Presence of transcription signals in two putative DNA replication origins of human cells

DNA-protein interaction dynamics at the Lamin B2 replication origin

To date, a complete understanding of the molecular events leading to DNA replication origin activation in mammalian cells still remains elusive. In this work, we report the results of a high resolution chromatin immunoprecipitation study to detect proteins interacting with the human Lamin B2 replication origin. In addition to the pre-RC component ORC4 and to the transcription factors USF and HOXC13, we found that 2 components of the AP-1 transcription factor, c-Fos and c-Jun, are also associated with the origin DNA during the late G1 phase of the cell cycle and that these factors interact with ORC4. Both DNA replication and AP-1 factor binding to the origin region were perturbed by cell treatment with merbarone, a topoisomerase II inhibitor, suggesting that DNA topology is essential for determining origin function.

In vivo protein-DNA interactions at human DNA replication origin

Protein-DNA interactions were studied in vivo at the region containing a human DNA replication origin, located at the 3' end of the lamin B2 gene and partially overlapping the promoter of another gene, located downstream. DNase I treatment of nuclei isolated from both exponentially growing and nonproliferating HL-60 cells showed that this region has an altered, highly accessible, chromatin structure. High-resolution analysis of protein-DNA interactions in a 600-bp area encompassing the origin was carried out by the in vivo footprinting technique based on the ligation-mediated polymerase chain reaction. In growing HL-60 cells, footprints at sequences homologous to binding sites for known transcription factors (members of the basic-helix-loop-helix family, nuclear respiratory factor 1, transcription factor Sp1, and upstream binding factor) were detected in the region corresponding to the promoter of the downstream gene. Upon conversion of cells to a nonproliferative state, a reduction in the intensity of these footprints was observed that paralleled the diminished transcriptional activity of the genomic area. In addition to these protections, in close correspondence to the replication initiation site, a prominent footprint was detected that extended over 70 nucleotides on one strand only. This footprint was absent from nonproliferating HL-60 cells, indicating that this specific protein-DNA interaction might be involved in the process of origin activation.

A novel DNA replication origin identified in the human heat shock protein 70 gene promoter

A general and sensitive method for the mapping of initiation sites of DNA replication in vivo, developed by Vassilev and Johnson, has revealed replication origins in the region of simian virus 40 ori, in the regions upstream from the human c-myc gene and downstream from the Chinese hamster dihydrofolate reductase gene, and in the enhancer region of the mouse immunoglobulin heavy-chain gene. Here we report that the region containing the promoter of the human heat shock protein 70 (hsp70) gene was identified as a DNA replication origin in HeLa cells by this method. Several segments of the region were cloned into pUC19 and examined for autonomously replicating sequence (ARS) activity. The plasmids carrying the segments replicated episomally and semiconservatively when transfected into HeLa cells. The segments of ARS activity contained the sequences previously identified as binding sequences for a c-myc protein complex (T. Taira, Y. Negishi, F. Kihara, S. M. M. Iguchi-Ariga, and H. Ariga, Biochem. Biophys. Acta 1130:166-174, 1992). Mutations introduced within the c-myc protein complex binding sequences abolished the ARS activity. Moreover, the ARS plasmids stably replicated at episomal state for a long time in established cell lines. The results suggest that the promoter region of the human hsp70 gene plays a role in DNA replication as well as in transcription.

A novel DNA replication origin identified in the human heat shock protein 70 gene promoter

A general and sensitive method for the mapping of initiation sites of DNA replication in vivo, developed by Vassilev and Johnson, has revealed replication origins in the region of simian virus 40 ori, in the regions upstream from the human c-myc gene and downstream from the Chinese hamster dihydrofolate reductase gene, and in the enhancer region of the mouse immunoglobulin heavy-chain gene. Here we report that the region containing the promoter of the human heat shock protein 70 (hsp70) gene was identified as a DNA replication origin in HeLa cells by this method. Several segments of the region were cloned into pUC19 and examined for autonomously replicating sequence (ARS) activity. The plasmids carrying the segments replicated episomally and semiconservatively when transfected into HeLa cells. The segments of ARS activity contained the sequences previously identified as binding sequences for a c-myc protein complex (T. Taira, Y. Negishi, F. Kihara, S. M. M. Iguchi-Ariga, and H. Ariga, Biochem. Biophys. Acta 1130:166-174, 1992). Mutations introduced within the c-myc protein complex binding sequences abolished the ARS activity. Moreover, the ARS plasmids stably replicated at episomal state for a long time in established cell lines. The results suggest that the promoter region of the human hsp70 gene plays a role in DNA replication as well as in transcription.

