Ku binds telomeric DNA in vitro.

Ku is a heterodimeric protein with high binding affinity for ends, nicks, and gaps in double-stranded DNA. Both in mammalian cells and in budding yeast, Ku plays a role in nonhomologous end joining in the double strand break repair pathway. However, Ku has a more significant role in DNA repair in mammalian cells compared with yeast, in which a homology-dependent pathway is the predominant one. Recently Ku has been shown to be a likely component of the telomeric complex in yeast, suggesting the possibility of a similar role for Ku at mammalian telomeres. However, long single-stranded G-rich overhangs are continuously present at mammalian but not at yeast telomeres. These overhangs have the potential to fold in vitro into G-G base-paired conformations, such as G-quartets, that might prevent Ku from recognizing telomeric ends and thus offer a mechanism to sequester the telomere from the prevalent double strand break repair pathway in mammals. We show here that Ku binds to mammalian telomeric DNA ends in vitro and that G-quartet conformations are unable to prevent Ku from binding with high affinity to the DNA. Our results indicate that the DNA binding characteristics of Ku are consistent with its direct interaction with telomeric DNA in mammalian cells and its proposed role as a telomere end factor.     

Chemical nature of in vivo DNA base damage in hydrogen peroxide-treated mammalian cells.

Hydrogen peroxide is generated in mammalian cells by normal metabolism or by treatment with external agents. Treatment of mammalian cells with this oxidizing agent results in DNA damage. Little is known about the chemical nature of hydrogen peroxide-mediated DNA damage in mammalian cells. Here we report on the chemical characterization of in vivo base damage to nuclear DNA in mammalian cells caused by exposure to H2O2. Chromatin was isolated from cells and analyzed by gas chromatography/mass spectrometry with selected-ion monitoring. Ten DNA base products were identified and quantitated. Modified bases identified were typical hydroxyl radical-induced products of DNA bases. Results indicate involvement of hydroxyl radicals in the mechanism of nuclear DNA damage in mammalian cells caused by H2O2.     

A mathematical model of the course of the DNA synthesis in mammalian cells after ultraviolet irradiation and its use in the determination of the length of the replicon

The chromosome of mammalian cells is divided into several shorter segments — replicons which replicate separately. When the cells are irradiated with ultraviolet radiation the pyrimidine flimers preventing the DNA-polymerase in its normal function and creating obstacles for a timely completing of the implication are formed. Using these facts as a basis we have derived a mathematical model of the course of the DNA synthesis in mammalian cells after ultraviolet irradiation, it has been proved that for the determination of the average length of units of replication in chromosomes of these cells the measurement of the intensity of post-radiation DNA synthesis in an asynchronous culture of mammalian cells can be used. Directions for the determination of this length using results of the measurement of the post-radiation synthesis are given, too. The whole method has already beer, tested on mammalian L-cells.     

Gene transfer and gene mapping in mammalian cells in culture

The ability to transfer mammalian genes parasexually has opened new possibilities for gene mapping and fine structure mapping and offers great potential for contributing to several aspects of mammalian biology, including gene expression and genetic engineering. The DNA transferred has ranged from whole genomes to single genes and smaller segments of DNA. The transfer of whole genomes by cell fusion forms cell hybrids, which has promoted the extensive mapping of human and mouse genes. Transfer, by cell fusion, of rearranged chromosomes has contributed significantly to determining close linkage and the assignment of genes to specific chromosomal regions. Transfer of single chromosomes has been achieved utilizing microcells fused to recipient cells. Metaphase chromosomes have been isolated and used to transfer single-to-multigenic DNA segments. DNA-mediated gene transfer, simulating bacterial transformation, has achieved transfer of single-copy genes. By utilizing DNA cleaved with restriction endonucleases, gene transfer is being empolyed as a bioassay for the purification of genes. Gene mapping and the fate of transferred genes can be examined now at the molecular level using sequence-specific probles. Recently, single genes have been cloned into eucaryotic and procaryotic vectors for transfer into mammalian cells. Moreover, recombinant libraries in which entire mammalian genomes are represented collectively are a rich new source of transferable genes. Methodology for transferring mammalian genetic information and applications for mapping mammalian genes is presented and prospects for the future discussed.     

Molecular complementation of a collagen mutation in mammalian cells using yeast artificial chromosomes.

