Nonreciprocal exchanges of information between DNA duplexes coinjected into mammalian cell nuclei

Construction and analysis of artificial chromosomes with de novo holocentromeres in Caenorhabditis elegans

Artificial chromosomes (ACs), generated in yeast (YACs) and human cells (HACs), have facilitated our understanding of the trans-acting proteins, cis-acting elements, such as the centromere, and epigenetic environments that are necessary to maintain chromosome stability. The centromere is the unique chromosomal region that assembles the kinetochore and connects to microtubules to orchestrate chromosome movement during cell division. While monocentromeres are the most commonly characterized centromere organization found in studied organisms, diffused holocentromeres along the chromosome length are observed in some plants, insects and nematodes. Based on the well-established DNA microinjection method in holocentric Caenorhabditis elegans, concatemerization of foreign DNA can efficiently generate megabase-sized extrachromosomal arrays (Exs), or worm ACs (WACs), for analyzing the mechanisms of WAC formation, de novo centromere formation, and segregation through mitosis and meiosis. This review summarizes the structural, size and stability characteristics of WACs. Incorporating LacO repeats in WACs and expressing LacI::GFP allows real-time tracking of newly formed WACs in vivo, whereas expressing LacI::GFP-chromatin modifier fusions can specifically adjust the chromatin environment of WACs. The WACs mature from passive transmission to autonomous segregation by establishing a holocentromere efficiently in a few cell cycles. Importantly, WAC formation does not require any C. elegans genomic DNA sequence. Thus, DNA substrates injected can be changed to evaluate the effects of DNA sequence and structure in WAC segregation. By injecting a complex mixture of DNA, a less repetitive WAC can be generated and propagated in successive generations for DNA sequencing and analysis of the established holocentromere on the WAC.

CRISPR-Cas12a-assisted PCR tagging of mammalian genes

Here we describe a time-efficient strategy for endogenous C-terminal gene tagging in mammalian tissue culture cells. An online platform is used to design two long gene-specific oligonucleotides for PCR with generic template cassettes to create linear dsDNA donors, termed PCR cassettes. PCR cassettes encode the tag (e.g., GFP), a Cas12a CRISPR RNA for cleavage of the target locus, and short homology arms for directed integration via homologous recombination. The integrated tag is coupled to a generic terminator shielding the tagged gene from the co-inserted auxiliary sequences. Co-transfection of PCR cassettes with a Cas12a-encoding plasmid leads to robust endogenous expression of tagged genes, with tagging efficiency of up to 20% without selection, and up to 60% when selection markers are used. We used target-enrichment sequencing to investigate all potential sources of artifacts. Our work outlines a quick strategy particularly suitable for exploratory studies using endogenous expression of fluorescent protein-tagged genes.

Regulatory Elements in Vectors for Efficient Generation of Cell Lines Producing Target Proteins

To date, there has been an increasing number of drugs produced in mammalian cell cultures. In order to enhance the expression level and stability of target recombinant proteins in cell cultures, various regulatory elements with poorly studied mechanisms of action are used. In this review, we summarize and discuss the potential mechanisms of action of such regulatory elements.

Determination of the Absolute Number of Transgene Copies in CMVFUT Transgenic Pigs

The aim of this research was to determine the number of transgene copies in the DNA of transgenic pigs. The copy number of the transgene was analysed in the transgenic animals with introduced pCMVFUT genetic construct containing a coding sequence of human H transferase under a control of CMV promoter. The copy number of the transgene that had integrated with the genome of the transgenic animals was analysed by qPCR with SYBR Green dye, which enabled nonspecific double-stranded DNA detection. CMVFT-2F and CMVFT-2R primers were used to amplify a 149 bp fragment of DNA. Forward primer had a sequence complementary to a promoter sequence and reverse primer to a coding sequence of H transferase. The copy number of the transgene in the examined samples was established by plotting the CT values obtained on a standard curve, which had been set by the usage of the CT values for the successive standard dilutions with known copy number (1.438-1.431 copies). As a standard we used pCMVFut genetic construct hydrolyzed with Not I restriction enzyme to a linear form. The real-time PCR results helped to establish the range of 3 - 4 as the number of the transgene copies that had integrated to the swine genome.

