New beginnings in studies of eukaryotic DNA replication origins

Early events in eukaryotic DNA replication

Eukaryotic DNA replication is a tightly regulated process that occurs during a discrete period of the cell cycle known as S phase. Recent work in two different systems has identified key participants in this process and characterized many of the protein-protein interactions required for the establishment of functional replication complexes. From these results, an understanding of how the control of DNA replication is exercised during the cell cycle appears to be on the horizon.

Replication of minichromosomes in Saccharomyces cerevisiae is sensitive to histone gene copy number and strain ploidy

We have characterized a defect in the mitotic transmission of plasmid minichromosomes in yeast strains deleted for the more highly expressed pair of histone H3 and H4 genes. Several observations indicate that an impairment in DNA replication contributes to the decrease in minichromosome stability. First, the maintenance of ARS plasmids that lack centromeres was also defective. Second, the addition of multiple ARS elements suppressed the defect in plasmid maintenance. Third, a synergistic increase in plasmid loss rate was seen when a plasmid containing an inefficient mutated ARS was tested in a strain deleted for histone genes, implying an interaction between ARS activity and the histone gene deletion. These results support the existence of a histone-dependent step in the initiation of DNA replication. We find that the stability of native chromosomes is not affected in strains deleted for histone genes. We propose that reduced histone H3 and H4 protein decreases the efficiency of initiation at ARS elements on plasmids and chromosomes, but that the presence of multiple origins on chromosomes compensates for the reduced efficiency. We find that decreased minichromosome stability is suppressed by increases in strain ploidy. The greater stability due to ploidy increases is not due to a relative increase in the expression of histone genes. We discuss models for the effect of strain ploidy on minichromosome maintenance.

Interactions of Epstein-Barr virus origins of replication with nuclear matrix in the latent and in the lytic phases of viral infection

Eukaryotic DNA is organized into domains or loops generated by the attachment of chromatin fibers to the nuclear matrix via specific regions called scaffold or matrix attachment regions. The role of these regions in DNA replication is currently under investigation since they have been found in close association with origins of replication. Also, viral DNA sequences, containing the origins of replication, have been found attached to the nuclear matrix. To investigate the functional role of this binding we have studied, in Raji cells, the interaction between Epstein-Barr virus (EBV) origins of replication and the nuclear matrix in relation to the viral cycle of infection. We report here that both the latent (ori P) and the lytic (ori Lyt) EBV origins of replication are attached to the nuclear matrix, the first during the latent cycle of infection and the second after induction of the lytic cycle. These findings suggest that the binding of the origins of replication with the nuclear matrix modulates viral replication and expression in the two different phases of infection.

A family of telomere-associated autonomously replicating sequences and their functions in targeted recombination in Hansenula polymorpha DL-1

A family of multiple autonomously replicating sequences (ARSs) which are located at several chromosomal ends of Hansenula polymorpha DL-1 has been identified and characterized. Genomic Southern blotting with an ARS, HARS36, originating from the end of a chromosome, as a probe showed several homologues in the genome of H. polymorpha. Nucleotide sequences of the three fragments obtained by a selective cloning for chromosomal ends were nearly identical to that of HARS36. All three fragments harbored an ARS motif and ended with 18 to 23 identical repetitions of 5'-GGGTGGCG-3' which resemble the telomeric repeat sequence in other eukaryotes. Transformation of H. polymorpha with nonlinearized plasmids containing the newly obtained telomeric ARSs almost exclusively resulted in the targeted integration of a single copy or multiple tandem copies of the plasmid into the chromosomes. The sensitivity to exonuclease Bal31 digestion of the common DNA fragment in all integrants confirmed the telomeric origin of HARS36 homologues, suggesting that several chromosomal ends, if not all of them, consisted of the same ARS motif and highly conserved sequences observed in HARS36. Even though the frequencies of targeted recombination were varied among the ends of the chromosomes, the overall frequency was over 96%. The results suggested that the integration of the plasmids containing telemeric ARSs occurred largely through homologous recombination at the telomeric repeats, which serve as high-frequency recombination targets.