The cloning of large contiguous segments of mammalian DNA in Saccharomyces cerevisiae has become possible with the advent of Yeast Artificial Chromosomes (YACs). We are interested in extending the technique of genetic complementation analysis to the molecular level through the introduction of YACs into mammalian cells and the mammalian germline. We report the successful introduction of homogeneous DNA derived from a 150 kbp YAC spanning the murine Col1a1 locus into murine fibroblasts carrying a mutation at this locus. The YAC DNA was fractionated by pulse field electrophoresis, condensed with polyamines, and introduced into mutant fibroblasts via DNA-lipid micelles. The DNA was integrated as a stable intact unit in 10% of the transfected clones conferring collagen RNA expression to the mutant cells.     

Damage and repair in mammalian cells after exposure to non-ionizing radiations III. Ultraviolet and visible light irradiation of cells of placental mammals,including humans,and determinations of photorepairable damage in vitro

Cultured cells of placental mammals (including human skin fibroblasts) as well as fresh cornea tissue from oxen have been UV (254 nm)-irradiated and either kept dark or exposed to photoreactivating light (wavelengths >375 nm) only prior to extraction of their DNA. The latter was added to an in vitro photorepair system consisting of UV-irradiated DNA from Haemophilus influenzae and yeast-photoreactivating enzyme, illuminated with broad-spectrum white fluorescent light. The extent of competitive inhibition of the in vitro photorepair of Haemophilus-DNA, resulting from the addition of mammalian DNA, has been taken as a measure of mammalian DNA lesions capable of reacting with photoreactivating enzyme. In most cases the amount of these DNA lesions was reduced if the UV-irradiated mammalian cells had been light-exposed prior to DNA extraction, indicating photoenzymatic repair of up to 90% of the lesions. DNA damage by the photoreactivating light itself was observed at varying degrees in human cells, where this effect presumably masks some of the photorepair.     

An episomal mammalian replicon: sequence-independent binding of the origin recognition complex

An extrachromosomally replicating plasmid was used to investigate the specificity by which the origin recognition complex (ORC) interacts with DNA sequences in mammalian cells in vivo. We first showed that the plasmid pEPI-1 replicates semiconservatively in a once-per-cell-cycle manner and is stably transmitted over many cell generations in culture without selection. Chromatin immunoprecipitations and quantitative polymerase chain reaction analysis revealed that, in G1-phase cells, Orc1 and Orc2, as well as Mcm3, another component of the prereplication complex, are bound to multiple sites on the plasmid. These binding sites are functional because they show the S-phase-dependent dissociation of Orc1 and Mcm3 known to be characteristic for prereplication complexes in mammalian cells. In addition, we identified replicative nascent strands and showed that they correspond to many plasmid DNA regions. This work has implications for current models of replication origins in mammalian systems. It indicates that specific DNA sequences are not required for the chromatin binding of ORC in vivo. The conclusion is that epigenetic mechanisms determine the sites where mammalian DNA replication is initiated.     

Repair of single nucleotide DNA mismatches transfected into mammalian cells can occur by short-patch excision

Synthetic DNA linkers containing a single mismatched nucleotide (C:A) are repaired without bias at high efficiency when introduced into mammalian cells on a SV40 shuttle vector. From the pattern of repair in vectors containing multiple linkers, it appears that DNA synthesis following mismatch excision can replace a length of DNA as short as 40 nucleotides. Furthermore, results from the introduction of linker molecules containing combinations of single-strand nicks suggest that transient unsealed nicks do not drive the direction of mismatch repair in mammalian cells, as has previously been proposed.     

Mutagenicity of a unique apurinic/apyrimidinic site in mammalian cells.

Abasic sites are common DNA lesions produced either spontaneously or as a consequence of the action of some genotoxic agent. The mutagenic properties of a unique abasic site replicated in mammalian cells have been studied using a shuttle vector. A plasmid, able to replicate both in mammalian cells and in bacteria, carrying a unique abasic site chemically synthesized has been constructed. After replication in mammalian cells, plasmid DNA was recovered and used to transform bacteria. Mutants were screened without selection pressure by differential hybridization with a labelled oligonucleotide and their DNA was sequenced. A mutation frequency ranging from 1% to 3% was found, depending on the base originally inserted during the vector construction, opposite the abasic site. All the sequenced mutants correspond to single base-pair substitutions targeted at the abasic site. We observed a deficit in guanine incorporation opposite the abasic site, while the three other bases were incorporated with a similar efficiency. The mutational potency of abasic sites was observed without any voluntary preconditioning treatment of mammalian cells in order to induce "SOS" like conditions.     

