Homologous and nonhomologous recombination in monkey cells

The 60-year evolution of lipid nanoparticles for nucleic acid delivery

Delivery of genetic information to the interior of target cells in vivo has been a major challenge facing gene therapies. This barrier is now being overcome, owing in part to dramatic advances made by lipid-based systems that have led to lipid nanoparticles (LNPs) that enable delivery of nucleic acid-based vaccines and therapeutics. Examples include the clinically approved COVID-19 LNP mRNA vaccines and Onpattro (patisiran), an LNP small interfering RNA therapeutic to treat transthyretin-induced amyloidosis (hATTR). In addition, a host of promising LNP-enabled vaccines and gene therapies are in clinical development. Here, we trace this success to two streams of research conducted over the past 60 years: the discovery of the transfection properties of lipoplexes composed of positively charged cationic lipids complexed with nucleic acid cargos and the development of lipid nanoparticles using ionizable cationic lipids. The fundamental insights gained from these two streams of research offer potential delivery solutions for most forms of gene therapies.

Mechanistic toxicology in light of genetic compensation

Mechanistic toxicology seeks to identify the molecular and cellular mechanisms by which toxicants exert their deleterious effects. One powerful approach is to generate mutations in genes that respond to a particular toxicant, and then test how such mutations change the effects of the toxicant. CRISPR is a rapid and versatile approach to generate mutations in cultured cells and in animal models. Many studies use CRISPR to generate short insertions or deletions in a target gene and then assume that the resulting mutation, such as a premature termination codon, causes a loss of functional protein. However, recent studies demonstrate that this assumption is flawed. Cells can compensate for short insertion and deletion mutations, leading toxicologists to draw erroneous conclusions from mutant studies. In this review, we will discuss mechanisms by which a mutation in one gene may be rescued by compensatory activity. We will discuss how CRISPR insertion and deletion mutations are susceptible to compensation by transcriptional adaptation, alternative splicing, and rescue by maternally derived gene products. We will review evidence that measuring levels of messenger RNA transcribed from a mutated gene is an unreliable indicator of the severity of the mutation. Finally, we provide guidelines for using CRISPR to generate mutations that avoid compensation.

Inducible gene expression in postmitotic neurons by an in vivo electroporation-based tetracycline system

In vivo electroporation has been widely used to transfect foreign genes into neural progenitors and analyze the function of genes of interest in the developing nervous system. However, it has not been thoroughly examined in the conditional regulation of exogenous genes in postmitotic neurons. Here we show that the combination of in vivo electroporation and the newest version of the tetracycline (Tet)-controlled gene regulatory (Tet-On) system efficiently induced gene expression in various types of neurons in mouse embryonic and postnatal tissues. In pyramidal neurons of the cerebral cortex, tetracycline-responsive element (TRE)-driven gene expression was induced in the presence of doxycycline (Dox). The induction occurred in a dose-dependent manner. The Dox-dependent induction was also observed in cerebellar Purkinje cells and spinal cord neurons. Moreover, the TRE-driven inducible expression of mammalian Barh1 (Mbh1) mimicked the phenotype of the ubiquitous expression of Mbh1 in the spinal cord. These results indicate that the combination of the Tet-On system and in vivo electroporation is useful for analyzing gene function specifically in postmitotic neurons.

Moments of Discovery

Devoted teachers and mentors during early childhood and adolescence nurtured my ambition to become a scientist, but it was not until I actually began doing experiments in college and graduate school that I was confident about that choice and of making it a reality. During my postdoctoral experiences and thereafter, I made several significant advances, most notably the discovery of the then novel acyl- and aminoacyl adenylates: the former as intermediates in fatty acyl coenzyme A (CoA) formation and the latter as precursors to aminoacyl tRNAs. In the early 1970s, my research changed from a focus on transcription and translation in Escherichia coli to the molecular genetics of mammalian cells. To that end, my laboratory developed a method for creating recombinant DNAs that led us and others, over the next two decades, to create increasingly sophisticated ways for introducing “foreign” DNAs into cultured mammalian cells and to target modifications of specific chromosomal loci. Circumstances surrounding that work drew me into the public policy debates regarding recombinant DNA practices. As an outgrowth of my commitment to teaching, I coauthored several textbooks on molecular genetics and a biography of George Beadle. The colleagues, students, and wealth of associates with whom I interacted have made being a scientist far richer than I can have imagined.

