Transfection of mouse fibroblast cells with a promoterless herpes simplex virus thymidine kinase gene: number of integrated gene copies and structure of single and amplified gene sequences.

Plasmids carrying the herpes simplex virus thymidine kinase (tk) gene were used to transfect thymidine kinase-deficient cells of the mouse fibroblast cell line LM(tk-). Individual cell clones were cultivated in selective hypoxanthine-aminopterin-thymidine medium to determine the number of integrated plasmid copies which was almost always in the range of one to three copies per genome. In contrast, cells transfected with plasmids carrying a promoterless "truncated" tk gene typically contained between 10 and 25 copies per genome. Surprisingly, when the truncated tk gene was transfected together with a simian virus 40 DNA segment, including its transcriptional enhancer, the number of integrated tk gene copies was always low, between one and three copies per genome. We have analyzed the genomic organization of integrated truncated tk genes by blot hybridization of restricted cellular DNA and concluded that integrated units of plasmid DNA molecules are arranged in tandem arrays which remain stable in most cases for many cell generations. In only 1 of ca. 20 cell clones did we observe a retraction and expansion of the number of integrated promoterless tk genes as a response to the removal or readdition of selective pressure. Surprisingly, the thymidine kinase activity determined in extracts from cells growing in selective hypoxanthine-aminopterin-thymidine medium (high numbers of integrated tk gene copies) was nearly the same as the enzymatic activity in cells growing in nonselective medium (low copy numbers). Moreover, Northern blots of polyadenylated RNA, extracted from cells growing under selective and nonselective conditions, showed that, in both cases, the major species of tk-specific transcripts was ca. 1.5 kilobases in size, as expected for a tk-specific mRNA containing the entire coding region of the gene. Thus, disproportionate DNA replication appeared not to be essential for an active tk gene expression in these cells. We discuss possible pathways leading to the formation of tandem arrays of integrated truncated tk genes and the conditions required for disproportionate DNA replication in the unique case in which we found a retraction and expansion of tk gene copy numbers as a response to selective growth conditions.

Transfer of nucleosomes from parental to replicated chromatin.

Simian virus 40 (SV40) minichromosomes were used as the substrate for in vitro replication. Protein-free SV40 DNA or plasmids, carrying the SV40 origin of replication, served as controls. Replicated minichromosomal DNA possessed constrained negative superhelicity indicative of the presence of nucleosomes. The topological state of replicated minichromosomal DNA was precisely determined by two-dimensional gel electrophoresis. We show that most or all nucleosomes, present on the replicated minichromosomal DNA, were derived from the parental minichromosome substrate. The mode and the rate of nucleosome transfer from parental to minichromosomal daughter DNA were not influenced by high concentrations of competing replicating and nonreplicating protein-free DNA, indicating that nucleosomes remain associated with DNA during the replication process. The data also show that parental nucleosomes were segregated to the replicated daughter DNA strands in a dispersive manner.

The human topoisomerase I gene promoter is regulated by NF-IL6.

We investigated the expression of the human DNA topoisomerase I (hTOP1) gene in HeLa cells and in adenovirus-transformed 293 cells. A highly conserved proximal promoter element is essential for hTOP1 promoter activity in HeLa cells but not in 293 cells. This correlates with the presence of specific promoter-binding proteins in HeLa cells and their absence in 293 cells. We identified the HeLa binding protein by screening a cDNA expression library with the specific promoter site as a probe and demonstrate now that the activating protein is identical to the nuclear factor for interleukin-6 expression (NF-IL6), a member of the C/EBP family of transcription factors. Overexpression of NF-IL6 strongly stimulates hTOP1 promoter activity in HeLa cells, suggesting that NF-IL6 is a major hTOP1-regulating protein. Because of the presence of adenovirus protein E1A, 293 cells express the hTOP1 gene more efficiently than HeLa cells but do not contain NF-IL6 activity. E1A activation of the hTOP1 promoter is suppressed by NF-IL6 overexpression. This result supports previous observations concerning a functional interaction between viral protein E1A and NF-IL6. Finally, we show that hTOP1 gene expression in differentiating macrophages is correlated with the synthesis of NF-IL6-specific mRNA.

