A DNA-recombinogenic activity in human cells

Anti-(U1)snRNP autoantibodies inhibit homologous pairing activity of the human recombination complex

The co-purification of the U1snRNP particle with a high-molecular-weight human homologous pairing activity has been observed consistently. Using human autoimmune sera directed against various snRNPs, it has been found that autoantibody binding to antigenic determinants specifically associated with the U1snRNP particle inhibits the formation of paired DNA molecules by the human homologous pairing activity. Immunoprecipitation of U1snRNP with anti-(U1)RNP autoantibodies significantly reduced the homologous pairing activity in these fractions. NaDodSO4-PAGE analysis of immunoprecipitated samples has revealed their content to be mostly composed of anti-(U1)RNP precipitable material. Taken together, these results suggest that some biochemical reactions in the process of homologous pairing promoted by high-molecular-weight complex are dependent upon U1snRNP components. It is postulated that the U1snRNP may be associated with the recombination complex in human cells.

Isolation of multiple activities from mouse FM3A cells which promote homologous pairing of DNA molecules

We describe the detection and partial purification of three homologous pairing activities from extracts of mouse mammary carcinoma FM3A cells. These activities, designated MHP1a, 1b, and 1c, form joint molecules between circular single-stranded DNA and homologous linear duplex DNA and are distinguished from one another by their chromatographic behaviors or isoelectric properties. The reactions promoted by these activities require homologous substrates but not ATP. All the reactions also show Mg2+ dependence in the absence of exogenous ATP. Analysis of the reaction products has revealed that strand exchange proceeds for lengths of up to at least 271 bp during the homologous pairing reaction. The finding of multiple types of homologous pairing and strand exchange activity in mouse cells may facilitate the elucidation of the mechanism of homologous recombination in somatic mammalian cells.

International Commission for Protection against Environmental Mutagens and Carcinogens. Recombination and gene conversion

Recombination is an important aspect of DNA metabolism. It leads to rearrangements of DNA sequences within genomes. Such genome rearrangements seem to be ubiquitous, since they play a role in evolution, human health and biotechnology. In medicine one important aspect of recombination is its role as one possible step in the multistep process of carcinogenesis. Since recombination may occur as a cellular response to DNA damage, the protection of cells from recombination-inducing agents, so-called recombinagen, should eliminate possible deleterious effects resulting from damage-induced DNA recombination. During the last few years, the awareness of the importance of recombination phenomena has substantially increased and the development of assay systems detecting recombinagens has progressed. The need for considering recombinagenic effects as a safety aspect of chemicals has gained ground in the field of genetic toxicology. This paper summarizes present knowledge concerning the occurence, inducibility, detection and toxicological interpretation of DNA recombination.

Repair of deletions and double-strand gaps by homologous recombination in a mammalian in vitro system

We have designed an in vitro system using mammalian nuclear extracts, or fractions derived from them, that can restore the sequences missing at double-strand breaks (gaps) or in deletions. The recombination substrates consist of (i) recipient DNA, pSV2neo with gaps or deletions ranging from 70 to 390 bp in the neo sequence, and (ii) donor DNAs with either complete homology to the recipient (pSV2neo) or plasmids whose homology with pSV2neo is limited to a 1.0- to 1.3-kbp neo segment spanning the gaps or deletions. Incubation of these substrates with various enzyme fractions results in repair of the recipient DNA's disrupted neo gene. The recombinational repair was monitored by transforming recA Escherichia coli to kanamycin resistance and by a new assay which measures the extent of DNA strand transfer from the donor substrate to the recipient DNA. Thus, either streptavidin- or antidigoxigenin-tagged beads are used to separate the biotinylated or digoxigeninylated recipient DNA, respectively, after incubation with the isotopically labeled donor DNA. In contrast to the transfection assay, the DNA strand transfer measurements are direct, quantitative, rapid, and easy, and they provide starting material for the characterization of the recombination products and intermediates. Accordingly, DNA bound to beads serves as a suitable template for the polymerase chain reaction. With appropriate pairs of oligonucleotide primers, we have confirmed that both gaps and deletions are fully repaired, that deletions can be transferred from the recipient DNA to the donor's intact neo sequence, and that cointegrant molecules containing donor and recipient DNA sequences are formed.

An overview of homologous pairing and DNA strand exchange proteins

Processes fundamental to all models of genetic recombination include the homologous pairing and subsequent exchange of DNA strands. Biochemical analysis of these events has been conducted primarily on the recA protein of Escherichia coli, although proteins which can promote such reactions have been purified from many sources, both prokaryotic and eukaryotic. The activities of these homologous pairing and DNA strand exchange proteins are either ATP-dependent, as predicted based on the recA protein paradigm, or, more unexpectedly, ATP-independent. This review examines the reactions promoted by both classes of proteins and highlights their similarities and differences. The mechanistic implications of the apparent existence of 2 classes of strand exchange protein are discussed.