PML-nuclear bodies accumulate DNA in response to polyomavirus BK and simian virus 40 replication

Promyelocytic nuclear bodies (PML-NBs) are distinct nuclear structures that are involved in apoptosis, differentiation, transcriptional regulation and DNA damage response. These bodies have also been shown to associate with nuclear sites of viral DNA replication. In the present study, we used BrdU pulse labeling to demonstrate that PML-NBs accumulate newly synthesized DNA in cells infected by the polyomaviruses simian virus 40 (SV40) or polyomavirus BK (BKV). Sequestration of DNA molecules in these structures depended on active viral DNA replication, and was observed exclusively in cells that contained prominent viral replication domains. Furthermore, a significant portion of the accumulated DNA was found to be single-stranded, indicating that the sequestered DNA had been subjected to processing by nuclease or DNA unwinding activities. siRNA-mediated suppression of the PML protein prevented the recruitment of single-stranded DNA into nuclear foci, but did not significantly affect the overall efficiency of viral DNA replication. These results indicate a role of PML and PML-NBs in post-replication DNA processing, and suggest that PML-NBs become linked to sites of viral DNA synthesis due to a role of these structures in DNA metabolism.

Nonlinear effects in the torsional adjustment of interacting DNA

DNA molecules in solution, having negatively charged phosphates and countercations readsorbed on its surface, possess a distinct charge separation motif to interact electrostatically. If their double-helical structure were ideal, duplexes in parallel juxtaposition could choose azimuthal alignment providing attraction, or at least a reduction of repulsion, between them. But duplexes are not perfect staircases and the distortions of their helical structure correlate with their base pair texts. If the patterns of distortions on the opposing molecules are uncorrelated, the mismatch will accumulate as a random walk and attraction vanishes. Based on this idea, a model of recognition of homologous sequences has been proposed [A. A. Kornyshev and S. Leikin, Phys. Rev. Lett. 86, 3666 (2001)]. But DNA has torsional elasticity. How will this help to relax a mismatch between the charge distributions on two nonhomologous DNA's? In the same work, the solution of this problem has been mapped onto a frustrated sine Gordon equation in a nonlocal random field (where the latter represents a pattern of twist angle distortions on the opposing molecules), but the results had been obtained in the limit of torsionally rigid molecules. In the present paper, by solving this equation numerically, we find a strongly nonlinear relaxation mechanism which utilizes static kink-soliton modes triggered by the "random field." In the range of parameters where the solitons do not emerge, we find good agreement with the results of a variational study [A. G. Cherstvy, A. A. Kornyshev, and S. Leikin, J. Phys. Chem. B (to be published)]. We reproduce the first-order transitions in the interaxial separation dependence, but detect also second-order or weak first-order transitions for shorter duplexes. The recognition energy between two nonhomologous DNA sequences is calculated as a function of interaxial separation and the length of juxtaposition. The soliton-caused kinky length dependence is discussed in connection with plots of recombination frequency as a function of the length of homology.

Asymmetric random walk in a reaction intermediate of homologous recombination

At an intermediate step of the homologous recombination between two double-stranded DNA molecules, a point (often called Holliday structure) connecting two strands coming from two recombining partners migrates along the homologous region. Assuming random walk of a connecting point, we previously explained the dependence of recombination frequency on the homology length observed in vivo. In this model, the random walk was assumed to be symmetric in that the forward transition rate equals the backward one. According to observations in vitro, however, catalysed migration appears unidirectional. Taking into account possible asymmetry, we thus reformulate our random walk model to reexamine the observations in vivo. We also derive some theoretical results to analyse dynamic processes observed in vitro.

A novel host cell reactivation assay to assess homologous recombination capacity in human cancer cell lines

Repair of DNA double-strand breaks (DSB) is essential for cell viability and genome stability. Homologous recombination repair plays an important role in DSB repair and impairment of this repair mechanism may lead to loss of genomic integrity, which is one of the hallmarks of cancer. Recent research has shown that the tumor suppressor genes p53 and BRCA1 and -2 are involved in the proper control of homologous recombination, suggesting a role of this type of repair in human cancer. We developed a novel assay based on recombination between two Green Fluorescent Protein (GFP) sequences in transiently transfected plasmid DNA. The plasmid construct contains an intact, emission-shifted, "blue" variant of GFP (BFP), with a 300 nucleotide stretch of homology to a nonfunctional copy of GFP. In the absence of homologous recombination only BFP is present, but homologous recombination can create a functional GFP. The homologous regions in the plasmid were constructed in both the direct and the inverted orientation of transcription to detect possible differences in the recombination mechanisms involved. A panel of human tumor cell lines was chosen on the basis of genetic background and chromosome integrity and tested for homologous recombination using this assay. The panel included cell lines with varying levels of karyotypic abnormalities, isogenic cell lines with normal and mutant p53, isogenic cell lines with or without DNA mismatch repair, BRCA1 and -2 mutant cell lines, and the lymphoma cell line DT40. With this assay, the observed differences between cell lines with the lowest and highest levels of recombination were about 100-fold. Increased levels of recombination were associated with mutant p53, whereas a low level of recombination was found in the BRCA1 mutant cell line. In the cell line HT1080TG, a mutagenized derivative of HT1080 with two mutant alleles of p53, high levels of recombination were found with the direct orientation but not with the inverted orientation plasmid. No difference in recombination was detected between two isogenic cell lines that only differed in DNA mismatch repair capability. We conclude that this assay can detect differences in homologous recombination capacity in cultured cell lines and that these differences follow the patterns that would be expected from the different genotypes of these cell lines. Future application in normal cells may be useful to identify genetic determinants controlling genomic integrity or to detect differences in DNA repair capacity in individuals.