cDNA clones contain autonomous replication activity

We have undertaken to investigate transcription as a regulatory event in mammalian DNA replication. Subpopulations of transcripts represented in a cDNA library of human embryo lung fibroblasts (IMR90) were examined for their ability to support autonomous replication after transfection into human cells (HeLa). Two of three cDNA clones (343, 363) containing 'O'-family repetitive sequences, after subcloning into pBR322 and transfection into HeLa cells, were capable of autonomous replication. One of these cDNA clones, 343, is enriched by selection for poly(A)+ RNA. In contrast, none of five Alu-containing transcripts was capable of autonomous replication in human cells. However, six out of ten cDNA clones contained neither 'O'-family or Alu homologous sequences and were as efficient as the cDNA clones containing 'O'-family sequences in replicating autonomously in human cells. cDNA clones, from an oligo-d(T)-primed library of human poly(A)+ enriched RNA, contain a significant proportion of independent clones that can also support autonomous replication of bacterial plasmids in human cells. cDNA clone 343 was observed to contain in a 448 bp EcoRI-HincII fragment, yeast ARS consensus, SAR consensus, IRs, bent DNA and a DUE, all sequence and structural characteristics often associated with many prokaryotic, viral and eukaryotic origins. Sequence analysis of seven other cDNA clones (from non-'O'-family, non-Alu homologous sequences, NOA) showed that five contained some of the same consensus sequences. Two NOA clones (NOA4 and -5) did not contain any representations of ARS and SAR consensus sequences, suggesting that these two features may not be essential for autonomous replication activity in mammalian cells.

Interactions of USF and Ku antigen with a human DNA region containing a replication origin

By means of a combination of ion-exchange and sequence-specific affinity chromatography techniques, we have purified to homogeneity two protein complexes binding in a human DNA region (B48) previously recognized to contain a DNA replication origin. The DNA sequence used for the protein purification (B48 binding site) contains a binding site for basic-helix-loop-helix DNA binding proteins. The first complex is composed of two polypeptides of 42- and 44-kDa; its size, heat stability, and target DNA sequence suggest that it corresponds to transcription factor USF; furthermore, the 42-kDa polypeptide is recognized by antibodies raised against 43-kDa-USF. The second complex is represented by equimolar amounts of two proteins of 72 and 87 kDa; microsequencing of the two species indicated that they correspond to the human Ku antigen. In analogy with Ku, they produce a regular pattern of footprints without an apparent sequence-specificity, and their binding can be competed by unspecific DNA provided that it contains free ends. The potential role of B48 binding site and of these cognate proteins in origin activation is discussed.

Identification of the initiation region of DNA replication in the murine immunoglobulin heavy chain gene and possible function of the octamer motif as a putative DNA replication origin in mammalian cells

An origin region of DNA replication in the murine immunoglobulin heavy chain (IgH) gene was identified by BrdU pulse labeling and PCR amplification methods. The origin region spans about 1000 base pairs and contains the region of transcriptional enhancer in which the octamer sequence is present. The octamer sequence, TNATTTGCAT, is a well-conserved promoter/enhancer element responsible for B cell-specific transcription and is also found in the regulatory sequences for histone genes and others. Its activity as an autonomously replicating sequence was further examined. The murine IgH enhancer region containing the octamer motif was cloned in pUC18 and transfected to HeLa cells. After 60-65 h, the low molecular weight DNA was extracted and the degree to which the plasmid DNA had been replicated in the cells was measured by back-transformation of competent bacteria. Five to ten copies of the plasmid were detected per cell. The replicated plasmid-form DNA could be detected by this assay for at least 7 days after transfection. Synthetic oligonucleotides corresponding to the octamer and the Ephrussi box in the IgH enhancer were also cloned into pUC18 and examined for replicating activity. These plasmids replicated provided that the octamer sequence remained intact, irrespective of the Ephrussi box sequence and of the sites of insertion. These results suggest that the octamer transcriptional element may also serve as a putative origin for cellular DNA replication.

A human DNA replication origin: localization and transcriptional characterization

A single-copy 13.7 kb human DNA region (L30E) located on Ch. 19 p13.3 contains an origin of DNA replication in myeloid HL-60 cells. The origin was localized, by means of quantitative PCR within approximately 3000 bp, in a highly transcribed region containing at least two closely spaced genes with the same polarity of transcription, one encoding lamin B2 and the other an unidentified protein. The origin region overlaps an undermethylated "CpG island" at the 5'-end of the second transcription unit. A binding site (CACGTG) for basic helix-loop-helix (bHLH) DNA binding proteins such as USF/MLTF or MYC-MAX was located by DNase I footprinting analysis in the promoter of the second gene. DMSO differentiation of HL-60 cells, that completely shuts off replication, also drastically reduces the transcription of L30E region. On the other hand such treatment does not modify the methylation pattern of the CpG island and does not abolish the DNase I protection of the bHLH binding site.