Unsuccessful attempt at gene-editing by homologous recombination in the zebrafish germ line using the approach of "Rong and Golic"

We have investigated the practicality of implementing a strategy for site-specific editing by homologous recombination in zebrafish analogous to that developed by Rong and Golic (Rong and Golic in Genetics 157:1307-1312, 2001) in Drosophila melanogaster. We analysed approximately 7,300 offspring from 22 crosses and demonstrated successful excision of the gene editing construct but failed to detect either gene editing or the random integration of the intact editing construct subsequent to excision. The clustering of events in our data set demonstrates that the excision events are not occurring independently and emphasise that a promoter driving high level, tissue-specific transcription in meiotic cells is likely to be necessary if this general approach to site-specific editing by homologous recombination is to fulfil its potential.

High-level transgene expression by homologous recombination-mediated gene transfer

Gene transfer and expression in eukaryotes is often limited by a number of stably maintained gene copies and by epigenetic silencing effects. Silencing may be limited by the use of epigenetic regulatory sequences such as matrix attachment regions (MAR). Here, we show that successive transfections of MAR-containing vectors allow a synergistic increase of transgene expression. This finding is partly explained by an increased entry into the cell nuclei and genomic integration of the DNA, an effect that requires both the MAR element and iterative transfections. Fluorescence in situ hybridization analysis often showed single integration events, indicating that DNAs introduced in successive transfections could recombine. High expression was also linked to the cell division cycle, so that nuclear transport of the DNA occurs when homologous recombination is most active. Use of cells deficient in either non-homologous end-joining or homologous recombination suggested that efficient integration and expression may require homologous recombination-based genomic integration of MAR-containing plasmids and the lack of epigenetic silencing events associated with tandem gene copies. We conclude that MAR elements may promote homologous recombination, and that cells and vectors can be engineered to take advantage of this property to mediate highly efficient gene transfer and expression.

Characterization of in vivo recombination activities in the mouse embryo

Homologous recombination makes use of sequence homology to repair DNA and to rearrange genetic material. In mammals, these processes have mainly been characterized using cultured cell systems. We have developed an assay that allows us to quantitatively analyze homologous recombination in vivo in the mouse embryo. Transgenic mouse lines were generated by microinjection into a fertilized mouse ovum of a vector containing two homologous LINE-1 (L1) sequences arranged as a direct repeat: these sequences can recombine with each other and with endogenous L1 sequences before, during or after integration of the vector into the genome. Using a plasmid rescue procedure, we determined the composition of the integrated vector array in several transgenic mice and their descendants. Homologous recombination frequencies were found to be strikingly high, involving 70% of integrated vectors in some arrays, with homologous deletions being five times more frequent than gene conversion without crossing-over. Interestingly, non-homologous recombination was found to be much less frequent. We also found that endogenous L1 sequences could be involved in homologous recombination events in the mouse embryo, and that the integrated arrays could be modified from generation to generation by homologous recombination between the integrated L1 sequences.

Illegitimate DNA integration in mammalian cells

Foreign DNA integration is one of the most widely exploited cellular processes in molecular biology. Its technical use permits us to alter a cellular genome by incorporating a fragment of foreign DNA into the chromosomal DNA. This process employs the cell's own endogenous DNA modification and repair machinery. Two main classes of integration mechanisms exist: those that draw on sequence similarity between the foreign and genomic sequences to carry out homology-directed modifications, and the nonhomologous or 'illegitimate' insertion of foreign DNA into the genome. Gene therapy procedures can result in illegitimate integration of introduced sequences and thus pose a risk of unforeseeable genomic alterations. The choice of insertion site, the degree to which the foreign DNA and endogenous locus are modified before or during integration, and the resulting impact on structure, expression, and stability of the genome are all factors of illegitimate DNA integration that must be considered, in particular when designing genetic therapies.