Rescue of polyomavirus DNA after co-transfection of recombinant plasmids with viral DNA fragments

Plasmid DNA bearing a single copy of the mouse polyomavirus (Py) genome (template A) was transfected into murine cells together with another DNA (template B) carrying intact the viral sequence interrupted in template A. Rescue of unit-length Py DNA including markers from both templates was observed as long as the viral DNA in B overlapped that split in A by one kbp or more. Such rescue was not detectably enhanced by linearizing either or both template(s), and occurred in the absence of template replication. These findings are suggestive of an intermolecular recombination process taking place soon after transfection and starting with homologous pairing between A and B. Such pairing would facilitate removal of vector DNA from one template (A), followed by closure of the resulting break or gap through recombination with the other template (B). Since B may consist of a PCR-synthesized DNA fragment, these observations could conceivably serve as the basis for a method of generating mutant viral genomes.

Cis-acting effects of sequences within 2.4-kb upstream of the human c-myc gene on autonomous plasmid replication in HeLa cells

We have used density shift analysis to monitor the autonomous replicating sequence (ARS) activity of plasmids containing various DNA fragments from the 5'-flanking region of the human c-myc gene. The ARS activity of certain of these plasmids implied that structures in the c-myc DNA could be recognized for the initiation of replication in the absence of chromosomal integration. The plasmid pNeo.Myc-2.4 contains 2.4 contains 2.4 kb of c-myc 5'-flanking DNA, and replicated semiconservatively as a circular extrachromosomal element. Deletion derivatives of pNeo.Myc-2.4 containing either of two nonoverlapping regions of c-myc DNA semiconservatively incorporated bromodeoxyuridine into discrete populations of heavy-light supercoiled molecules to roughly the same extent as the chromosomal DNA in the same cultures. Some constructs displayed lower ARS activity, implying that distinct cis-acting sequences in the c-myc 5'-flanking DNA may independently affect DNA replication. The ARS activity of two separate c-myc sequences suggests that replication initiation signals are redundant in the c-myc origin. The smallest c-myc insert that displayed substantial ARS activity was 930 bp long and contained three 10/11 matches to the yeast ARS consensus and several additional features found in eukaryotic replication origins.

Dependence of frequency of homologous recombination on the homology length

The frequency of homologous recombination is believed to be a linear function of the length (N bp) of homology between DNAs. Here, the N intercept is believed to be determined by a threshold length below which some physical constraint is effective. In the mammalian gene targeting systems, however, the frequency depends more steeply than linearly on the homology length. To explain both the linear dependence and the steeper dependence, we propose a model where the branch point of a reaction intermediate is assumed to "walk randomly" along the homologous region until it is processed. The intermediate is assumed to be destroyed if the branch point ever reaches either end of the homology. In this model, the length dependence is governed by a parameter, h, which is defined as efficiency of processing of the intermediate and reflects unlikelihood of the destruction at either end of the homology. We find that the frequency is proportional to N3 for smaller N and is a linear function of N for larger N. Where the shift from the N3 dependence to the linear dependence takes place is determined by the parameter h. The range of N showing the N3 dependence becomes narrower as h becomes larger. The dependence steeper than linear dependence, which is observed not only in the mammalian gene targeting system but also in bacteriophage T4, Escherichia coli and yeast systems, agrees well with the predicted N3 dependence. The N intercept is determined not by physical (or structural) constraints but only by the parameter h in this model.

Studies of fowlpox virus recombination in the generation of recombinant vaccines

A p7.5/beta-galactosidase (7.5 lacZ) gene construct, cloned adjacent to the fowlpox virus (FPV) thymidine kinase (tk) gene was used as a marker to identify the products of recombination as 'blue' FPV plaques. The rFPVs were detected as early as 4 h after the introduction of plasmid DNAs and by 72 h post-infection (p.i.) for one transfer vector comprised 0.48% of the viral population. The proportion of rFPV increased linearly from 0.073% to 0.62% as the cumulative length of homologous sequences in the transfer vector increased from 0.73 to 4.5 kb. Two approaches using a second reporter gene, the Newcastle disease virus haemagglutinin-neuraminidase (NDV HN) gene were tested to differentiate between single and double cross-over events. In one, the HN gene was cloned into the FPV tk gene and the 7.5 lacZ cloned outside of the homologous region. Progeny of a single cross-over with FPV DNA generated an unstable plaque containing the HN gene and subsequent intramolecular recombination resulted in excision of the 7.5 lacZ and the generation of a stable 'white' plaque. For virus grown in CEF cells (tk+) in the presence of 5-bromo-deoxyuridine, only those viruses which contained a tk gene disrupted by the HN gene formed plaques. This approach allowed us to easily identify rFPV containing the HN gene but lacking 7.5 lacZ or other bacterial sequences. In a second approach, a double cross-over between rFPV DNA containing a stably expressed beta-galactosidase gene cloned into the tk gene (blue plaque) and plasmid DNA containing the HN gene flanked by tk sequences would allow transplacement of the 7.5 lacZ gene with the HN gene, and generating a white plaque. We were unable to generate recombinant viruses with the HN gene and which generated a white plaque, indicating that double cross-over events do not occur at a sufficiently high frequency in FPV.