Saccharomyces cerevisiae proteins involved in hybrid DNA formation in vitro

RecA-like activities that can form hybrid DNA in vitro have been identified in a wide variety of organisms. We have previously described the strand exchange protein 1 (SEP1) from the yeast Saccharomyces cerevisiae that can form hybrid DNA in vitro. Purified as an Mr 132,000 polypeptide, recent molecular and immunological studies have now shown that the native form is an Mr 175,000 polypeptide containing strand exchange activity. The gene encoding SEP1 has been cloned and sequenced. The primary sequence failed to reveal any significant sequence homology to other sequences in data base searches. In vivo SEP1 was found to be essential for normal meiosis as cells containing a homozygous insertion mutation in the SEP1 gene failed to sporulate. In order to identify additional factors that are involved in hybrid DNA formation in S cerevisiae, we used an in vitro stimulation assay to identify proteins that reconstitute strand exchange activity in reactions containing limiting amounts of SEP1. We have identified two proteins that functionally interact with SEP1. First, an Mr 34,000 single-stranded DNA binding protein stimulated the reaction by lowering the requirement for SEP1 about 3-4 fold. This protein is a fragment of the large subunit of a hetero-trimeric complex called yRP-A (yRF-A) which is thought to be the functional eukaryotic equivalent of single-stranded DNA binding proteins in prokaryotes. The gene encoding this protein (RPA1) is essential for growth. Second, an Mr 33,000 polypeptide, termed Stimulatory Factor 1 (SF1), dramatically stimulated the SEP1 catalyzed reaction by lowering the requirement for SEP1 about 300 fold.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of nonconservative homologous junctions in mammalian cells

Homologous recombination in mammalian cells between extrachromosomal molecules, as well as between episomes and chromosomes, can be mediated by a nonconservative mechanism. It has been proposed that the key steps in this process are the generation (by double-strand cleavage) of overlapping homologous ends, the creation of complementary single-strand ends (either by strand-specific exonuclease degradation or by unwinding of the DNA helix), and finally the creation of heteroduplex DNA by the annealing of the single-strand ends. We have analyzed in detail the structure of nonconservative homologous junctions and determined the contribution of each end to the formation of the junction. We have also analyzed multiple descendants from single recombination events. Two types of junctions were found. The majority (90%) of the junctions were characterized by a single crossover site. These crossover sites were distributed randomly throughout the junction. The remaining 10% of the junctions had mosaic patterns of parental markers. Furthermore, in 9 of 10 cases, multiple descendants from a single recombination event were identical. Thus, it appears that in most cases few parental markers were involved in junction formation. This finding suggests that nonconservative homologous junctions are mediated mainly by short heteroduplexes of a few hundred base pairs or less. These results are discussed in terms of the current models of nonconservative homologous recombination.

Caffeine-induced reduction of the survival of gamma-irradiated HeLa cells and the reversal of the caffeine effect by Escherichia coli RecA protein

It is confirmed that survival of gamma-irradiated HeLa cells is decreased by post-treatment with caffeine. The caffeine effect is believed to be the result of an inhibition of the repair of gamma-ray-induced DNA damage. In this work we show that the caffeine-induced reduction of the survival of gamma-irradiated HeLa cells is reversed when Escherichia coli RecA protein is introduced into the cells with the aid of liposomes.

Repair of deletions and double-strand gaps by homologous recombination in a mammalian in vitro system

We have designed an in vitro system using mammalian nuclear extracts, or fractions derived from them, that can restore the sequences missing at double-strand breaks (gaps) or in deletions. The recombination substrates consist of (i) recipient DNA, pSV2neo with gaps or deletions ranging from 70 to 390 bp in the neo sequence, and (ii) donor DNAs with either complete homology to the recipient (pSV2neo) or plasmids whose homology with pSV2neo is limited to a 1.0- to 1.3-kbp neo segment spanning the gaps or deletions. Incubation of these substrates with various enzyme fractions results in repair of the recipient DNA's disrupted neo gene. The recombinational repair was monitored by transforming recA Escherichia coli to kanamycin resistance and by a new assay which measures the extent of DNA strand transfer from the donor substrate to the recipient DNA. Thus, either streptavidin- or antidigoxigenin-tagged beads are used to separate the biotinylated or digoxigeninylated recipient DNA, respectively, after incubation with the isotopically labeled donor DNA. In contrast to the transfection assay, the DNA strand transfer measurements are direct, quantitative, rapid, and easy, and they provide starting material for the characterization of the recombination products and intermediates. Accordingly, DNA bound to beads serves as a suitable template for the polymerase chain reaction. With appropriate pairs of oligonucleotide primers, we have confirmed that both gaps and deletions are fully repaired, that deletions can be transferred from the recipient DNA to the donor's intact neo sequence, and that cointegrant molecules containing donor and recipient DNA sequences are formed.