The gene for a novel human lamin maps at a highly transcribed locus of chromosome 19 which replicates at the onset of S-phase

A previously described human DNA fragment which is replicated early in S-phase of HL-60 cell DNA (C. Tribioli, G. Biamonti, M. Giacca, M. Colonna, S. Riva, and A. Falaschi, Nucleic Acids Res. 15:10211-10232, 1987) was used to screen a genomic library in lambda Ch28. A clone which contained a 13.7-kb insert (L30E) found to code for several transcripts was isolated. The transcription of L30E DNA exhibited a complex pattern and a tissue-specific and proliferation-dependent type of regulation. The data were consistent with two tandemly arranged transcription units, the 3' end of one separated from the 5' end of the other by a sequence of about 600 bp containing an active promoter. The isolation and sequencing of L30E-specific cDNAs permitted identification of two genes, one of which encoded a B-type human lamin (analogous to mouse lamin B2). L30E DNA was mapped by in situ hybridization at the G-negative subtelomeric band p13.3 of chromosome 19. Interestingly, in synchronized HL-60 cells, L30E DNA is replicated in the first minute of S-phase. Replication of the lamin gene early in S-phase may reflect a coupling between early replication and transcription of genes for S-phase-specific proteins such as lamins.

The replication activation potential of selected RNA polymerase II promoter elements at the simian virus 40 origin

Binding sites for cellular transcription factors were placed near the simian virus 40 origin of replication, and their effect on replication and TATA-dependent transcription was measured in COS cells. The hierarchy of transcriptional stimulation changed when the plasmids replicated. Only one of seven inserted sequences, a moderately weak transcription element, stimulated replication detectably. However, when two nonstimulatory sites were present in multiple copies they did activate replication. Multiple sites for the chimeric activator GAL4-VP16 did not stimulate replication even though transcription was stimulated strongly. The results indicate that the ability of a binding site to stimulate replication from the simian virus 40 ori is not based on its transcriptional activation potential but is instead related to a separate replication activation potential that can be increased by having multiple sites.

The gene for a novel human lamin maps at a highly transcribed locus of chromosome 19 which replicates at the onset of S-phase

A previously described human DNA fragment which is replicated early in S-phase of HL-60 cell DNA (C. Tribioli, G. Biamonti, M. Giacca, M. Colonna, S. Riva, and A. Falaschi, Nucleic Acids Res. 15:10211-10232, 1987) was used to screen a genomic library in lambda Ch28. A clone which contained a 13.7-kb insert (L30E) found to code for several transcripts was isolated. The transcription of L30E DNA exhibited a complex pattern and a tissue-specific and proliferation-dependent type of regulation. The data were consistent with two tandemly arranged transcription units, the 3' end of one separated from the 5' end of the other by a sequence of about 600 bp containing an active promoter. The isolation and sequencing of L30E-specific cDNAs permitted identification of two genes, one of which encoded a B-type human lamin (analogous to mouse lamin B2). L30E DNA was mapped by in situ hybridization at the G-negative subtelomeric band p13.3 of chromosome 19. Interestingly, in synchronized HL-60 cells, L30E DNA is replicated in the first minute of S-phase. Replication of the lamin gene early in S-phase may reflect a coupling between early replication and transcription of genes for S-phase-specific proteins such as lamins.

The replication activation potential of selected RNA polymerase II promoter elements at the simian virus 40 origin

Binding sites for cellular transcription factors were placed near the simian virus 40 origin of replication, and their effect on replication and TATA-dependent transcription was measured in COS cells. The hierarchy of transcriptional stimulation changed when the plasmids replicated. Only one of seven inserted sequences, a moderately weak transcription element, stimulated replication detectably. However, when two nonstimulatory sites were present in multiple copies they did activate replication. Multiple sites for the chimeric activator GAL4-VP16 did not stimulate replication even though transcription was stimulated strongly. The results indicate that the ability of a binding site to stimulate replication from the simian virus 40 ori is not based on its transcriptional activation potential but is instead related to a separate replication activation potential that can be increased by having multiple sites.