A nucleosome assembly factor is a constituent of simian virus 40 minichromosomes.

Using in vitro replication assays, we compared native with salt-treated simian virus 40 minichromosomes isolated from infected cell nuclei. Minichromosomes from both preparations contain the full complement of nucleosomes, but salt treatment removes histone H1 and a fraction of nonhistone chromatin proteins. Both types of minichromosomes served well as templates for in vitro replication, but the structures of the replication products were strikingly different. Replicated salt-treated minichromosomes contained, on average, about half the normal number of nucleosomes as previously shown (T. Krude and R. Knippers, Mol. Cell. Biol. 11:6257-6267, 1991). In contrast, the replicated untreated minichromosomes were found to be densely packed with nucleosomes, indicating that an assembly of new nucleosomes occurred during in vitro replication. Biochemical and immunological data showed that the fraction of nonhistone chromatin proteins associated with native minichromosomes includes a nucleosome assembly activity that appears to be closely related to chromatin assembly factor I (S. Smith and B. W. Stillman, Cell 58:15-25, 1989). Furthermore, this minichromosome-bound nucleosome assembly factor is able to exert its activity in trans to replicating protein-free competitor DNA. Thus, native chromatin itself contains the activities required for an ordered assembly of nucleosomes during the replication process.

Camptothecin, a specific inhibitor of type I DNA topoisomerase, induces DNA breakage at replication forks.

The structure of replicating simian virus 40 minichromosomes, extracted from camptothecin-treated infected cells, was investigated by biochemical and electron microscopic methods. We found that camptothecin frequently induced breaks at replication forks close to the replicative growth points. Replication branches were disrupted at about equal frequencies at the leading and the lagging strand sides of the fork. Since camptothecin is known to be a specific inhibitor of type I DNA topoisomerase, we suggest that this enzyme is acting very near the replication forks. This conclusion was supported by experiments with aphidicolin, a drug that blocks replicative fork movement, but did not prevent the camptothecin-induced breakage of replication forks. The drug teniposide, an inhibitor of type II DNA topoisomerase, had only minor effects on the structure of these replicative intermediates.

Insertional activation of a promoterless thymidine kinase gene.

A plasmid carrying a promoterless herpes simplex virus thymidine kinase gene was transfected via calcium phosphate precipitation into LM (tk-) mouse fibroblast cells. The transfected gene was efficiently expressed, as the transfected cells grew perfectly well in selective hypoxanthine-aminopterin-thymidine medium, suggesting that the thymidine kinase-coding region became linked to a promoterlike element on integration into the recipient genome. To investigate the structure of the surrogate promoter, we first isolated the integrated gene from a genomic library. The nucleotide sequence of the DNA adjacent to the thymidine kinase-coding sequence was then determined. We found, first, that the integration of the transfected DNA apparently occurred by a blunt end ligation mechanism involving no obvious sequence similarities between integrated and recipient DNA and, second, that the 5'-flanking region included a TATA box, two CCAAT boxes, and a GC box element. However, the TATA box motif and the most proximal CCAAT box appeared to be sufficient for full promoter activity, as determined by the transfection efficiencies of appropriate plasmid constructs. Except for these canonical promoter elements, the surrogate promoter had no obvious similarities to known thymidine kinase gene promoters.

Role of amino-terminal histone domains in chromatin replication.

Simian virus 40 minichromosomes were treated with trypsin to specifically remove the amino-terminal histone domains (tails). Trypsin treatment does not affect the spacing and the number of nucleosomes on minichromosomes but indices a more extended conformation, as shown by the reduced sedimentation coefficient of trypsinized minichromosomes compared with the untreated controls. Trypsinized minichromosomes replicate more efficiently than control minichromosomes in in vitro replication assays. The increased template efficiency appears to be due to higher rates of replicative fork movement. In vitro replication in the presence of protein-free competitor DNA shows that replicating trypsinized minichromosomes do not lose nucleosomes and replicating competitor DNA does not gain nucleosomes. This finding suggests that tailless nucleosomes are transferred from the unreplicated prefork stem to replicated DNA branches and excludes a participation of the basic histone domains in nucleosome transfer.

