cells.

From simian virus 40 to transient shuttle vectors in mutagenesis studies

Exogenous DNA probes are frequently used to study mutagenesis in mammalian cells. Experimental protocols utilizing simian virus 40 (SV40) and transient shuttle vectors able to replicate in mammalian cells as well as in bacteria are described. The main interests and the limits of the 2 genetic assays are discussed from results obtained with both systems. Despite some minor discrepancies, results obtained are very similar using either method. The complementarity of the 2 assays will allow a better comprehension of the mechanisms by which mutations may arise in mammalian cells.

Comparative study of Epstein-Barr virus and SV40-based shuttle-expression vectors in human repair-deficient cells

Shuttle vectors and expression vectors have been used in human cells to examine various aspects of DNA repair including effects of DNA damage on mutagenesis, transcription, replication and recombination. A combined shuttle-expression system should provide further advantages for the stable expression of and perhaps selection/rescue strategies for DNA repair genes. We describe 2 such systems. The first is a simian virus 40 (SV40) shuttle system which allows a quasi-stable episomal vector/host relationship in which the shuttle vector may be recovered in extrachromosomal DNA preparations many months after transfection and selection but in which a high proportion of the plasmids rescued in bacteria are heavily mutated and rearranged. Secondly, we describe Epstein-Barr virus-based shuttle-expression vectors which exist as stable, multicopy episomes in human cells. Using a reporter gene and a metal-inducible promoter we have obtained low basal and very high induced expression from episomal vectors in a variety of human cells including xeroderma pigmentosum and ataxia telangiectasia cell lines. This should facilitate many molecular genetic experiments in human cells and may have particular application to molecular cloning, expression and analysis of DNA repair genes.

Studies on direct and indirect effects of DNA damage on mutagenesis in monkey cells using an SV40-based shuttle vector

We are using an SV40-based shuttle vector, pZ189, to study mechanisms of mutagenesis in mammalian cells. The vector can be treated with mutagens in vitro and replicated in animal cells; resulting mutants can be selected and amplified in bacteria for DNA sequencing. This versatile vector system has allowed us to explore several different questions relating to the mutagenic process. We have studied the direct effects of template damage caused by UV or benzo[a]pyrene diolepoxide by treating vector DNA with these agents and then replicating the damaged DNA in monkey cells. Mutational mechanisms were deduced from the spectrum of mutations induced in the supF target gene of the vector DNA. To study the role of indirect effects of DNA damage on mutagenesis in mammalian cells, we have treated the cells and the vector DNA separately with DNA-damaging agents. We find that pretreatment of cells with DNA-damaging agents, or with conditioned medium from damaged cells, causes an enhancement of mutagenesis of a UV-damaged vector. Thus, DNA damage can act indirectly to enhance the mutagenic process. We also have preliminary evidence that pZ189 can be used in an in vitro DNA replication system to study the process of mutation fixation on the biochemical level. We believe that the pZ189 vector will prove to be as useful for in vitro studies of mutational mechanisms as it has been for in vivo studies.

SV40-based shuttle viruses

We summarize in this paper the advantages of the shuttle virus system. These SV40-based vectors exhibit the unique properties of being packaged as SV40 pseudo-virions and of being able to infect host cells. Using these transient vectors, we show that their replication can be regulated in some monkey cell lines, in such a way that either low or very high amounts of plasmid DNA can be obtained. The stability of these infectious shuttle vectors in different conditions is analyzed by rescuing them in E. coli, using various gene mutation targets. Moreover, we describe a new series of vectors which can be produced as single-stranded DNA in bacteria. They allow the transfection of a plasmid genome into mammalian cells, as either single-stranded or double-stranded DNA.

Analysis of single-stranded DNA stability and damage-induced strand loss in mammalian cells using SV40-based shuttle vectors

The fate and stability of fully or partially single-stranded DNA molecules transfected into mammalian cells have been analysed. For this, we constructed a simian virus 40 (SV40)-based shuttle vector containing the f1 bacteriophage replication origin in the two possible orientations (pi SVF1-A and pi SVF1-B). This vector contains the SV40 origin of replication, the late viral genes and DNA sequences for replication and selection in Escherichia coli. It also carries the lacO sequence, which permits the analysis of plasmid stability. Single-stranded DNA from pi SVF1-A and pi SVF1-B were produced in bacteria and annealed in vitro to form a heteroduplex molecule. We showed that, in monkey kidney COS7 cells, single-stranded vectors replicate to form duplex molecules. After transfection of the three forms of molecules (single-stranded, heteroduplex or double-stranded), replicated DNA was rescued in E. coli. Vector stability was analysed by checking for plasmid rearrangements and screening for lacO mutants. The single-stranded pi SVF1 has a lower rearrangement level, while the spontaneous mutation frequency (on the lacO target) is in the same range as for the double-stranded vector. In contrast, the level of spontaneous mutagenesis is higher for the heteroduplex than for the single- and double-stranded forms. In addition, we found that replication of heteroduplex with one strand containing ultraviolet light-induced lesions yields progeny molecules in which the irradiated strand is mostly lost. This result indicates for the first time the specific loss of the damaged strand in mammalian cells.