Influence of chromatin molecular changes on RNA synthesis during embryonic development

Two aspects of the chromatin repeat length (rl) are discussed: (i) Why is rl longer for slowly dividing cells than in rapidly dividing cells?, and (ii) Why is the temporal evolution of rl a decreasing function of time (t) in mammalian cortical neurons, whereas it is an increasing function of t for granule cells around the time of birth? These questions are discussed in terms of a hypothesis which assumes a correlation between deoxyribonucleic acid (DNA) packaging, transcription, and replication.

Towards the molecular bases of polymerase dynamics

One aspect of the strong relationship that is known to exist between the processes of DNA replication and transcription is manifest in the coupling of the rates of movement of the replication fork (rf) and RNA polymerase (rt). We address two issues concerning the largely unexplored area of polymerase dynamics: (i) The validity of an approximate kinematic formula linking rf and rt suggested by experiments in which transcription is inhibited in some prokaryotes with the antibiotic streptolydigin, and (ii) What are the molecular bases of the kinematic formula? An analysis of the available data suggests possible molecular bases for polymerase dynamics. In particular, we are led to a hypothesis: In active chromatin rt may depend on the length (lambda t) of the transcript of the primary messenger RNA (pre-mRNA). This new effect is subject to experimental verification. We discuss possible experiments that may be performed in order to test this prediction.

Relationship of eukaryotic DNA replication to committed gene expression: general theory for gene control

The historic arguments for the participation of eukaryotic DNA replication in the control of gene expression are reconsidered along with more recent evidence. An earlier view in which gene commitment was achieved with stable chromatin structures which required DNA replication to reset expression potential (D. D. Brown, Cell 37:359-365, 1984) is further considered. The participation of nonspecific stable repressor of gene activity (histones and other chromatin proteins), as previously proposed, is reexamined. The possible function of positive trans-acting factors is now further developed by considering evidence from DNA virus models. It is proposed that these positive factors act to control the initiation of replicon-specific DNA synthesis in the S phase (early or late replication timing). Stable chromatin assembles during replication into potentially active (early S) or inactive (late S) states with prevailing trans-acting factors (early) or repressing factors (late) and may asymmetrically commit daughter templates. This suggests logical schemes for programming differentiation based on replicons and trans-acting initiators. This proposal requires that DNA replication precede major changes in gene commitment. Prior evidence against a role for DNA replication during terminal differentiation is reexamined along with other results from terminal differentiation of lower eukaryotes. This leads to a proposal that DNA replication may yet underlie terminal gene commitment, but that for it to do so there must exist two distinct modes of replication control. In one mode (mitotic replication) replicon initiation is tightly linked to the cell cycle, whereas the other mode (terminal replication) initiation is not cell cycle restricted, is replicon specific, and can lead to a terminally differentiated state. Aberrant control of mitotic and terminal modes of DNA replication may underlie the transformed state. Implications of a replicon basis for chromatin structure-function and the evolution of metazoan organisms are considered.

DNA helicase IV from HeLa cells

Human DNA helicase IV, a novel enzyme, was purified to homogeneity from HeLa cells and characterized. The activity was measured by assaying the unwinding of 32P labeled 17-mer annealed to M13 ss DNA. From 440g of HeLa cells we obtained 0.31 mg of pure protein. Helicase IV was free of DNA topoisomerases, DNA ligase and nuclease activities. The apparent molecular weight is 100 kDa. It requires a divalent cation for activity (Mg2+ = Mn2+ = Zn2+) and the hydrolysis of only ATP or dATP. The activity is destroyed by trypsin and is inhibited by 200 mM KCl or NaCl, 100 mM potassium phosphate, 45 mM ammonium sulfate, 5 mM EDTA, 20 microM ss M13 DNA or 20 microM poly [G] (as phosphate). The enzyme unwinds DNA by moving in the 5' to 3' direction along the bound strand, a polarity opposite to that of the previously described human DNA helicase I (Tuteja et al Nucleic Acids Res. 18, 6785-6792, 1990). It requires more than 84 bases of single-stranded DNA in order to exert its unwinding activity and does not require a replication fork-like structure. Like human DNA helicase I the enzyme can also unwind RNA-DNA hybrid.