Recombination and its roles in DNA repair, cellular immortalization and cancer

Genetic recombination is the creation of new gene combinations in a cell or gamete, which differ from those of progenitor cells or parental gametes. In eukaryotes, recombination may occur at mitosis or meiosis. Mitotic recombination plays an indispensable role in DNA repair, which presumably directed its early evolution; the multiplicity of recombination genes and pathways may be best understood in this context, although they have acquired important additional functions in generating diversity, both somatically (increasing the immune repertoire) and in germ line (facilitating evolution). Chromosomal homologous recombination and HsRad51 recombinase expression are increased in both immortal and preimmortal transformed cells, and may favor the occurrence of multiple oncogenic mutations. Tumorigenesis in vivo is frequently associated with karyotypic instability, locus-specific gene rearrangements, and loss of heterozygosity at tumor suppressor loci - all of which can be recombinationally mediated. Genetic defects which increase the rate of somatic mutation (several of which feature elevated recombination) are associated with early incidence and high risk for a variety of cancers. Moreover, carcinogenic agents appear to quite consistently stimulate homologous recombination. If cells with high recombination arise, either spontaneously or in response to "recombinogens," and predispose to the development of cancer, what selective advantage could favor these cells prior to the occurrence of growth-promoting mutations? We propose that the augmentation of telomere-telomere recombination may provide just such an advantage, to hyper-recombinant cells within a population of telomerase-negative cells nearing their replicative (Hayflick) limit, by extending telomeres in some progeny cells and thus allowing their continued proliferation.

Suppression of tumor growth by the 3' untranslated region of mel-18 in 3Y1 cells transformed by the E6 and E7 genes of human papillomavirus type 18

By introducing a cDNA library derived from rat embryonic fibroblast cells, we isolated several morphologically flat revertants of rat 3Y1 cells transformed by the E6 and E7 genes of human papillomavirus type 18 (HPV18). From one of the revertants, we recovered a 0.2-kb cDNA, N56, that suppresses the tumor growth of the transformed 3Y1 cells irrespective of the expression of the E6 and E7 genes. The nucleotide sequence of the cDNA was shown to be identical to that of the 3' untranslated region of a putative mammalian polycomb group gene, mel-18.

ES cell cycle rates affect gene targeting frequencies

We have investigated the gene targeting frequency at the hprt locus in a range of embryonic stem cell lines selected for variations in cell cycle parameters. Our results show that targeting frequency varies with cell line by as much as 12-fold between nonisogenic lines and 3-fold between isogenic lines and that a nonisogenic line can support homologous recombination events by up to 21-fold more frequently than an isogenic line. This variation is consistent with both insertion and replacement vectors. These results can be explained by an inverse linear correlation of targeting frequencies with cell doubling times. Additionally, by reducing serum concentration in the culture medium the mean cell doubling time for R1 ES cells can be increased from 11.4 to 15.7 h, with a subsequent 15-fold decrease in gene targeting frequency. This change fits the correlation found for the different nonisogenic cell lines. Our observations have important implications when performing gene targeting experiments and explain some of the variation noted between experiments.

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.

An 'instant gene bank' method for gene cloning by mutant complementation

We describe a new method of gene cloning by complementation of mutant alleles which obviates the need for construction of a gene library in a plasmid vector in vitro and its amplification in Escherichia coli. The method involves simultaneous transformation of mutant strains of the fungus Aspergillus nidulans with (i) fragmented chromosomal DNA from a donor species and (ii) DNA of a plasmid without a selectable marker gene, but with a fungal origin of DNA replication ('helper plasmid'). Transformant colonies appear as the result of the joining of chromosomal DNA fragments carrying the wild-type copies of the mutant allele with the helper plasmid. Joining may occur either by ligation (if the helper plasmid is in linear form) or recombination (if it is cccDNA). This event occurs with high efficiency in vivo, and generates an autonomously replicating plasmid cointegrate. Transformants containing Penicillium chrysogenum genomic DNA complementing A. nidulans niaD, nirA and argB mutations have been obtained. While some of these cointegrates were evidently rearranged or consisted only of unaltered replicating plasmid, in other cases plasmids could be recovered into E. coli and were subsequently shown to contain the selected gene. The utility of this "instant gene bank" technique is demonstrated here by the molecular cloning of the P. canescens trpC gene.