Mapping of replication origins and termination sites in the Duchenne muscular dystrophy gene

The replication structure of the human dystrophin gene in cultured masculine erythroleukemia cells (line HEL 92.1.7) was studied using the replication direction assay. This gene is organized into at least six replicons ranging in size from 170 to more than 500 kb. One of the replicon junctions (sites of replication termination) was mapped to intron 44, i.e., roughly in the same area where the major recombination hot spot is located. A replicon junction was also found between the muscle and the brain promoters. The two replicons mapped in the present study are highly asymmetric, as the distances covered by the replication forks moving in opposite directions from the same origin differ by more than threefold.

Inactivation of topoisomerase I or II may lead to recombination or to aberrant replication termination on both SV40 and yeast 2 micron DNA

Topoisomerase I is believed to be sufficient for early replication of circular viral genomes such as those of SV40 and of yeast plasmids. Topoisomerase II is required for the decatenation of the daughter genomes and probably also for fork elongation during the later stages of SV40 replication. Using the neutral-neutral two-dimensional gel system, we have followed the progression of replication of both SV40 and the yeast 2 micron plasmid under various conditions of topoisomerase inhibition. During SV40 replication, inhibition of topoisomerase II by VP16, VM26 or hypertonic shock (but not by merbarone), and inhibition of topoisomerase I by camptothecin all led to the accumulation of aberrant DNA structures containing two almost completely replicated genomes. These aberrant structures resembled either recombination intermediates or late Cairns structures in which the site of replication termination had shifted and now mapped to a continuum of sites throughout the genome. Replication of the 2 micron plasmid in a topoisomerase II- but not a topoisomerase I-deficient yeast gave rise to very similar structures. The data suggest that inactivation of topoisomerase I or II either stimulates recombination or, by differentially affecting replication fork progression, leads to aberrant replication termination.

A novel autonomously replicating sequence (ARS) for multiple integration in the yeast Hansenula polymorpha DL-1

Several autonomously replicating sequences of Hansenula polymorpha DL-1 (HARSs) with the characteristics of tandem integration were cloned by an enrichment procedure and analyzed for their functional elements to elucidate the mechanism of multiple integration in tandem repeats. All plasmids harboring newly cloned HARSs showed a high frequency of transformation and were maintained episomally before stabilization. After stabilization, the transforming DNA was stably integrated into the chromosome. HARS36 was selected for its high efficiency of transformation and tendency for integration. Several tandemly repeated copies of the transforming plasmid containing HARS36 (pCE36) integrated into the vicinity of the chromosomal end. Bal 31 digestion of the total DNA from the integrants followed by Southern blotting generated progressive shortening of the hybridization signal, indicating the telomeric localization of the transforming plasmids on the chromosome. The minimum region of HARS36 required for its HARS activity was analyzed by deletion analyses. Three important regions, A, B, and C, for episomal replication and integration were detected. Analysis of the DNA sequences of regions A and B required for the episomal replication revealed that region A contained several AT-rich sequences that showed sequence homology with the ARS core consensus sequence of Saccharomyces cerevisiae. Region B contained two directly repeated sequences which were predicted to form a bent DNA structure. Deletion of the AT-rich core in region A resulted in a complete loss of ARS activity, and deletion of the repeated sequences in region B greatly reduced the stability of the transforming plasmid and resulted in retarded cell growth. Region C was required for the facilitated chromosomal integration of transforming plasmids.