DNA fragments in the blood plasma of cancer patients: quantitations and evidence for their origin from apoptotic and necrotic cells.

Increased levels of DNA fragments have frequently been found in the blood plasma of cancer patients. Published data suggest that only a fraction of the DNA in blood plasma is derived from cancer cells. However, it is not known how much of the circulating DNA is from cancer or from noncancer cells. By quantitative methylation-specific PCR of the promoter region of the CDKN2A tumor suppressor gene, we were able to quantify the fraction of plasma DNA derived from tumor cells. In the plasma samples of 30 unselected cancer patients, we detected quantities of tumor DNA from only 3% to as much as 93% of total circulating DNA. We investigated possible origins of nontumor DNA in the plasma and demonstrate here a contribution of T-cell DNA in a few cases only. To investigate the possibility that plasma DNA originates from apoptotic or necrotic cells, we performed studies with apoptotic (staurosporine) and necrotic (staurosporine plus oligomycin) cells in vitro and with mice after induction of apoptotic (anti-CD95) or necrotic (acetaminophen) liver injury. Increasing amounts of DNA were found to be released in the supernatants of cells and in the blood plasma samples of treated animals. A clear discrimination of apoptotic and necrotic plasma DNA was possible by gel electrophoresis. The same characteristic patterns of DNA fragments could be identified in plasma derived from different cancer patients. The data are consistent with the possibility that apoptotic and necrotic cells are a major source for plasma DNA in cancer patients.

An SV40 large T antigen binding site in the cellular genome is part of a cis-acting transcriptional element.

A genomic mouse DNA fragment (Q300), containing a high affinity binding site for SV40 large T antigen, serves as a cis-acting transcriptional element in in vivo and in in vitro studies. We have performed experiments to investigate whether bound T antigen could modulate the promoter-enhancer activity of the Q300 element. In vivo studies showed a negative effect of T antigen on the Q300 driven expression of the chloramphenicol acetyl transferase reporter gene. Band shift and DNAase I protection experiments demonstrated that T antigen and a nuclear protein, probably a CCAAT-binding factor, can simultaneously bind to closely adjacent sites on the Q300 DNA. Transcription studies in vitro showed that bound T antigen suppresses the transcriptional enhancer effect of the Q300 element. We interpret the results of these model studies to indicate that T antigen, bound to DNA, is able to affect the function of a cellular cis-acting transcriptional element. Bound T antigen may influence the activity of a cellular transcription factor at a closely adjacent DNA site.

Chromatin-associated protein kinases specific for acidic proteins.

Protein kinases (EC 2.7.1.37) were eluted by 0.4 NaCl from chromatin of several mammalian cell typs. The enzymes were partially purified by ion-exchange chromatography, DNA-cellulose columns and sucrose gradient centrifugation. At least five different enzymes could be distinguished by their biochemical properties and their substrate specificities. Three of the enzyme activities tested phosphorylate different sets of histones, while two enzymes phosphorylate acidic nonhistone chromatin proteins or artificial substrates like casein and phosvitin. The two nonhistone protein kinases have slightly different pH and salt optima. They sediment through sucrose gradients with approx. 4 S and approx. 8 S, respectively. These enzymes are further characterized by their different substrate specificity, since they phosphorylate different, though partially overlapping sets of nonhistone chromatin proteins. Enzymes with these properties were deteced in chromatin from mouse ascites cells, bovine lymphocytes, African green monkey kidney cells and a human SV40 transformed cell line.

Comparison of replicative and non-replicative chromatin assembly pathways in HeLa cell extracts.

It has been reported that chromatin assembly in mammalian cell extracts depends exclusively or preferentially on ongoing DNA replication (Stillman, B. (1986) Cell 45, 555-565). More recently, this view has been challenged demonstrating that, in the same extracts, chromatin can also be formed efficiently in the absence of DNA replication (Gruss et al. (1990) EMBO J. 9, 2911-2922). The experiments, described in this communication, were performed to resolve this apparent contradiction. We found that there are at least two distinct in vitro pathways for chromatin assembly in HeLa cell extracts. The replicative pathway requires a nuclear protein, most likely identical with the chromatin assembly factor, described by Stillman (1986, Cell 45, 555-565), and the free soluble histones present in the cytosol of S phase cells. In contrast, a non-replicative pathway was identified that depends on isolated nuclear histones. As one component of the non-replicative assembly pathway we identified a cytosolic factor that was purified to apparent homogeneity and shown to be an acidic 50 kDa polypeptide. The isolated cytosolic 50 kDa protein efficiently promoted nucleosome assembly as demonstrated by one- and two-dimensional gel electrophoresis of in vitro packaged plasmid DNA.