An "instant gene bank" method for heterologous gene cloning: complementation of two Aspergillus nidulans mutants with Gaeumannomyces graminis DNA

We present a novel technique for gene cloning by complementation of mutations in Aspergillus nidulans with DNA from a heterologous organism, Gaeumannomyces graminis. This technique bypasses the time-consuming and difficult construction of gene libraries, making it both rapid and simple. The method relies on recombination between a fungal replicating vector pHELP1 and linear G. graminis genomic DNA during co-transformation. We were able to complement two out of seven A. nidulans mutants tested and to rescue transforming DNA from both in Escherichia coli. Complementation of the A. nidulans argB mutation resulted from integration of 8-10 kb segments of G. graminis DNA into pHELP1. The complementation of the A. nidulans pyrG mutation resulted from a complex rearrangement. Complementing DNA was shown to originate from G. graminis, and was capable of retransforming the original mutants to give the expected phenotype.

Co-transformation with autonomously-replicating helper plasmids facilitates gene cloning from an Aspergillus nidulans gene library

Autonomously-replicating, marker-less "helper" plasmids were added to transformations of Aspergillus nidulans with plasmids which normally transform by chromosomal integration. This resulted in as much as a 200-fold increase in transformation efficiency. Recovery of autonomously-replicating plasmid co-integrates indicated that co-transformation involves recombination between integrating and helper plasmids, which occurs at a high frequency. Increasing DNA sequence-homology between pairs of plasmids used in simultaneous transformations enhanced co-transformation efficiency. Using helper plasmids and an A. nidulans gene library in a normally-integrating vector, the genes adC and adD were cloned as part of such a co-integrate. In effect, the addition of helper plasmid converts an integrating into an autonomously-replicating gene library in vivo.

Intermolecular ligation mediates efficient cotransformation in Phytophthora infestans

The processing of DNA molecules during transformation was characterized in the oomycete Phytophthora infestans. Linear and circular forms of non-replicating transformation vectors supported similar rates of stable transformation. Remarkably, digestion of plasmids within the selectable marker genes neomycin phosphotransferase (npt) or hygromycin phosphotransferase (hpt) had little effect on the recovery of drug-resistant transformants, and the cleaved sites were shown to be reconstituted in the transformants. An assay for the transient expression of beta-glucuronidase (GUS) in protoplasts treated with partial or disrupted GUS genes demonstrated that active genes could be reconstituted through intramolecular and/or intermolecular ligation between compatible ends, while incompatible ends were inefficiently joined. Stable transformation studies also demonstrated that complementing portions of incomplete npt or hpt genes joined through homologous recombination. Based on the indication of efficient ligation between DNA molecules during transformation, an efficient procedure for cotransformation was developed. The frequency of cotransformation between vectors expressing selected genes (npt or hpt) and nonselected sequences (GUS, beta-galactosidase, or streptomycin phosphotransferase) approached unity when the plasmids were linearized with the same restriction enzyme before transformation. In contrast, cotransformation between circular plasmids or those cut with different enzymes occurred infrequently (10%). Hybridization analysis of DNA from cotransformants demonstrated that linearized plasmids became colocalized within genomic DNA, while circular plasmids typically inserted at unliked sites.

Transformation of the oomycete pathogen Phytophthora megasperma f. sp. glycinea occurs by DNA integration into single or multiple chromosomes

A procedure for stable transformation was developed for Phytophthora megasperma f. sp. glycinea, an oomycete pathogen of soybean. Transformants were obtained using a bacterial hygromycin resistance gene fused to a promoter and terminator from the ham34 gene of another oomycete, Bremia lactucae. Vector DNA, alone or complexed to cationic liposomes, was introduced into protoplasts using polyethylene glycol and CaCl2. DNA and RNA hybridization, and phosphotransferase assays, confirmed the presence and expression of vector DNA in the transformants. Hybridization to electrophoretically separated chromosomes of P. m. glycinea showed that vector DNA had integrated into only one chromosome in four transformants, and into multiple chromosomes in one transformant.