Characterization of nonconservative homologous junctions in mammalian cells

Homologous recombination in mammalian cells between extrachromosomal molecules, as well as between episomes and chromosomes, can be mediated by a nonconservative mechanism. It has been proposed that the key steps in this process are the generation (by double-strand cleavage) of overlapping homologous ends, the creation of complementary single-strand ends (either by strand-specific exonuclease degradation or by unwinding of the DNA helix), and finally the creation of heteroduplex DNA by the annealing of the single-strand ends. We have analyzed in detail the structure of nonconservative homologous junctions and determined the contribution of each end to the formation of the junction. We have also analyzed multiple descendants from single recombination events. Two types of junctions were found. The majority (90%) of the junctions were characterized by a single crossover site. These crossover sites were distributed randomly throughout the junction. The remaining 10% of the junctions had mosaic patterns of parental markers. Furthermore, in 9 of 10 cases, multiple descendants from a single recombination event were identical. Thus, it appears that in most cases few parental markers were involved in junction formation. This finding suggests that nonconservative homologous junctions are mediated mainly by short heteroduplexes of a few hundred base pairs or less. These results are discussed in terms of the current models of nonconservative 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.

ATP-independent strand transfer protein from murine spermatocytes, spermatids, and spermatozoa

A protein-catalyzing D-loop formation is present in murine spermatocytes, spermatids, and spermatozoa, but is not found in somatic tissue or in premeiotic cells of the germline. Unlike the Escherichia coli RecA protein and the meiotic rec protein (m-rec) previously described, D-loop formation by this protein (referred to as "mAi-rec") does not require ATP. The meiotic profile of mAi-rec activity is only partly similar to that of m-rec. Like m-rec, it rises steeply during early prophase and reaches a peak at pachytene. Unlike m-rec, its activity remains high during the postmeiotic phase of spermatid development and is prominent in immunochemically stained spermatozoa. A polyclonal antibody to E. coli RecA reacts with mAi-rec and inhibits its activity. No such reaction occurs with m-rec protein. The extent of sequence homology between E. coli RecA and murine mAi-rec is highly limited; none of the several monoclonal antibodies tested reacted with mAi-rec.

Recombination between irradiated shuttle vector DNA and chromosomal DNA in African green monkey kidney cells

An autonomously replicating shuttle vector was used to investigate enhancement of plasmid-chromosome recombination in mammalian host cells by gamma irradiation and UV light. Sequences homologous to the shuttle vector were stably inserted into the genome of African green monkey kidney cells to act as the target substrate for these recombination events. The shuttle vector molecules were irradiated at various doses before transfection into the mammalian host cells that contained the stable insertions. The homologous transfer of the bacterial ampicillin resistance gene from the inserted sequences to replace a mutant ampicillin sensitivity gene on the shuttle vector was identified by the recovery of ampicillin-resistant plasmids after Hirt extraction and transformation into Escherichia coli host cells. Gamma irradiation increased homologous shuttle vector-chromosome recombination, whereas UV light did not increase the frequency of recombinant plasmids detected. Introducing specific double-strand breaks in the plasmid or prolonging the time of plasmid residence in the mammalian host cells also enhanced plasmid-chromosome recombination. In contrast, plasmid mutagenesis was increased by UV irradiation of the plasmid but did not change with time. The ampicillin-resistant recombinant plasmid molecules analyzed appeared to rise mostly from nonconservative exchanges that involved both homologous and possibly nonhomologous interactions with the host chromosome. The observation that similar recombinant structures were obtained from all the plasmid treatments and host cells used suggests a common mechanism for plasmid-chromosome recombination in these mammalian cells.