Glutaminyl-tRNA synthetase as a component of the high-molecular weight complex of human aminoacyl-tRNA synthetases. An immunological study.

The human glutaminyl-tRNA synthetase is three times larger than the corresponding bacterial and twice as large as the yeast enzyme. It is possible that the additional sequences of the human glutaminyl-tRNA synthetase are required for the formation of the multienzyme complex which is known to include several of aminoacyl-tRNA synthetases in mammalian cells. To address this point we prepared antibodies against three regions of the human glutaminyl-tRNA synthetase, namely against its enzymatically important core region, and against two sections in its large C-terminal extension. In intact multienzyme complexes the core region was accessible to specific antibody binding. However, the C-terminal sections became available to specific antibody binding only when certain components of the multienzyme complex were either absent or degraded. These findings allow first conclusions as to the relative position of some components in the mammalian aminoacyl-tRNA synthetase complex.

A histone H4-specific methyltransferase. Properties, specificity and effects on nucleosomal histones.

A histone H4-specific methyltransferase was purified 80-100-fold from nuclei of calf lymphocytes and from calf thymus. Some biochemical properties of the enzyme are described. The enzyme transfers in vitro methyl groups from S-adenosylmethionine preferentially to the lysine residue 20 of histone H4. This is the major in vivo methylation site of H4. DNA-bound or nucleosomal H4 is not methylated in vitro. We have used methylated and unmodified H4 (in the presence of sufficient quantities of the other core histones) for nucleosome reconstitution in vitro and have not found significant differences in the efficiencies of assembly.

ATP and the processivity of Xenopus laevis DNA polymerase alpha.

We use specific restriction fragments as defined primers for DNA synthesis on single-stranded circular phage fd DNA. These structures are relatively poor templates for a highly purified DNA polymerase alpha from Xenopus laevis eggs. However, DNA synthesis is stimulated about 5-fold by addition of ATP to the reaction mixture. We show that the deoxynucleotide polymers, synthesized in the presence of ATP, are significantly longer than those produced in the absence of ATP. We also show that this effect is due to a more tenacious binding of DNA polymerase alpha to DNA and conclude that ATP increases the processivity of the enzyme.

Zinc affects the conformation of nucleoprotein filaments formed by replication protein A (RPA) and long natural DNA molecules.

Replication protein A is the major single strand DNA binding protein of human cells, composed of three subunits with molecular weights of 70, 32, and 14 kDa. Most of the DNA binding activity of RPA has been mapped to the largest subunit that contains two OB-fold DNA binding domains and a third, OB-like structure in the carboxyterminal domain (CTD). This third domain resembles an OB-fold with a zinc binding domain inserted in the middle of the structure, and has recently been shown to carry a coordinated Zn(II) ion. The bound metal ion is essential for the tertiary structure of the RPA70-CTD, and appears to modulate its DNA binding activity when tested with synthetic oligonucleotides. We show here that zinc strongly affects the conformation of nucleoprotein filaments formed between RPA and long natural DNA molecules. In these experiments, the CTD is dispensable for DNA binding and the unwinding of long double stranded DNA molecules. However, using band shift assays and electron microscopy, we found that RPA-DNA complexes contract at zinc concentrations that do not affect the conformations of complexes formed between DNA and a RPA70 deletion construct lacking the CTD. Our data suggest that nucleoprotein complexes with RPA in its natural, zinc-bearing form may have a compact rather than an extended conformation.

Protein-DNA interactions at the simian virus 40 origin of replication.