Reconstitution of an episomal mouse aprt gene as a consequence of recombination

When a functional murine adenine phosphoribosyltransferase (aprt) gene linked to bovine papilloma virus (BPV) DNA is transfected into Aprt- L cells, the cells are rendered Aprt+ and the aprt gene persists as an episome. Cotransfection with two BPV vectors, one containing the 5' half of the aprt gene and the other the 3' half of the gene, that share about 300 bp of common sequence in intron 2, produces Aprt+ cells with functional aprt as an episome. Southern blot analysis of low molecular weight DNA derived from Hirt extracts revealed the regeneration of a diagnostic SmaI fragment, consistent with establishment of an episome with functional aprt that was reconstituted as a consequence of recombination. To establish cells with an episomal target for recombination, BPV vectors containing a G418 resistance marker and either the 5' half or 3' half of aprt were transfected into Aprt- L cells. Stably transfected cells, selected by their growth in G418, were in turn transfected with DNA containing the other half of the aprt gene. Following selection of Aprt+ cells, Southern blot and polymerase chain reaction (PCR) analysis of low molecular weight DNA confirmed the presence of a complete episomal aprt gene. The region of DNA shared by the episomal aprt fragment and the transfected aprt half was sequenced after PCR amplification of the reconstituted, episomal gene and was found to be wild type. The region of overlap that serves as the substrate for recombination lies entirely within an intron and can, therefore, tolerate nucleotide substitutions and deletions. The absence of such errors in the sequences examined is consistent with recombination events that are not error prone.

Extrachromosomal recombination is deranged in the rec2 mutant of Ustilago maydis

Transformation of a leu1 auxotroph of Ustilago maydis to prototrophy with an autonomously replicating plasmid containing the selectable LEU1 gene was found to be efficient regardless of whether the transforming DNA was circular or linear. When pairs of autonomously replicating plasmids bearing noncomplementing leu1 alleles were used to cotransform strains deleted entirely for the genomic copy of the LEU1 gene, Leu+ transformants were observed to arise by extrachromosomal recombination. The frequency of recombination increased severalfold when one plasmid of the pair was made linear by cleavage at one end of the leu1 gene, but increased 10-100-fold when both plasmids were first made linear. The increase in recombination noted in wild-type and rec1 strains was not apparent in the rec2 mutant unless the members of the pair of plasmids were cut at opposite ends of the leu1 gene to yield linear molecules offset in only one of the two possible configurations. Use of a pair of plasmid substrates designed to measure nonreciprocal and multiple exchange events revealed only a minor fraction of the total events arise through these modes, and further that no stimulation occurred when the plasmid DNA was linear. It is unlikely that the defect in rec2 lies in a mismatch correction step since a high yield of Leu+ recombinants was obtained from the rec2 mutant when it was transformed with heteroduplex DNA constructed from plasmids with the two different leu1 alleles.

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.

The mechanism of extrachromosomal homologous DNA recombination in plant cells

By cotransfecting plasmids carrying particular mutations in the beta-glucuronidase (GUS) gene into Nicotiana plumbaginifolia protoplasts and by monitoring the recombination rates using a recently developed transient assay, we were able to obtain insights into the mechanism of extrachromosomal recombination operating in plant cells. An exchange of flanking markers takes place in over 90% of the recombination events. In most of the remaining cases two consecutive, independent single crossover events occur. These events involve the same DNA substrate and lead to two successive exchanges of flanking markers, thus mimicking a presumed double crossover intermediate. A comparison of the outcome of our experiments with the predictions of two recombination models originally proposed for mammalian cells indicates that extrachromosomal recombination in plant cells is best described by the single strand annealing model. According to this model all recombination events result in an exchange of flanking markers. Our results rule out the double strand break repair model which predicts that flanking markers are exchanged in only half of all events.

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.