Recombination between irradiated shuttle vector DNA and chromosomal DNA in African green monkey kidney cells

An autonomously replicating shuttle vector was used to investigate enhancement of plasmid-chromosome recombination in mammalian host cells by gamma irradiation and UV light. Sequences homologous to the shuttle vector were stably inserted into the genome of African green monkey kidney cells to act as the target substrate for these recombination events. The shuttle vector molecules were irradiated at various doses before transfection into the mammalian host cells that contained the stable insertions. The homologous transfer of the bacterial ampicillin resistance gene from the inserted sequences to replace a mutant ampicillin sensitivity gene on the shuttle vector was identified by the recovery of ampicillin-resistant plasmids after Hirt extraction and transformation into Escherichia coli host cells. Gamma irradiation increased homologous shuttle vector-chromosome recombination, whereas UV light did not increase the frequency of recombinant plasmids detected. Introducing specific double-strand breaks in the plasmid or prolonging the time of plasmid residence in the mammalian host cells also enhanced plasmid-chromosome recombination. In contrast, plasmid mutagenesis was increased by UV irradiation of the plasmid but did not change with time. The ampicillin-resistant recombinant plasmid molecules analyzed appeared to rise mostly from nonconservative exchanges that involved both homologous and possibly nonhomologous interactions with the host chromosome. The observation that similar recombinant structures were obtained from all the plasmid treatments and host cells used suggests a common mechanism for plasmid-chromosome recombination in these mammalian cells.

Modifications of the effect of bleomycin in the somatic mutation and recombination test in Drosophila melanogaster

Exposure to oxygen has been implicated as an important mechanism of mutations, cancer and aging. Most data supporting this notion have been obtained in vitro, but the elaborate defense systems against oxygen stress in aerobic organisms make it difficult to extrapolate in vitro data to in vivo conditions. In the present investigation the somatic mutation and recombination test (SMART) in Drosophila with the wing spot system (Graf et al., 1984) has been used as an in vivo system to study the effect of oxygen radicals generated by bleomycin (BLM). BLM causes a dose-related increase of wing spots and this effect drastically increases by increasing oxygen in the atmosphere to 70%. Data from treatment of larvae of different ages, as well as post-treatment with oxygen, indicate that BLM can persist, presumably intercalated in DNA, and subsequently be activated by oxygen to generate free radicals. By the use of inversion heterozygosity, which eliminates somatic recombination, it was shown that the majority of wing spots induced by BLM emanate from somatic recombination. A small number of flies deviated from the rest by an abnormally high frequency of BLM-induced wing spots. Preliminary results from a selection of such flies indicate that this extreme response to BLM is genetically determined. Treatment with BLM was also combined with agents known to interfere with the defense mechanisms against radicals or function as radical scavengers. Only ascorbic acid cotreatment had a modifying effect on BLM mutagenicity. The other agents did not alter or at most had a marginal effect on BLM mutagenicity. These data indicate that the defense mechanisms do not constitute a limiting factor in this case. BLM intercalates between DNA bases, presumably giving little time and opportunity for modifying agents to react with radicals generated in direct contact with the gene targets. No effect of BLM was observed on male germ cells by measuring loss and non-disjunction of ring-X/Y, neither in air nor in a 70% oxygen atmosphere.

Calf thymus histone H1 is a recombinase that catalyzes ATP-independent DNA strand transfer

An activity that catalyzes the strand transfer from linear double-stranded tetracycline-resistance gene (tetr) DNA to circular M13mp8-tetr viral DNA was detected in a crude extract from calf thymus. This activity was purified to near, if not complete, homogeneity as judged by NaDodSO4/polyacrylamide gel electrophoresis. We have tentatively named this protein calf thymus strand-transfer protein 1 (CTST1). The apparent molecular mass of the protein was 35 kDa by gel electrophoresis. Its sedimentation coefficient was approximately 1.5 S in glycerol gradient centrifugation. These values led us to examine the possibility that CTST1 is histone H1. Western blot analysis of CTST1 with anti-rat liver histone H1 antiserum showed that CTST1 crossreacts with the serum, indicating that CTST1 is histone H1. The mobility of CTST1 was identical to one of the subtypes of calf thymus histone H1 by NaDodSO4/polyacrylamide gel and acetic acid/urea/polyacrylamide gel electrophoreses. We have also confirmed the above conclusion by showing that calf thymus histone H1 has a strand-transfer activity with a specific activity comparable to that of CTST1. The reaction required homologous substrates, but neither Mg2+ nor ATP. The reaction also required stoichiometric amounts of protein. The purified CTST1 fraction lacked detectable exo- and endonuclease activities and also lacked a DNA helicase activity.