Rearrangements occurring adjacent to a single Ty1 yeast retrotransposon in the presence and absence of full-length Ty1 transcription

The structures of two unusual deletions from the yeast Saccharomyces cerevisiae are described. These deletions extend from a single Ty1 retrotransposon to an endpoint near a repetitive tRNA(Gly) gene. The deletions suggest that unique sequences flanked by two nonidentical repetitive sequences, or bordered on only one side by a transposable element, have the potential to be mobilized in the yeast genome. Models for the formation of these two unusual deletions were tested by isolating and analyzing 32 additional unusual deletions of the CYC1 region that extend from a single Ty1 retrotransposon. Unlike the most common class of deletions recovered in this region, these deletions are not attributable solely to homologous recombination among repetitive Ty1 or delta elements. They arose by two distinct mechanisms. In an SPT8 genetic background, most unusual deletions arose by transposition of a Ty1 element to a position adjacent to a tRNA(Gly) gene followed by Ty1-Ty1 recombination. In an spt8 strain, where full-length Ty1 transcription and, therefore, transposition are reduced, most deletions were due to gene conversion of a 7-kb chromosomal interval flanked by a Ty1 element and a tRNA(Gly) gene.

A mathematical model of homologous recombination in cultured cells

This work presents a model describing the rate of recombination between homologous segments of DNA stably integrated into the genome of cultured cells. The model has been applied to rat cell lines carrying the polyomavirus middle T oncogene and a functional origin of viral DNA replication. Introduction of the gene coding for the polyoma large T antigen or the SV40 large T antigen into cells by DNA transfection promotes homologous recombination in the resident viral inserts with rates varying between 0.1 x 10(-3) and 3.7 x 10(-1) per cell generation.

Homologous recombination between plasmid DNA molecules in maize protoplasts

The requirements for homologous recombination between plasmid DNA molecules have been studied using the PEG (polyethylene glycol)-mediated transformation system of maize (Zea mays L.) protoplasts coupled with the transient expression assay for beta-glucuronidase (GUS). Two plasmids were introduced into maize protoplasts; one plasmid (pB x 26) contained a genomic clone of the Adh1 maize gene; the other plasmid (piGUS) was a promoterless construction containing part of intron A of the Adh1 gene fused to the gusA coding sequence. Thus, the two vectors shared an effective homologous region consisting of a 459 bp (HindIII-PvuII) fragment of the Adh1 intron A sequence. An active gusA fusion gene would result upon homologous recombination between the plasmids within the intron A sequence, and indeed GUS activity was observed in extracts following co-transformation of maize protoplasts with the two plasmids. The presence of recombinant DNA molecules in protoplast DNA isolated 1 day after co-transformation was verified using polymerase chain reactions (PCR) and Southern blots. For efficient homologous recombination, both plasmids had to be linearized. The recombination reaction was induced by restriction of the plasmid molecules either inside the effective homologous region or at the borders of the intron sequence. However, the presence of even small, terminal, nonhomologous sequences at the 3' end of the pB x 26 fragment inhibited the recombination reaction. Also, both ends of the linearized piGUS DNA molecules were involved in the recombination reaction. The results revealed some features of homologous recombination reactions occurring in plant cells which cannot be accommodated by mechanisms postulated for similar reactions in animal system and in lower eukaryotes.

Reciprocal homologous junctions generated in mouse cells

We analysed pairs of reciprocal homologous junctions resulting from intermolecular conservative homologous recombination in mouse cells. The assay used did not rely on the reconstitution of a selectable gene. This permitted the introduction of multiple markers in the parental homologous sequences which in turn enabled us to compare the contribution of each parent to the reciprocal products of a given recombination event. In all recombinants analysed we found, when comparing the reciprocal junctions, a middle segment originating from only one parent. This segment of uniparental origin occurred randomly throughout the region of homology and could extend over a thousand base pairs. These results are consistent with a gap repair process like the one proposed for homologous recombination in yeast. However, introducing a double-strand break in the region of homology did not enhance but rather decreased the proportion of recombinants with reciprocal homologous junctions relative to other types of recombinants.