Transformation-defective mutants with 5' deletions of the src gene are frequently generated during replication of Rous sarcoma virus in established quail fibroblasts

Replication of Rous sarcoma virus (RSV) in avian fibroblasts leads to the generation of replication-competent variants that are defective for cell transformation (td virus). These td variants contain deletions affecting various portions of the v-src gene. We compared the rate of td virus production in Q3B cells, a quail cell line established by mutagen treatment, and in normal quail fibroblasts. Twenty-five days after infection with an RSV stock containing only transforming virions, Q3B cells harbor similar amounts of v-src-containing and v-src-deleted proviruses. However, these cells synthesize very low levels of p60v-src and generate large excess of td variants, as determined by biological assays. Unlike Q3B cells, normal quail fibroblasts infected with the same virus stock produce td variants only after multiple passages of undiluted virus on fresh cells. Restriction analysis showed that the td virus produced by Q3B cells is composed of two types of genomes: one lacking the entire v-src gene and the other carrying partial deletions of this gene predominantly located in the amino-terminal portion of the coding region of v-src. To study the mechanisms of these partial deletions, we molecularly cloned and sequenced the v-src genes of several td proviruses. We show that these mutants carry single or multiple v-src deletions of limited size, presumably generated by multiple mechanisms. Two deletions of 170 and 112 bp located in the 5' portion of v-src are frequently generated during RSV replication in Q3B cells and may represent preferential sites for v-src deletion in these cells.

Relative frequencies of homologous recombination between plasmids introduced into DNA repair-deficient and other mammalian somatic cell lines

Twelve mammalian somatic cell lines, some of them DNA damage-sensitive mutants paired with their respective wild-type parental lines, were assayed for their ability to catalyze extrachromosomal, intermolecular homologous recombination between pSV2neo plasmid recombination substrates. All of the somatic cell lines analyzed are capable of catalyzing homologous recombination; however, there is a wide range of efficiencies with which they do so. Five human cell lines display a fourfold range of recombination frequencies, and six hamster cell lines vary almost 20-fold. Linearizing one of the recombination substrates stimulates recombination in all but one of the cell lines. Two of the three paired mutant cell lines display a threefold reduction in their ability to catalyze homologous recombination when compared to their respective parental cell lines, indicating that the mutations that render them sensitive to DNA damaging agents might also play a role in homologous recombination.

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.

Hypervariable minisatellite DNA is a hotspot for homologous recombination in human cells

Hypervariable minisatellite DNA sequences are short tandemly repeated sequences that are present throughout the human genome and are implicated to enhance recombination. We have constructed a consensus hypervariable minisatellite sequence and analyzed its effect on homologous recombination in human cells in culture. The consensus sequence d(AGAGGTGGGCAGGTGG)6.5 is shown to stimulate homologous recombination up to 13.5-fold. The stimulation occurs at a distance and in both directions but does show a quantitative directionality. Stimulation occurs in a codominant manner, and the sequence is inherited equally in the products. Enhancement is maintained, but at a reduced level, when double-strand breaks are introduced into the substrates. Multiple unselected recombination events are promoted, and preferential stimulation of reciprocal exchange events is demonstrated.

A genetic investigation of the mechanism of adenovirus marker rescue

We have developed quantitative and segregational methods for investigating the mechanism of genetic exchange in adenovirus marker rescue. Estimates of "marker rescue frequency" (m.r.f.) were used to show that marker rescue increases linearly with increasing dose of fragment up to equimolarity with the full-length genome. The m.r.f. is also affected by the size of the rescuing fragment and the position of the wild-type allele within it, regardless of whether the fragment is terminal or internal. This is compatible with marker rescue being based on homologous exchange between the recombining partners. Examination of individually transfected cells showed that there is very wide variability in the values of the m.r.f.'s. This suggests that marker transfer can occur after replication of the full-length genome has begun, and can occur late into the infectious cycle. Unselected markers on the rescuing fragment were shown to be co-inherited frequently. This suggests that physical linkage is accompanied by genetic linkage. To examine this more closely, a multifactorial marker rescue was performed. The data show unequivocally that markers resident on the same fragment as the selected allele are inherited at high frequency, with a gradient of transfer in which markers closest to the selected marker are transferred most frequently. Markers up to 13 and perhaps as many as 17 kb apart can be inherited together. There are very few examples of the inheritance of distal markers in the absence of proximal ones. These data suggest that large pieces of DNA are transferred in a concerted reaction during marker rescue.