Simian Virus 40 (SV40)-encoded large T antigen has an intrinsic ATP-dependent DNA-unwinding activity which is necessary for an early step in the activation of the viral origin of replication. Isolated T antigen unwinds any double-stranded DNA, regardless of whether it is linear or circularly closed. However, initiation of DNA replication depends on an intact origin of replication, and even minor deviations from the wild-type origin sequence abolish the template activity of an origin-bearing plasmid. This discrepancy suggests that T antigen may not be sufficient for origin activation and that other, probably cellular, functions are involved. We have isolated a cellular protein, the LOB protein, which specifically interacts with the AT-rich region of the SV40 origin and which induces a pronounced bending of the bound DNA.

Conserved regulatory elements in the type I DNA topoisomerase gene promoters of mouse and man.

The gene for mammalian type I DNA topoisomerase is constitutively expressed, but also regulated by a number of external stimuli. We compared the nucleotide sequences of the human and the mouse topoisomerase I gene promoters because promoter elements, essential for basic as well as regulated gene expression, should be conserved during evolution. We found that proximal upstream sequences are highly conserved and include potential binding sites for ubiquitous transcription factors, a regulatory CRE site as well as two novel promoter elements that have been shown to be important for the expression of the human gene. The more distal parts of the upstream sequences are less well conserved but include two regions that are almost identical in the human and the mouse gene. One of these regions contains a binding site for a basic-helix-loop-helix/leucine-zipper protein, and the other contains an AT-rich element with the potential for DNA bending.

Excision of integrated simian virus 40 DNA involving homologous recombination between viral DNA sequences.

We have investigated the structure of simian virus 40 (SV40) DNA integrated into the genome of transformed mouse mKS-A cells. We have identified at least six independent integration units containing intact or truncated SV40 DNA sequences. One integration unit was isolated from a genomic mKS-A cell library and investigated by restriction enzyme analysis and partial nucleotide sequencing. This integration unit contains one apparently intact SV40 genome flanked on both sides by truncated versions of the SV40 genome. One of the flanking elements contains a large deletion in the SV40 "late" region and an abbreviated SV40 "early" region. This element was efficiently excised and mobilized after fusion of mKS-A to COS cells. The excision products invariably included the entire SV40 early region even though they were derived from an integrated element lacking this part of the SV40 genome. An analysis of this discrepancy led to the conclusion that the early region sequences were acquired by homologous recombination and, furthermore, that homologous excisional recombination was clearly preferred over non-homologous recombination.

Replication protein A induces the unwinding of long double-stranded DNA regions.

We have investigated nucleoprotein filaments composed of human replication protein A (RPA) and DNA by electron microscopy. At low ionic strengths, RPA complexes with single-stranded DNA are similar in length to protein-free DNA suggesting that RPA-bound DNA remains in an extended configuration under these conditions. However, severe compaction of RPA-DNA complexes occurs in buffers with > 2 mM MgCl2 or with 100 mM NaCl. At low ionic strengths, RPA binds to A + T-rich internal regions of linear double-stranded simian virus 40 (SV40) DNA and induces separation of complementary DNA strands. RPA also binds to closed-circular SV40 DNA, but requires the function of a DNA topoisomerase to invade and completely unwind duplex DNA regions. The ability of RPA to unwind long stretches of double-stranded DNA is not shared by the bacterial single-strand binding protein and the phage T4 gene 32 protein.

Protein-induced bending of the simian virus 40 origin of replication.

A 3.5 S protein, isolated from mammalian nuclei, specifically binds to DNA fragments containing the simian virus 40 (SV40) origin of replication. Two distinct nucleoprotein complexes are formed, a complex with high electrophoretic mobility carrying probably only one protein molecule, and a complex with reduced electrophoretic mobility carrying probably two protein molecules per DNA fragment. Band shift competition as well as methylation interference assays locate the binding site of the protein in the A + T-rich "late" region of the origin between SV40 nucleotides 13 and 35. The late origin binding (LOB) protein and T antigen bind simultaneously to adjacent sites in the origin. Using circularly permuted DNA fragments of identical lengths we show that the LOB protein induces pronounced bending of the origin fragment. The bending center maps at the 5' end of the adenine tract with one bound protein molecule and at the 3' end when two LOB proteins are bound to one origin fragment.