T-DNA integration: a mode of illegitimate recombination in plants

Transferred DNA (T-DNA) insertions of Agrobacterium gene fusion vectors and corresponding insertional target sites were isolated from transgenic and wild type Arabidopsis thaliana plants. Nucleotide sequence comparison of wild type and T-DNA-tagged genomic loci showed that T-DNA integration resulted in target site deletions of 29-73 bp. In those cases where integrated T-DNA segments turned out to be smaller than canonical ones, the break-points of target deletions and T-DNA insertions overlapped and consisted of 5-7 identical nucleotides. Formation of precise junctions at the right T-DNA border, and DNA sequence homology between the left termini of T-DNA segments and break-points of target deletions were observed in those cases where full-length canonical T-DNA inserts were very precisely replacing plant target DNA sequences. Aberrant junctions were observed in those transformants where termini of T-DNA segments showed no homology to break-points of target sequence deletions. Homology between short segments within target sites and T-DNA, as well as conversion and duplication of DNA sequences at junctions, suggests that T-DNA integration results from illegitimate recombination. The data suggest that while the left T-DNA terminus and both target termini participate in partial pairing and DNA repair, the right T-DNA terminus plays an essential role in the recognition of the target and in the formation of a primary synapsis during integration.

Homologous recombination in a mammalian plasmid

Bovine papillomavirus (BPV) shuttle vectors replicate as a circular plasmid in mouse cell nuclei without impairing host cell viability. We used these vectors to analyze homologous recombination in mammalian cells. When several BPV-based plasmids carrying direct repeats were introduced into C127 cells, we detected many recombinant plasmid molecules that have lost the sequence between the repeats. Many recombinant type molecules as well as parental type molecules were detected in all the cell clones isolated for analysis. Sequencing after rescue of the plasmid in Escherichia coli showed that most of the recombinants were from accurate homologous recombination. When the repeats on the plasmid were in inverted orientation, no crossing-over type products were detected. We discuss possible mechanisms that explain these features.

Targeted gene modification for gene therapy of stem cells

Ideally, gene therapy would correct the specific gene defect without adding potentially harmful extraneous DNA sequences. Such correction can be obtained with homologous recombination between input DNA sequences and identical (homologous) sequences in the genomic target gene. The development of techniques for obtaining virtually pure populations of hematopoietic stem cells should permit the use of the highly efficient nuclear microinjection methods for transfer of DNA. These techniques combined with new highly sensitive methods for detecting cells with the specified genetic modification of nonexpressed genes would make homologous recombination-mediated gene therapy feasible for hematopoietic stem cells. These advances are reviewed with particular emphasis on approaches to targeted gene modification of hematopoietic stem cells and speculation on directions for future research.

Distance-independence of mitotic intrachromosomal recombination in Saccharomyces cerevisiae

Many genetic studies have shown that the frequency of homologous recombination depends largely on the distance in which recombination can occur. We have studied the effect of varying the length of duplicated sequences on the frequency of mitotic intrachromosomal recombination in Saccharomyces cerevisiae. We find that the frequency of recombination resulting in the loss of one of the repeats and the intervening sequences reaches a plateau when the repeats are short. In addition, the frequency of recombination to correct a point mutation contained in one of these repeats is not proportional to the size of the duplication but rather depends dramatically on the location of the mutation within the repeated sequences. However, the frequency of mitotic interchromosomal reciprocal recombination is dependent on the distance separating the markers. The difference in the response of intrachromosomal and interchromosomal mitotic recombination to increasing lengths of homology may indicate there are different rate-limiting steps for recombination in these two cases. These findings have important implications for the maintenance and evolution of duplicated sequences.

Use of damaged plasmid to study DNA repair in X-ray sensitive (xrs) strains of Chinese hamster ovary (CHO) cells

The effect of gamma-irradiation of pSV2gpt DNA on its transfection frequency has been analysed using CHO xrs mutants. Xrs mutants are sensitive to ionizing radiation and show a defect in double-strand break (dsb) rejoining. At low doses a sharp decrease in relative transfection frequency, i.e. transfection frequency of irradiated plasmid relative to untreated plasmid, was observed in the xrs mutants compared with the parent line K1. Electrophoresis of the irradiated plasmid DNA showed that the decrease in transfection frequency in the xrs mutants correlated with the change of supercoiled molecules into open-circular forms. One explanation for these results is that the xrs gene could play a part in the integration or repair of open-circular molecules produced by gamma-radiation. In the parent line CHO-K1, open-circular and supercoiled molecules have the same transfection frequency. The effect of linearization of pSV2gpt DNA by restriction enzymes on transfection frequency in xrs and wild-type strains has also been examined. In contrast to the above results we have not detected a difference in the relative transfection frequency between xrs and wild-type strains. The results suggest that restricted plasmid DNA is subject to extensive nucleolytic degradation, and this occurs to equal extents in wild type and mutant strains.