Infectivity of vesicles prepared from chilo iridescent virus inner membrane: evidence for recombination between associated DNA fragments

Treatment of CIV particles with octylglucoside at high ionic strength leads to the solubilization of the inner viral membrane. Incubation of permissive cells (Cf124 cells) with vesicles obtained after dialysis of the detergent shows that this fraction is infectious. This infectivity, which is very low, could only be detected after two serial passages on permissive cells. This phenomenon is, however, reproducible. Isopycnic centrifugation analysis shows that some DNA cosediments with the vesicles. Extraction and purification of this DNA confirm the presence of a large DNA fragment of about 50.10(6) Da. Digestion with restriction endonucleases demonstrated that this DNA did not correspond to a particular fragment but to a population of DNA fragments of homogeneous size arising from various regions of the viral genome. Purified viral DNA was not infectious, the presence of DNA in the vesicles could not account therefore for their infectivity. Experiments of non-genetic reactivation of purified CIV DNA by UV-irradiated virus suggest that one (or several) structural component(s) of CIV particles must be involved in the first stages of the viral replication cycle. In addition, transfection of cells with large overlapping DNA fragments could generate infectious particles when the cells were superinfected with UV-irradiated virus. It can be supposed that the vesicle suspensions, which probably contain the reactivating factor, are composed of a population of vesicles which are all different in their DNA content. Infectivity of such suspensions would be the consequence of a recombination between large overlapping DNA fragments.

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.

Effect of DNA damage on stable transformation of mammalian cells with integrative and episomal plasmids

The efficiency of stable transformation of human cells by integrative (non-replicating) plasmids carrying a selectable gene has been shown to be markedly enhanced by the introduction into the plasmid DNA of bulky damage, such as cyclobutane pyrimidine dimers or psoralen photoadducts. Enhanced transformation (ET) occurs in all human cells tested, including DNA repair-deficient cells from the hereditary syndrome xeroderma pigmentosum, but significantly less, if at all, in rodent cells. ET has been observed with a variety of integrative plasmid constructs, suggesting the generality of the phenomenon; as expected, ET is due to an increase in the number of cells carrying integrated plasmid sequences. In contrast to integrative plasmids, stable transformation by episomal (autonomously replicating) plasmids derived from the Epstein-Barr virus is only depressed by the introduction of photoproducts; furthermore, pronounced inactivation of transformation mediated by episomal plasmids becomes apparent in xeroderma pigmentosum cells. Altogether, these results suggest that DNA damage increases the probability of stable insertion of heterologous non-replicating DNA into human chromosomes. Moreover, the differential sensitivity to DNA damage of human cell transformation mediated by integrative versus episomal plasmids suggests caution in using such assay to measure host cell reactivation capacity; processing of DNA damage in mammalian cells might differ significantly between intra- versus extra-chromosomal DNA. Since ET may be induced by damage outside the selectable gene carried on integrative plasmids, we propose a model that involves local disruption of chromatin structure by helix-distorting DNA lesions flanking actively transcribed sequences; alternatively, reorganization of such altered DNA structure might be favored by the presence of topoisomerase-like activities in the proximity of active genes. Because ET can also be induced by DNA damage to the recipient cells, it is speculated that similar mechanism(s) might be involved in the generation of other types of non-homologous DNA recombination in damaged human chromosomes, including oncogenic cell transformation mediated by integrative DNA viruses.

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.

A ras-related gene with transformation suppressor activity

A 1.8 kb cDNA clone, Krev-1, with revertant-inducing activity on Kirsten sarcoma virus-transformed NIH/3T3 cells, has been isolated from a human fibroblast cDNA expression library. In Krev-1 transfectants, there is a correlation between the levels of specific mRNA and the degrees of suppression of the transformed phenotype. The cDNA encodes a protein of 21,000 daltons that unexpectedly shares around 50% amino acid identities with ras proteins. The Krev-1 homologs are found in mouse, rat, and chicken DNA, and their transcripts are ubiquitously expressed in many rat organs. Thus, the Krev-1 gene seems to play an important role(s) in a wide variety of tissues, and may be involved in the negative growth regulation of certain cell types.