A recombination hotspot in the LTR of a mouse retrotransposon identified in an in vitro system

The recombinational frequency between two long terminal repeat elements (LTR-IS) of a mouse retrotransposon was about 13 times higher, compared with that of two control DNA sequences in extracts from mouse testes, but not in extracts from ascites cells. Deletion of a 37 bp region from the LTR-IS element strongly suppresses its recombinational activity. This 37 bp region encompasses an area of potentially single-stranded DNA and interacts with at least two nuclear proteins. One of them binds sequence-specifically to single-stranded DNA and is present in both types of extracts. Another protein(s) binds to dsDNA at the motif TGGAAATCCCC and is absent in extracts from testes. Our results suggest that a cis-acting DNA sequence within the 504 bp LTR-IS element is responsible for its high recombinational activity in vitro, and they further support the previous suggestion that the LTR-IS elements are meiotic recombinational hotspots in vivo.

Molecular analysis of homologous recombination catalysed by human nuclear extract: fidelity and DNase protection

We present a molecular analysis of DNA's resulting from homologous recombination, between two duplex molecules, and catalysed by human nuclear extracts. Sequence analysis of 20 recombined clones (400 nucleotides per clone), in a genetically silent sequence surrounding the recombination initiation or termination site, shows no modification compared to the parental sequence. Transient protection of the DNA's against DNase treatment was brought about by the nuclear extract. This protection was found to be strickly confined to the homologous sequences potentially implicated in recombination.

Bloom's syndrome. XII. Report from the Registry for 1987

Bloom's syndrome has been known as a clinical entity for 34 years. Careful records of cases diagnosed throughout the world have been maintained since its recognition as an entity, and most instances of cytologically verified Bloom's syndrome have been accessioned to what has been referred to as the Bloom's Syndrome Registry since the mid-1960s. Presented here is the fourth in a series of progress reports from the Registry of information accumulated during this long-term surveillance of affected families, along with mention of selected recent advances that have been made in the understanding of the syndrome. 130 persons had been accessioned to the Registry by the end of 1987; 96 of these were alive, their mean age being 18.9 years. Although a number of clinical complications occur in Bloom's syndrome, the most important is malignant neoplasia. In the 130 persons in the Registry, 57 malignant neoplasms had been detected, the mean age at diagnosis being 24.8 years. Neoplasia in Bloom's syndrome is noteworthy not only because of its frequency and exceptionally early age of emergence but for its variety of histological types and sites of origin.

A recombinase from Drosophila melanogaster embryos

We have partially purified a DNA strand-exchange activity (recombinase) from nuclear extracts of Drosophila melanogaster embryos. The protein fraction forms a joint molecule between a circular single-strand DNA and a homologous linear duplex DNA that is resolved from the substrates by agarose gel electrophoresis. A strand-exchange activity can be obtained from nuclear extracts from embryos as old as 24 hr. The activity is similar to that partially purified from human cells [Hsieh, P., Meyn, S.M. & Camerini-Otero, R.D. (1986) Cell 44, 885-894]. It is homology-dependent, requires Mg2+, appears to be directional in that it prefers to displace the 3' end of the noncomplementary strand, and does not require exogenous ATP. Forty nanograms of protein in the partially purified DNA strand-exchange fraction from D. melanogaster embryos can completely convert 50 ng of substrate single-strand DNA into joint molecules in 10 min. In the electron microscope, joint molecules are seen to consist of a circular single-strand DNA molecule attached to only one end of a linear duplex DNA molecule; a displaced strand is also seen. The region of heteroduplex formation can be as long as 600 base pairs. The demonstration of a strand-exchange activity from wild-type D. melanogaster embryos invites analysis of recombination-defective mutants to explore the role of DNA strand exchange in homologous recombination.

Sensitive homologous recombination strand-transfer assay: partial purification of a Drosophila melanogaster enzyme and detection of sequence effects on the strand-transfer activity of RecA protein

A sensitive homologous recombination strand-transfer assay is described that employs short radiolabeled double-stranded DNA fragments from the lac/polylinker region of plasmid pUC18 and (+)viral M13mp18 single-stranded DNA as substrates. Substitution of a short radiolabeled double-stranded fragment for full-length linear M13 double-stranded DNA results in an assay whose sensitivity is improved greater than 8-fold. In addition, it is less sensitive to interference from nucleases or ligases than previous assays. The assay was used to partially purify an ATP-independent strand-transfer activity from a crude nuclear extract of Drosophila melanogaster embryos. We have also tested the efficiency with which various short double-stranded DNA segments are assembled into plectonemic joints by RecA protein with this assay and found 5- to 10-fold differences. These results are interpreted as evidence for DNA sequence-specific effects in RecA-mediated homologous pairing in vitro.