The new mouse genetics: altering the genome by gene targeting

Gene targeting (homologous recombination between DNA sequences residing in the chromosome and newly introduced DNA sequences) in pluripotent, mouse embryo-derived stem (ES) cells promises to provide the means to generate mice of any desired genotype. This review describes some of the background and current advances of gene targeting in mouse ES cells.

Analysis of recombination in mammalian cells using SV40 and SV40-derived vectors

Viruses and viral vectors have played a crucial role in our understanding of the pathways of homologous and non-homologous recombination in mitotically dividing mammalian cells. In particular, they have allowed the confirmation of the preponderance of non-homologous over homologous recombination events and led to schemes for the selection and isolation of homologous recombination products. These studies have allowed an examination of the properties of reciprocal and non-reciprocal homologous recombination events extrachromosomally, in the chromosome and between plasmids and chromosomes. They suggest that it is feasible now to direct DNA segments to predetermined chromosomal locations by homologous recombination.

Enhancement of DNA repair capacity of mammalian cells by carcinogen treatment

To determine whether DNA excision repair is enhanced in mammalian cells in response to DNA damage, as it is in bacteria as part of the SOS response, we used an expression vector-host cell reactivation assay to measure cellular DNA repair capacity. When UV-damaged chloramphenicol acetyltransferase (CAT) vector DNA was introduced into monkey cells (CV-1), the level of CAT activity was inversely related to the UV fluence due to inhibition of CAT gene expression by UV photoproducts. When CV-1 cells were treated with either UV radiation or mitomycin C, 24-48 h before transfection, CAT expression from the UV-irradiated plasmid was increased. This increase also occurred in a line of normal human cells, but not in repair-deficient human xeroderma pigmentosum cells. We confirmed that this increase in CAT expression was due to repair, and not to production of damage-free templates by recombination; the frequency of generation of supF+ recombinants after transfection with UV-irradiated pZ189 vectors carrying different point mutations in the supF gene did not significantly increase in carcinogen-treated CV-1 cells. From these results we conclude that carcinogen treatment enhances the excision-repair capacity of normal mammalian cells.

Homologous recombination between hepadnaviral genomes following in vivo DNA transfection: implications for studies of viral infectivity

The cloned DNA of duck hepatitis B virus (DHBV) can initiate a productive infection of susceptible ducklings when presented by direct intrahepatic injection. We have examined the effects of the structure of the incoming DNA upon the outcome of this in vivo transfection. Plasmid-linked DHBV genomes of greater than unit length regularly give rise to infectious virus irrespective of the location of the plasmid insert on the transcriptional map. When mutant DHBV genomes are coinjected with subgenomic viral DNA fragments spanning the mutation, wild-type recombinants arise. These results indicate that, as in transfection of cultured cells, in vivo transfection of hepatocytes is regularly followed by homologous recombination involving incoming DNA molecules. These frequent recombination events will complicate efforts to use in vivo transfection for certain genetic analyses of hepadnaviruses.

Recombination of selectable marker DNA in Nicotiana tabacum

A chimeric neomycin phosphotransferase II (NPT II) gene, which normally provides kanamycin resistance to transformed plant cells, was inactivated by in vitro deletions. Repair plasmids not containing plant-specific transcription signals but containing only the NPT II coding region (or parts of it) were used in co-transformation experiments involving direct DNA uptake into protoplasts isolated from Nicotiana tabacum. Recombination, or gene conversion mediated by homologous sequences produced active NPT II genes in about 1% of transformants, rendering these cells resistant to kanamycin. Analysis of the size of the active enzyme indicated that recombination had occurred producing an NPT II gene indistinguishable from the wild-type gene. Southern blot analysis revealed that the bulk of co-transformed donor plasmid DNA had suffered structural modifications; however, kanamycin resistance was inherited in a Mendelian fashion, indicating that at least one functional and structurally intact copy of the regenerated NPT II gene is integrated into the host genome.

A recombinant Chinese hamster ovary cell line containing a 300-fold amplified tetramer of the hepatitis B genome together with a double selection marker expresses high levels of viral protein

A new series of double-selection plasmids containing recombinant genes expressing the neomycin phosphotransferase (NEO) of transposon Tn5 and mouse dihydrofolate reductase (DHFR) in mammalian cells is described. Activity of the recombinant DHFR gene varied more than 50-fold, depending on the location of the simian virus 40 72 base-pair repeat or enhancer, which is part of the promoter of the NEO unit. A NEO-DHFR module with the enhancer located at the 3' end of the DHFR gene was inserted into a plasmid containing four tandem head-to-tail copies of the hepatitis B virus (HBV) genome and the new plasmid was used to transform DHFR- Chinese hamster ovary cells. In one of the cell lines obtained, an unrearranged copy of the HBV tetramer could be amplified 300-fold by increasing selective pressure with methotrexate, resulting in a proportional increase of the synthesis of HBV surface antigen. Four different mRNAs detected in the amplified cell line probably encode HBV core protein, pre-S and surface antigens, and the X protein. As a result of the DNA amplification, synthesis of HBV proteins is no longer restricted to resting cells. Integrated plasmid sequences appear to be stable during the amplification process.