CTBP1/RBP1, a Saccharomyces cerevisiae protein which binds to T-rich single-stranded DNA containing the 11-bp core sequence of autonomously replicating sequence, is a poly(deoxypyrimidine)-binding protein

South-Western screening of a glutathione-S-transferase fusion protein library constructed from the yeast Saccharomyces cerevisiae genomic DNA lead to isolation of core T-rich-strand-binding protein (CTBP) clones that bound to single-stranded DNA containing the T-rich-strand of the 11-bp core sequence of autonomously replicating sequences. One of these clones, CTBP1, contains a portion of previously described RBP1 which is an RNA-binding and single-stranded DNA-binding protein of S. cerevisiae. GST-CTBP1 as well as the full-length fusion protein with RBP1 (GST-RBP1) bind exclusively to the T-rich strand of the core sequence with an apparent dissociation constant of 5 nM, but not to the A-rich strand or double strand of the same sequence. Mutations within the core which reduce the number of T or C residues decrease the affinity of this protein. In keeping with this, binding of GST-CTBP1 to the core sequence is efficiently completed by poly(dT), poly(dT-dC) or poly(dC), but not by poly(dA) or poly(dG) to significant extents. Among polyribonucleic acids, GST-CTBP1 binds to poly(U) and poly(I) with greatest affinity, whereas GST-RBP1 binds to RNA in a rather non-specific manner. In no cases was affinity for RNA greater than that for DNA. Our results indicate that CTBP1/RBP1 is a polydeoxypyrimidine-binding protein of S. cerevisiae. CTBP1 contains two sets of an RNA-recognition motif (RRM) and a glutamine stretch. The binding affinity of the N-terminal or C-terminal set containing one RRM and one glutamine stretch is nearly two orders of magnitude lower than that of the wild-type CTBP1 containing both sets. The isolated N-terminal or C-terminal RRM alone (RRM1 and RRM2, respectively) is sufficient for binding nucleic acids with the binding specificity similar to that of the wild-type RRM, although the binding affinity of the isolated RRM2 is nearly two orders of magnitude lower than that of RRM1. Our results indicate that the two RRMs present in CTBP1/RBP1 have differential binding affinities and that the high affinity of RRM for polydeoxypyrimidine results from synergy between two lower-affinity RRMs.

Origins of replication and the nuclear matrix: the DHFR domain as a paradigm

The eukaryotic genome appears to be organized in a loopwise fashion by periodic attachment to the nuclear matrix. The proposal that a chromatin loop corresponds to a functional domain has stirred interest in the properties of the DNA sequences at the bases of these loops, the matrix-attached regions (MARs). Evidence has been presented suggesting that certain MARs act as boundary elements isolating domains from their chromosomal context. MARs have also been found in the vicinity of promoters and enhancers and they could act by displacing these cis-regulatory elements into the proper nuclear subcompartment. Attachment to the matrix might also play a role in DNA replication. A large body of evidence indicates that replication occurs on the nuclear matrix. This implies that any DNA sequence will be attached to the matrix at a certain time during the cell cycle. This transient mode of attachment contrasts with the proposed permanent attachment of origins of DNA replication with the nuclear matrix. While some data exist that support this suggestion, the current lack of understanding of the mammalian replication origin precludes definitive conclusions regarding the role of MARs in the initiation process.

Features of the DNA fingerprinting probe pITZ1

Stringently controlled plasmids generate DNA fingerprint patterns in mammals when used at low hybridization temperatures. In order to develop a probe for use in paternity testing in cattle we screened a bovine, partial genomic plasmid library with the PCR-amplified ori region of plasmid P1. Of eight isolated clones one generated strong band patterns at high stringency in various mammalian species (data not shown). Sequence analysis revealed an imperfect, compound dinucleotide repeat region, which was PCR-amplified and cloned into the plasmid vector pUC19. Fingerprint results generated by this probe (termed pITZ1) in cattle are compared with the results generated by VNTR-probe pV47, which itself was developed by screening a human chromosome 16 library with tandem repeats of bacteriophage M13. Probe pITZ1 is useful in conjunction with other VNTR-probes for DNA fingerprinting in cattle and donkey populations. The dinucleotide repeat region responsible for the band patterns generated with pITZ1 is close to an Alu-like sequence, which may be involved in eukaryotic replication mechanisms.