Expression of a DNA-ligase-stimulatory factor in Bloom's syndrome cell line GM1492

An increased DNA ligase activity is observed in extracts of Bloom's syndrome (BS) fibroblast cell line GM1492. The activity is 2-3-fold higher in this cell line compared to normal human fibroblasts, and 5-20-fold higher than in three other BS cell lines investigated. The DNA ligase activity in GM1492 cells is promoted by a heat-resistant, protease-sensitive factor comigrating with DNA ligases on single-stranded-DNA--cellulose. The factor stimulates DNA ligase I as well as DNA ligase II, and is not identical to the activity-promoting homologous DNA pairing, which is also enhanced in GM1492 cell extracts.

Identification of homologous pairing and strand-exchange activity from a human tumor cell line based on Z-DNA affinity chromatography

An enzymatic activity that catalyzes ATP-dependent homologous pairing and strand exchange of duplex linear DNA and single-stranded circular DNA has been purified several thousand-fold from a human leukemic T-lymphoblast cell line. The activity was identified after chromatography of nuclear proteins on a Z-DNA column matrix. The reaction was shown to transfer the complementary single strand from a donor duplex linear substrate to a viral circular single-stranded acceptor beginning at the 5' end and proceeding in the 3' direction (5'----3'). Products of the strand-transfer reaction were characterized by electron microscopy. A 74-kDa protein was identified as the major ATP-binding peptide in active strand transferase fractions. The protein preparation described in this report binds more strongly to Z-DNA than to B-DNA.

Characterization of an ATP-dependent DNA strand transferase from human cells

We have characterized an enzymatic activity from human cell nuclei which is capable of catalyzing strand exchange between homologous DNA sequences. The strand exchange activity was Mg2+ dependent and required ATP hydrolysis. In addition, it was capable of promoting reannealing of homologous DNA sequences and could form nucleoprotein networks in a fashion reminiscent of purified bacterial RecA protein. Using an in vitro recombination assay, we also showed that the strand exchange activity was biologically important. The factor(s) responsible for the activity has been partially purified.

RecA-like activity in mammalian cell extracts of different origin

The occurrence of a RecA-like activity similar to the one detected in the fibroblast cell line GM1492 derived from a patient suffering from the autosomal recessive disease Bloom's syndrome has been investigated in cell extracts of different origin. The formation of D-loop containing joint molecules from phi X174 RFI DNA and fragments of phi X174 single-stranded DNA by partially purified extracts was measured by a filter binding assay. The RecA-like activity, dependent on ATP and Mg2+, was detected at an elevated level only in the human and rodent cell lines, GM1492 and CHO respectively. The level of activity in DNA-cellulose-purified cell extracts from these cell lines was 4-7-fold higher compared to normal human fibroblasts. Low levels of activity were also detected in extracts from two additional Bloom's syndrome fibroblast cell lines, Fanconi's anemia fibroblasts, virus- (Epstein-Barr virus, Simian virus 40) transformed human cells and human placenta. Cell extracts from rat testis, spleen and calf thymus were also of low activity.

Promotion of double-strand break repair by human nuclear extracts preferentially involves recombination with intact homologous DNA

Parameters of DNA double strand break (dsb) repair catalysed by human nuclear extract were analysed using, as substrate, the replicative form (RF) of M13 mp8 in which a single double strand break (dsb) was introduced by restriction. After incubation with the extract, the dsb repair was estimated by the ability of the incubated RF to produce plaques following transfection into JM 109 (Rec A-) bacteria. The possibility of recombination with a purified fragment from M13 mp8 RF enhances up to 20 times the plaquing ability of the RF. The repair by recombination occurs under several conditions: i) the break in the RF must be located in the region of homology with the fragment. ii) the fragment has to be intact in the region corresponding to the break in the RF. iii) a minimal length of homology between the region surrounding the dsb in the RF, and the fragment is required. The in vitro reaction is ATP dependent and dNTP's partially dependent. Dephosphorylation of the free ends in the RF decreases the repair by ligation but is without effect on the recombination.

Characterization of an ATP-dependent DNA strand transferase from human cells

We have characterized an enzymatic activity from human cell nuclei which is capable of catalyzing strand exchange between homologous DNA sequences. The strand exchange activity was Mg2+ dependent and required ATP hydrolysis. In addition, it was capable of promoting reannealing of homologous DNA sequences and could form nucleoprotein networks in a fashion reminiscent of purified bacterial RecA protein. Using an in vitro recombination assay, we also showed that the strand exchange activity was biologically important. The factor(s) responsible for the activity has been partially purified.