Analysis of homologous recombination in cultured mammalian cells in transient expression and stable transformation assays

Recombination between plasmid molecules, each containing a nonoverlapping deletion mutation in the hamster adenine phosphoribosyltransferase gene, was measured after coinjection into rat cells. Using these two plasmids, as linear or circular molecules, the recombination efficiency was measured soon after injection in a transient expression assay or after selection for stable transformants. The transient assay revealed that linear molecules were a better substrate for recombination, with double strand breaks within the region of homology stimulating recombination more than breaks outside the region of homology. A 20 to 70-fold increase in the efficiency of recombination was observed when two linear molecules were coinjected as compared to two circular molecules. Linear molecules were found to not only stimulate recombination but also to facilitate stable integration of the recombinant molecule into the host genome.

High frequency of homologous recombination in mammalian cells between endogenous and introduced SV40 genomes

We have detected a high frequency of homologous recombination between introduced and chromosomal DNA in mammalian cells. Linear enhancerless SV40 DNA has been transfected into monkey cells that have either one (COS1 cells) or five to seven (COS7 cells) copies of the SV40 early region stably integrated into their genome. Enhancer-containing wild-type SV40 DNA is formed as a result of homologous recombination of the introduced DNA with chromosomal DNA. Up to 25% of the successfully transfected cells produce wild-type virus within 48 hr after transfection. The highest levels of wild-type virus were produced from transfections of molecules that contained a double-strand break at positions of uninterrupted homology with the chromosomal template. This SV40/COS cell system provides a rapid assay for recombination between introduced and genomic DNA.

Enhancement of genetic transformation frequencies of mammalian cell cultures by damage to the cell DNA

Ultraviolet (UV)-light and 5-fluorodeoxyuridine (FUdR), two known DNA damaging agents, were found to enhance the frequency of stable plasmid transformations in several different animal cell lines. Combined treatment with the two agents was more effective than treatment with either agent alone. A correlation between the transformability of a cell line in the absence of treatment and its response to damaging treatment was also observed. Southern blot analysis of transformed clones indicated that the stimulation in transformation frequency was not due to an increased number of copies of the integrated plasmid in the transformed cells.

Homologous recombination of polyoma virus DNA in mouse cells

We have produced nonviable deletion mutants of polyoma virus in order to study homologous recombination after DNA transfection into mouse cells. The frequency of recombination was determined by the formation of infectious virus. It was dependent on the amount of DNA transfected and the size of the region of homology between the mutations. Recombination frequencies were highest when both mutated genomes were transfected in closed circular form rather than after linearization of one or both of the recombination partners. The system described may be useful for a more detailed analysis of physiological and genetic conditions influencing the frequency of homologous recombination in mouse cells as well as to study enzymes involved and intermediates produced in this process.

Circular and linear simian virus 40 DNAs differ in recombination

Linear forms of simian virus 40 (SV40) DNA, when added to transfection mixtures containing circular SV40 and phi X174 RFI DNAs, enhanced the frequency of SV40/phi X174 recombination, as measured by infectious center in situ plaque hybridization in monkey BSC-1 cells. The sequences required for the enhancement of recombination by linear DNA reside within the SV40 replication origin/regulatory region (nucleotides 5,171 to 5,243/0 to 128). Linearization of phi X174 RFI DNA did not increase the recombination frequency. The SV40/phi X174 recombinant structures arising from transfections supplemented with linear forms of origin-containing SV40 DNA contained phi X174 DNA sequences interspersed within tandem head-to-tail repeats derived from the recombination-enhancing linear DNA. Evidence is presented that the tandem repeats are not formed by homologous recombination and that linear forms of SV40 DNA must compete with circular SV40 DNA for the available T antigen to enhance recombination. We propose that the enhancement of recombination by linear SV40 DNA results from the entry of that DNA into a rolling circle type of replication pathway which generates highly recombinogenic intermediates.

Expression of Growth Hormone Genes in Transgenic Mice

Human or rat growth hormone (GH) genes have been introduced into all cells of a mouse by microinjection of fertilized eggs but they were not expressed under their own promoters. However, substitution of a mouse metallothionein (MT) promoter allowed expression and regulation comparable to that of the endogenous MT genes. These fusion genes have been used to stimulate the growth of both normal mice and dwarf mice that lack sufficient GH. Substitution of a rat elastase-I promoter directed expression of GH exclusively to the acinar cells of the pancreas. Progress has been made towards developing the hGH gene into a vector that is not expressed in vivo unless an enhancer element is inserted. Recombination between overlapping DNA fragments derived from a MThGH gene, each of which is nonfunctional, has been observed when they are coinjected into mouse eggs. In some cases, functional hGH was produced as evidenced by enhanced growth of the mice.