Mimosine reversibly arrests cell cycle progression at the G1-S phase border

It has previously been demonstrated that the compound mimosine inhibits cell cycle traverse in late G1 phase prior to the onset of DNA synthesis (Hoffman BD, Hanauske-Abel HM, Flint A, Lalande M: Cytometry 12:26-32, 1991; Lalande M: Exp Cell Res 186:332-339, 1990). These results were obtained by using flow cytometric analysis of DNA content to compare the effects of mimosine on cell cycle traverse with those of aphidicolin, an inhibitor of DNA polymerase alpha activity. We have now measured the incorporation of bromodeoxyuridine into lymphoblastoid cells by flow cytometry to determine precisely where the two inhibitors act relative to the initiation of DNA synthesis. It is demonstrated here that mimosine arrests cell cycle progression at the G1-S phase border. The onset of DNA replication occurs within 15 min of releasing the cells from the mimosine block. In contrast, treatment with aphidicolin results in the accumulation of cells in early S phase. These results indicate that mimosine is a suitable compound for affecting the synchronous release of cells from G1 into S phase and for analyzing the biochemical events associated with this cell cycle phase transition.

Minimal subenhancer requirements for high-level polyomavirus DNA replication: a cell-specific synergy of PEA3 and PEA1 sites

The cell-specific regulation of DNA replication has important implications for the molecular strategy of cellular gene control. Mouse polyomavirus (Py) DNA replication is examined as a model of cell-specific replication control. Using an FM3A-derived mouse cell line which expresses early viral proteins (FOP cells), we determined the minimal sequence requirements for viral DNA replication. FOP cells were observed to have much simpler enhancer requirements than 3T6 and many other cells and did not need a B enhancer for high levels of DNA replication. Using these cells, we show that the individual or tandem binding sites for several unrelated trans-acting factors which are generally subfunctional as transcriptional enhancers (simian virus 40 A core, TGTGGAATG; EBP20, TGTGGTTTT; PEA1 [an AP-1 analog], GTGACTAA; PEA2, GACCGCAG; and PEA3, AGGAAG) stimulated low levels of Py DNA replication. The ordered dimeric combination of PEA3 and PEA1 factor-binding sites, however, acted synergistically to stimulate viral DNA replication to high wild-type levels. This is in contrast to prior results in which much larger enhancer sequences were necessary for high-level viral DNA replication. PEA3/PEA1-stimulated DNA replication showed a distance and orientation independence relative to the origin, which disagrees with some but not other prior analyses of enhancer-dependent DNA replication. It therefore appears that trans-acting factor-binding sites (enhansons) can generally activate DNA replication and that the AP-1 family of sites may act synergistically with other associated trans-acting factors to strongly affect Py DNA replication in specific cells.

Minimal subenhancer requirements for high-level polyomavirus DNA replication: a cell-specific synergy of PEA3 and PEA1 sites

The cell-specific regulation of DNA replication has important implications for the molecular strategy of cellular gene control. Mouse polyomavirus (Py) DNA replication is examined as a model of cell-specific replication control. Using an FM3A-derived mouse cell line which expresses early viral proteins (FOP cells), we determined the minimal sequence requirements for viral DNA replication. FOP cells were observed to have much simpler enhancer requirements than 3T6 and many other cells and did not need a B enhancer for high levels of DNA replication. Using these cells, we show that the individual or tandem binding sites for several unrelated trans-acting factors which are generally subfunctional as transcriptional enhancers (simian virus 40 A core, TGTGGAATG; EBP20, TGTGGTTTT; PEA1 [an AP-1 analog], GTGACTAA; PEA2, GACCGCAG; and PEA3, AGGAAG) stimulated low levels of Py DNA replication. The ordered dimeric combination of PEA3 and PEA1 factor-binding sites, however, acted synergistically to stimulate viral DNA replication to high wild-type levels. This is in contrast to prior results in which much larger enhancer sequences were necessary for high-level viral DNA replication. PEA3/PEA1-stimulated DNA replication showed a distance and orientation independence relative to the origin, which disagrees with some but not other prior analyses of enhancer-dependent DNA replication. It therefore appears that trans-acting factor-binding sites (enhansons) can generally activate DNA replication and that the AP-1 family of sites may act synergistically with other associated trans-acting factors to strongly affect Py DNA replication in specific cells.

A protein target site in an early replicated human DNA sequence: a highly conserved binding motif

We have previously reported that a human nuclear factor, probably corresponding to the USF/MLTF protein [1,2], is able to bind specifically to a DNA sequence present in DNA replicated at the onset of S-phase [3]. Here we demonstrate that the same factor binds also to several other similar sequences, present in eukaryotic and viral genomes. Mutations or methylation in a CpG dinucleotide, central in the palindromic binding site, completely abolish binding. Furthermore, we present evidence for the existence of at least two other nuclear proteins in human cells with the same DNA binding specificity. The data presented suggest a strong evolutionary conservation, among distantly related organisms, of the binding motif, which is probably the target of a number of nuclear factors that share the same DNA binding specificity albeit in the context of different functions.