Homologous recombination intermediates between two duplex DNA catalysed by human cell extracts

Using as substrates, 1: the replicative form (RF) of phage M13 mp8 in which the reading frame of the lac Z' gene was disrupted by insertion of an octonucleotide, and 2: a restriction fragment one kb long, containing the functional lac Z' gene (isolated from wild type M13 mp8), we show that nuclear extracts from human cells (3 lines tested) promote the targeted replacement of the altered sequence by the functional one. Following incubation with the extracts, the DNA's were introduced in JM 109 bacteria (rec A- and lac Z'-) which were grown in presence of a colorimetric indicator of beta-galactosidase activity. Homologous recombination gives rise to the genotypical modification: lac Z'+ instead of lac Z'- in the bacteriophage DNA. This is revealed by phenotypical expression of the lac Z' gene product in replicating bacteriophage, i.e. the formation of blue instead of white plaques. The frequency of recombination (blue/total plaques) is increased by a factor of 50-80 as a function of protein concentration and of incubation time. The maximal frequency observed is 5 X 10(-5). There is no increase over the background when extracts are boiled. Electrophoresis and electron microscopy of DNA's incubated with the extracts show the formation of recombination intermediates with single strand exchange. Restriction analysis of recombined DNA confirms that the process corresponds to targeted sequence exchange. These data allow to propose three steps for homologous recombination between two duplex DNA's: i) unpairing of the two duplexes; ii) single-strand exchange and synaptic pairing; iii) resolution of the cross-junctions. The three steps correspond to those predicted by the gene conversion model of Holliday.

Partial purification of an activity from human cells that promotes homologous pairing and the formation of heteroduplex DNA in the presence of ATP

An activity that can promote homologous pairing and strand transfer between suitable DNA substrates has been partially purified from human skin fibroblasts and from HeLa cells. The strand transfer reaction was investigated with DNA substrates consisting of single-stranded circular and duplex linear phage DNA. It requires ATP, and under optimal conditions yields heteroduplex molecules containing one strand from each parental DNA substrate. The reactions appears to be of the same general nature as those mediated by RecA proteins of Escherichia coli and the Rec1 protein of Ustilago maydis.

Extrachromosomal recombination in mammalian cells as studied with single- and double-stranded DNA substrates

We have previously proposed a model to account for the high levels of homologous recombination that can occur during the introduction of DNA into mammalian cells (F.-L. Lin, K. Sperle, and N. Sternberg, Mol. Cell. Biol. 4:1020-1034, 1984). An essential feature of that model is that linear molecules with ends appropriately located between homologous DNA segments are efficient substrates for an exonuclease that acts in a 5'----3' direction. That process generates complementary single strands that pair in homologous regions to produce an intermediate that is processed efficiently to a recombinant molecule. An alternative model, in which strand degradation occurs in the 3'----5' direction, is also possible. In this report, we describe experiments that tested several of the essential features of the model. We first confirmed and extended our previous results with double-stranded DNA substrates containing truncated herpesvirus thymidine kinase (tk) genes (tk delta 5' and tk delta 3'). The results illustrate the importance of the location of double-strand breaks in the successful reconstruction of the tk gene by recombination. We next transformed cells with pairs of single-stranded DNAs containing truncated tk genes which should anneal in cells to generate the recombination intermediates predicted by the two alternative models. One of the intermediates would be the favored substrate in our original 5'----3' degradative model and the other would be the favored substrate in the alternative 3'----5' degradative model. Our results indicate that the intermediate favored by the 3'----5' model is 10 to 20 times more efficient in generating recombinant tk genes than is the other intermediate.

Effects of Bloom's syndrome fibroblasts on genetic recombination and mutagenesis of herpes simplex virus type 1

The effects of Bloom's syndrome (BS) fibroblasts on genetic recombination and the mutation frequency of herpes simplex virus type 1 (HSV-1) was determined by employing two factor crosses of selected temperature-sensitive (ts) mutants. A significant increase in the recombination frequency (RF) was observed in seven of nine crosses when multiple BS fibroblast lines were compared to normal human fibroblasts. The RF of HSV-1 ts mutants increased following 12-O-tetradecanoylphorbol-13-acetate (TPA) treatment of normal, but not BS fibroblasts, suggesting that BS fibroblasts express higher constitutive levels of genetic recombination activity. HSV-1 ts mutants demonstrated significantly higher reversion frequencies to the nontemperature sensitive (ts+) phenotype following growth in BS rather than normal fibroblasts, indicating that exogenous viral DNA encoding many of the enzymes necessary for its own replication is affected by the mutator phenotype of BS.