Effect of cell cycle position on transformation by microinjection

We have investigated the effect of cell cycle position on the efficiency of transformation by microinjection. Linear recombinant plasmids transform synchronized cells with similar frequencies following injections at all cell cycle stages, whereas supercoiled molecules show a decreased ability to generate transformants in early S phase. This inhibition is not due to an inability to transiently express a transferred gene, since cells at all stages of the cycle efficiently expressed a hamster adenine phosphoribosyltransferase gene introduced on a supercoiled plasmid. Southern transfer analyses of the cell cycle specific transformants revealed that tandem arrays of plasmids, integrated into the host chromosomes, could be generated at all cell cycle stages.

Rescue of silent integrated polyoma genomes suggests homologous recombination between resident and transfected DNA fragments

Two defective polyoma virus genomes, deleted in the nucleotide sequences coding the N-termini of the tumor antigens, were introduced into Fisher 3T3 rat cells by DNA-mediated gene transfer (transfection). The resulting integrated genomes were incapable of conferring a transformed phenotype to the cells. However, after transfection of these lines with small polyoma fragments overlapping the deleted sequences, transformed clones were isolated. These clones were analyzed by Southern genomic blot hybridization and by isolation in E. coli of plasmids containing viral sequences excised following fusion with mouse polyoma growth-permissive cells. In all cases at least one intact copy of the early region of the polyoma genome was found. Furthermore, restriction sites adjacent to the initial inactive insertion remained unchanged in many of the transformed lines. These results show that functional restoration of the defective polyoma early region involves homologous recombination between the deleted viral genomes integrated in the cellular DNA and the transfecting viral fragments.

Recombination between simian virus 40 and adeno-associated virus: virion coinfection compared to DNA cotransfection

Recombination between simian virus 40 (SV40) and adeno-associated virus (AAV) has been detected, by infectious center in situ plaque hybridization procedures, after both DNA contransfection and virion coinfection of monkey BSC-1 cells. The number of cells producing recombinants (1 in a 1000) was the same irrespective of the way in which the SV40 and AAV genomes were delivered to the cell, despite the fact that 5-10 times more cells were infected after virion coinfection. Several other dosage-response parameters of the recombination process consequent to virion coinfection were comparable to those after DNA cotransfection. The sole difference observed between the two infection systems was that the SV40/AAV recombinants formed after virion coinfection contained an inordinately high proportion of AAV terminal DNA sequences. By separating the SV40 and AAV infections in time, such that the AAV infection was delayed until after certain events in the SV40 cycle had taken place, an optimum phase for recombination in the SV40 cycle was identified. This phase occurs a few hours after infection, well before the onset of SV40 DNA replication and the synthesis of SV40-specific early proteins.

DNA sequence studies of simian virus 40 chromosomal excision and integration in rat cells

Cell fusion between simian CV1 cells and the simian virus 40-transformed rat cell line 14B, which contains a single copy of integrated simian virus 40 DNA, results in chromosomal excision of viral DNA. A heterogeneous population of circular molecules containing both viral and cellular DNA is detected in the replicating pool. We present the DNA sequences across six novel junctions created by these excision events and use this information to define the parental genomic sequences involved in this form of "illegitimate" recombination. The data were analyzed to discover whether any common structural feature(s) could be detected at these sites. In each case a redundancy of either two or three base-pairs was found at the precise points of cross-over in both parental DNA molecules. The cross-over points were further distinguished by the presence of at least one copy of the sequence 5'Pyr-T-T3' in either of the homologous sequences that define the cross-over points. Additional stretches of homology are found extending from the homologous cross-over points. To explore the possibility that the selection of the cross-over sites is determined by the free energy of base-pairing, we have used the program of Zuker & Stiegler (1981) to form model heteroduplexes between single-stranded parental DNA molecules. In some cases model heteroduplexes were formed that paired the cross-over points, although these structures were of dubious thermodynamic stability. We therefore conclude that, while the redundancies at the cross-over points must play some role in these processes, other factors aside from simple base-pairing across replicating structures must also be involved. In order to expand our analysis of the recombination events that accompany transformation of rat cells by simian virus 40, we determined the DNA sequences across one of the sites on the rat genome that served as the target for the integration event that engendered the 14B line. Our analysis of this DNA showed that: (1) viral and chromosomal DNA share three base-pairs of homology at the site of cross-over; (2) the cross-over site in the rat genome is adjacent to the trinucleotide 5'Pyr-T-T3'; and (3) the homology shared by the virus and chromosome does not resemble the homology reported at another integration locus, but is similar in that it is flanked on one side by alternating purine and pyrimidine nucleotides.

Analysis of gene expression using simian virus 40 vectors

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.