The herpes simplex virus 1 origin binding protein: a DNA helicase.

A recombinant herpes simplex 1 origin binding protein, the product of the herpes UL9 gene, has been overexpressed in mammalian cells and purified to near homogeneity. The origin binding protein shows DNA-dependent nucleoside 5'-triphosphatase and DNA helicase activities in addition to its origin binding activity. The ability to hydrolyze nucleoside 5'-triphosphates is influenced strongly by the structure and sequence of the DNA cofactor. The properties of the recombinant origin binding protein are identical to those of the protein synthesized in herpes simplex 1-infected mammalian cells.     

Characteristics of enzymatic DNA methylation in cultured cells of human and hamster origin,and the effect of DNA replication inhibition

In mammalian cells, inhibitors of DNA replication have been shown to induce chromosomal aberrations, cell death and changes in gene control. Inhibition of DNA synthesis has been reported to induce hypermethylation of mammalian DNA (enzymatic postsynthetic formation of 5-methylcytosine). These 5-methylcytosines in mammalian DNA have variously been suggested to be important in gene control, DNA repair, and control of DNA replication. In establishing the normal characteristics of enzymatic DNA methylation, we have demonstrated that, in asynchronously growing cells of both human and hamster origin, some cytosine methylation is delayed for several hours after strand synthesis and that this delayed methylation is completed before the DNA strand acts as a template for DNA replication in the next S-phase. Further, in testing whether the deleterious effects on mammalian cells of DNA synthesis inhibitors might be mediated via changes in enzymatic DNA methylation, we have found, contrary to some previous findings, no evidence for any change in the level of DNA methylation in DNA strands synthesized during 6 h of treatment of cells of human origin with high concentrations of four different inhibitors of DNA replication or during the 4 h following the 6 h treatment. Almost totally blocking DNA replication had no effect on the small amount of delayed methylation of DNA strands not involved in semi-conservative replication during the time of the experiment. This lack of effect on DNA methylation was obtained when the labelling medium contained normal, undialysed serum. In contrast, if dialysed serum was used in the labelling medium in order to maximize l-[Me-³H]methionine utilization, highly variable, totally irreproducible patterns of apparent DNA hypermethylation were obtained.     

Structural organizations of replicon domains during DNA synthetic phase in the mammalian nucleus

In mammalian cells, it has been shown that adjacent multiple DNA replicons, termed a replicon cluster or a replicon domain, are replicated coordinately in a defined temporal order during the DNA synthetic (S) phase. However, no intranuclear structure of this replicon domain has been revealed in the nucleus labelled with [3H]thymidine at the limited resolution level of autoradiography. By immunofluorescent staining with antibody against 5-bromodeoxyuridine (BrdU), we succeeded in detecting novel, intranuclear ring-like structures of replicating replicon domains that were organized temporarily during the S phase of mammalian cells with incorporated BrdU.     

Induction of beta-polymerase mRNA by DNA-damaging agents in Chinese hamster ovary cells.

Only a few of the genes involved in DNA repair in mammalian cells have been isolated, and induction of a DNA repair gene in response to DNA damage has not yet been established. DNA polymerase beta (beta-polymerase) appears to have a synthetic role in DNA repair after certain types of DNA damage. Here we show that the level of beta-polymerase mRNA is increased in CHO cells after treatment with several DNA-damaging agents.     

Delayed DNA methylation is an integral feature of DNA replication in mammalian cells