DNA ligase I deficiency in Bloom's syndrome

Certain rare human diseases with autosomal recessive mode of inheritance are associated with a greatly increased cancer frequency which may reflect specific defects in DNA repair or replication. These disorders include xeroderma pigmentosum, ataxia-telangiectasia, Fanconi's anaemia and Bloom's syndrome. Cells from individuals with Bloom's syndrome usually grow slowly in culture and exhibit increased chromosomal breakage and rearrangement, an elevated frequency of sister chromatid exchanges, retarded rates of progression of DNA replication forks, delayed conversion of replication intermediates to high-molecular-weight DNA, and slightly increased sensitivity to DNA-damaging agents. Several of these features are also characteristic of Escherichia coli and yeast mutants with a defective DNA ligase. In this investigation we show that one of the two DNA ligases of human cells, ligase I, is defective in a representative lymphoid cell line of Bloom's syndrome origin.

Extrachromosomal recombination in mammalian cells as studied with single- and double-stranded DNA substrates

We have previously proposed a model to account for the high levels of homologous recombination that can occur during the introduction of DNA into mammalian cells (F.-L. Lin, K. Sperle, and N. Sternberg, Mol. Cell. Biol. 4:1020-1034, 1984). An essential feature of that model is that linear molecules with ends appropriately located between homologous DNA segments are efficient substrates for an exonuclease that acts in a 5'----3' direction. That process generates complementary single strands that pair in homologous regions to produce an intermediate that is processed efficiently to a recombinant molecule. An alternative model, in which strand degradation occurs in the 3'----5' direction, is also possible. In this report, we describe experiments that tested several of the essential features of the model. We first confirmed and extended our previous results with double-stranded DNA substrates containing truncated herpesvirus thymidine kinase (tk) genes (tk delta 5' and tk delta 3'). The results illustrate the importance of the location of double-strand breaks in the successful reconstruction of the tk gene by recombination. We next transformed cells with pairs of single-stranded DNAs containing truncated tk genes which should anneal in cells to generate the recombination intermediates predicted by the two alternative models. One of the intermediates would be the favored substrate in our original 5'----3' degradative model and the other would be the favored substrate in the alternative 3'----5' degradative model. Our results indicate that the intermediate favored by the 3'----5' model is 10 to 20 times more efficient in generating recombinant tk genes than is the other intermediate.

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.

General recombination mechanisms in extracts of meiotic cells

RecA-like proteins have been purified from somatic and meiotic cells of mouse and lily. The rec proteins have been designated "s-rec" and "m-rec" to indicate their respective tissues of origin. The two proteins differ in molecular weight and in their response to temperature, the latter being consistent with the optimal temperature for physiological function of their tissues of origin. There is a major increase in m-rec protein with the entry of cells into meiosis, the peak of activity being early pachytene. Extracts of the cells and also those of yeast (Saccharomyces cerevisiae) have been prepared that have the capacity to catalyze homologous recombination. These extracts behave similarly to the m-rec proteins upon entry of cells into meiosis. Yeast transferred to sporulation medium displays a 100-fold increase in the recombination activity of the extract at about the time of entry into meiosis. The occurrence of peak levels of m-rec and recombination activity in extracts from cells in early pachytene points strongly to that stage as the time at which the enzymatic phase of recombination occurs.

Homologous recombination catalyzed by human cell extracts

Two plasmids containing noncomplementing and nonreverting deletions in a bacterial phosphotransferase gene conferring resistance to neomycin (Neor) were incubated with human cell extracts, and the mixtures were used to transform recombination-deficient (recA-) Escherichia coli cells. We were able to obtain Neor colonies at a frequency of 2 X 10(-3). This frequency was 100 to 1,000 times higher than that obtained with no extracts. The removal of riboadenosine 5'-triphosphate, Mg2+, or deoxynucleoside triphosphates from the reaction mixture severely reduced the yield of Neor colonies. Examination of plasmid DNA from the Neor colonies revealed that they resulted from gene conversion and reciprocal recombination. On the basis of these results, we conclude that mammalian somatic cells in culture have the enzymatic machinery to catalyze homologous recombination in vitro.

Homologous recombination catalyzed by human cell extracts

Two plasmids containing noncomplementing and nonreverting deletions in a bacterial phosphotransferase gene conferring resistance to neomycin (Neor) were incubated with human cell extracts, and the mixtures were used to transform recombination-deficient (recA-) Escherichia coli cells. We were able to obtain Neor colonies at a frequency of 2 X 10(-3). This frequency was 100 to 1,000 times higher than that obtained with no extracts. The removal of riboadenosine 5'-triphosphate, Mg2+, or deoxynucleoside triphosphates from the reaction mixture severely reduced the yield of Neor colonies. Examination of plasmid DNA from the Neor colonies revealed that they resulted from gene conversion and reciprocal recombination. On the basis of these results, we conclude that mammalian somatic cells in culture have the enzymatic machinery to catalyze homologous recombination in vitro.