Transformation depending on intermolecular homologous recombination is stimulated by UV damage in transfected DNA

DNA-mediated gene transfer (DMGT) was performed in DNA repair-proficient and UV-hypersensitive, repair-deficient Chinese hamster ovary (CHO) cell lines using the UV-irradiated thymidine kinase gene from herpes simplex virus (HSV-TK). Transformation frequencies in repair-deficient CHO cell lines declined relative to repair-proficient cells with increasing UV damage in transfected DNA; approximately 3-fold higher UV fluence was required to inactivate 50% of irradiated HSV-TK plasmid molecules in repair-proficient cells. In cotransfection experiments performed with pairs of HSV-TK plasmids containing linker insertion mutations in TK coding sequences, moderate UV damage in plasmid DNA enhanced the yield of TK+ transformants resulting from homologous recombination between HSV-TK sequences up to 4-fold. These results suggest that UV damage in DNA can stimulate transformation of mammalian cells dependent on intermolecular DNA homology.

Transient gene expression in tobacco protoplasts: I. Time course of CAT appearance

The early events of transient gene expression have been investigated monitoring CAT activity in tobacco protoplasts encoded by the recombinant plasmid pRT101cat. The first appearance of CAT activity was observed within 30 minutes after the outset of cultivation, and maximal values were obtained between four and 24 hours. CAT expression, at the level of RNA synthesis, could not be inhibited by cordycepin (3'deoxyadenine) added one hour after protoplast plating, whereas cycloheximide, an inhibitor of protein synthesis, showed an influence during the first four hours. This indicates a rapid decay of biologically active forms of both the DNA transferred and the CAT-mRNA synthesized within the first hours. These results suggest that in the tobacco protoplast system CAT protein stability lasts up to two weeks rather than a continuous synthesis of new enzyme.

Phleomycin resistance as a dominant selectable marker in CHO cells

The Tn5 and the Streptoalloteichus hindustanus (Sh) ble genes conferring resistance to bleomycin-phleomycin antibiotics have been cloned into a mammalian vector under the RSV-LTR promoter. The resulting plasmids, pUT506 and pUT507 respectively, were used to transfect CHO cells by either the calcium phosphate or the recently described polybrene-DMSO method. Phleomycin- or bleomycin-resistant clones arose with a higher frequency after transfection with pUT507, and pUT507 transfectants were more resistant to both antibiotics than pUT506 transfectants. Phleomycin resistance in pUT507 transfectants was stable and associated with integration of plasmid sequences in genomic DNA. The Sh ble gene, which confers a dominant phleomycin-resistance phenotype, should provide a useful transferable selectable marker in CHO cells as well as in other animal cell lines.

Extensive microheterogeneity of serine tRNA genes from Drosophila melanogaster

The nucleotide sequences of nine genes corresponding to tRNA(Ser)4 or tRNA(Ser)7 of Drosophila melanogaster were determined. Eight of the genes compose the major tRNA(Ser)4,7 cluster at 12DE on the X chromosome, while the other is from 23E on the left arm of chromosome 2. Among the eight X-linked genes, five different, interrelated, classes of sequence were found. Four of the eight genes correspond to tRNA(Ser)4 and tRNA(Ser)7 (which are 96% homologous), two appear to result from single crossovers between tRNA(Ser)4 and tRNA(Ser)7 genes, one is an apparent double crossover product, and the last differs from a tRNA(Ser)4 gene by a single C to T transition at position 50. The single autosomal gene corresponds to tRNA(Ser)7. Comparison of a pair of genes corresponding to tRNA(Ser)4 from D. melanogaster and Drosophila simulans showed that, while gene flanking sequences may diverge considerably by accumulation of point changes, gene sequences are maintained intact. Our data indicate that recombination occurs between non-allelic tRNA(Ser) genes, and suggest that at least some recombinational events may be intergenic conversions.

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.

Introduction of homologous DNA sequences into mammalian cells induces mutations in the cognate gene

Injection of homologous DNA sequences into nuclei of cultured mammalian cells induces mutations in the cognate chromosomal gene. It appears that these mutations result from incorrect repair of a heteroduplex formed between the introduced and the chromosomal sequence. This phenomenon is termed 'heteroduplex induced mutagenesis'. The high frequency of these events suggests that this method may prove useful for introducing mutations into specific mammalian genes.

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.