In the majority of sites of methylation in the DNA of mammalian cells, the symmetry of methylation is restored within a few minutes of the passage of a replication fork. However, it has been shown that daughter strand methylation in immortalised cell lines is delayed in a substantial minority of sites for up to several hours after replication. We report here the results of two new approaches to the determination of the functional significance of delayed DNA methylation in mammalian cells. Firstly, we demonstrate that normal, nontransformed cells (human peripheral lymphocytes in short-term primary culture) have comparable proportions of delayed DNA methylation to many immortalised cell lines, showing that delayed DNA methylation is not just a secondary consequence of abnormally high methionine requirements commonly observed in transformed cells and that delayed DNA methylation would be unlikely not to occur in vivo. Secondly, we have used 5-aza-2'-deoxycytidine (5azadCyd) to derive subclones of cells from the Chinese hamster ovary cell line which have stably hypomethylated DNA. In three of these subclones which had lost on average one fourth of the methylation sites from their genomes, the proportion of daughter strand methylation which was delayed after replication was reduced by less than 10%. If delayed DNA methylation were site-specific, this implies that of the order of twice the number of "immediate" methylation sites than delayed methylation sites had been lost from the genomes of these hypomethylated subclones. Thus, delayed DNA methylation is an integral part of the process whereby replicating mammalian cells maintain the pattern of methylation in their genomes. These observations are discussed in relation to the significance of delayed DNA methylation for the accurate maintenance of methylation patterns in the genome and the consequent implications for the possible role of methylated deoxycytidines in mammalian gene control.     

Baculoviruses as Vectors in Mammalian Cells

The Baculoviridae are a large family of enveloped DNA viruses exclusively pathogenic to arthropods. Baculoviruses have been extensively used in insect cell-based recombinant protein expression system and as biological pesticides. They have been deomostrated to be safe to mammals, birds and fish. Recently, baculoviruses has been shown to transduce different mammalian cells in spite of the fact that they cannot replicate in mammalian cells (11, 73, 76). This has resulted in the development of baculoviruses as mammalian expression systems and even as vestors for gene therapy.     

Mechanisms of activation of the RAW264.7 macrophage cell line by transfected mammalian DNA

Bacterial DNA can stimulate the production of cytokines and nitric oxide (NO), while mammalian DNA can block these responses. If mammalian DNA is transfected into macrophages, however, it can stimulate NO production, without inducing IL-12. To define further this activity, signaling pathways induced by transfected calf thymus (CT) DNA were studied. Using RAW264.7 cells as a model, CT DNA in the transfection agent FuGENE 6 activated cells through the NF-kappaB and MAPKs pathways, similar to bacterial DNA and LPS. The role of these pathways was further investigated using specific inhibitors, with studies indicating that NO production is blocked by inhibitors of NF-kappaB and p38 but not other MAPKs. These data indicate that the immune activity of DNA is influenced by context or intracellular location and that, when transfected into cells, mammalian DNA can activate cells through signaling pathways similar to those of bacterial DNA.     

Lack of effect of hydroxyurea on base excision repair in mammalian cells

The effect of hydroxyurea on the initial steps of base excision repair has been examined in mammalian cells in 3 different proliferative states: i.e., quiescent cells, asynchronously growing cells undergoing multiple divisions prior to confluence; and synchronous cell populations undergoing the first cell cycle(s) after release from quiescence. Two parameters of the base excision repair pathway were examined: (1) The direct excision of 7-methylguanine from cellular DNA in the presence of increasing hydroxyurea concentrations was quantitated by high performance liquid chromatography; (2) the effects of hydroxyurea on the uracil DNA glycosylase were examined by quantitating the levels of this base excision repair enzyme in quiescent and proliferating cells. In quiescent cells, hydroxyurea at concentrations routinely used to quantitate DNA repair had no effect on the excision rates of 7-methylguanine examined over a span of 3 days; nor was there any effect on the specific activity of uracil DNA glycosylase in confluent cells. In asynchronously proliferating mammalian cells, identical hydroxyurea concentrations had no effect on the induction of the glycosylase. In synchronous growing cells HU had no effect on the temporal sequence of induction of uracil DNA glycosylase prior to DNA replication, nor on the extent of this induction. These results suggest that hydroxyurea at concentrations generally used to measure DNA repair has no effect on base excision repair.     

Comparison of piggyBac transposition efficiency between linear and circular donor vectors in mammalian cells

The piggyBac transposon has recently attracted attention as a tool for transgene integration in mammalian cells. However, previous studies involving piggyBac investigated only transposition from circular DNA, although some linear DNA vectors are used to transfect mammalian cells. In this study, we compared the transposition efficiency of piggyBac between linear and circular DNA. Colony counting assay, luciferase assay, and plasmid rescue assay showed that piggyBac transposon can transpose from linear DNA, but its efficiency is lower than the transposition efficiency from circular DNA. These results suggest that circular DNA is more suitable as donor vectors of piggyBac than linear DNA.