Two steps in the assembly of complexes at yeast replication origins in vivo

The integration of chromosomal DNA replication into the eukaryotic cell cycle might involve temporal regulation of interactions between cellular factors and replication origins. We show here that yeast replication origins exist in two chromatin states during the cell cycle. In the postreplicative state, genomic footprints closely resemble those produced in vitro by the purified ORC and ABF1 proteins, indicating that the binding of these proteins to replication origins is not sufficient to drive the initiation of DNA replication. The prereplicative state is characterized by an additional region of protection overlapping the ORC footprint. This prereplicative complex appears near the end of mitosis and persists through G1. After entry into S phase, origins return to the postreplicative state. Similarities in temporal regulation of the prereplicative state and the Xenopus licensing factor suggest that mechanisms limiting DNA replication to once per cell cycle may be conserved among eukaryotes.

Replicative intermediates of human papillomavirus type 11 in laryngeal papillomas: site of replication initiation and direction of replication

We have examined the structures of replication intermediates from the human papillomavirus type 11 genome in DNA extracted from papilloma lesions (laryngeal papillomas). The sites of replication initiation and termination utilized in vivo were mapped by using neutral/neutral and neutral/alkaline two-dimensional agarose gel electrophoresis methods. Initiation of replication was detected in or very close to the upstream regulatory region (URR; the noncoding, regulatory sequences upstream of the open reading frames in the papillomavirus genome). We also show that replication forks proceed bidirectionally from the origin and converge 180 degrees opposite the URR. These results demonstrate the feasibility of analysis of replication of viral genomes directly from infected tissue.

Specific initiation at an origin of replication from Schizosaccharomyces pombe

Using a genetic assay for efficient autonomous replication, we have isolated from Schizosaccharomyces pombe a 6.2-kb fragment which shows the properties expected of an origin of DNA replication in S. pombe. A 2.8-kb subclone of the fragment has the same replication properties. Two-dimensional gel analysis of replication intermediates throughout plasmids carrying the 6.2- or 2.8-kb fragments shows that replication initiates only in a specific region, which can be localized to within several hundred base pairs, in the fragments. This region is also a site of replication initiation in the S. pombe chromosome where the fragments normally reside. These results provide strong evidence that initiation of replication in S. pombe is localized and mediated by specific DNA sequence signals.

Specific initiation at an origin of replication from Schizosaccharomyces pombe

Using a genetic assay for efficient autonomous replication, we have isolated from Schizosaccharomyces pombe a 6.2-kb fragment which shows the properties expected of an origin of DNA replication in S. pombe. A 2.8-kb subclone of the fragment has the same replication properties. Two-dimensional gel analysis of replication intermediates throughout plasmids carrying the 6.2- or 2.8-kb fragments shows that replication initiates only in a specific region, which can be localized to within several hundred base pairs, in the fragments. This region is also a site of replication initiation in the S. pombe chromosome where the fragments normally reside. These results provide strong evidence that initiation of replication in S. pombe is localized and mediated by specific DNA sequence signals.

Analysis of an origin of DNA amplification in Sciara coprophila by a novel three-dimensional gel method

The replication origin region for DNA amplification in Sciara coprophila DNA puff II/9A was analyzed with a novel three-dimensional (3D) gel method. Our 3D gel method involves running a neutral/neutral 2D gel and then cutting out vertical gel slices from the area containing replication intermediates, rotating these slices 90 degrees to form the third dimension, and running an alkaline gel for each of the slices. Therefore, replication intermediates are separated into forks and bubbles and then are resolved into parental and nascent strands. We used this technique to determine the size of forks and bubbles and to confirm the location of the major initiation region previously mapped by 2D gels to a 1-kb region. Furthermore, our 3D gel analyses suggest that only one initiation event in the origin region occurs on a single DNA molecule and that the fork arc in the composite fork-plus-bubble pattern in neutral/neutral 2D gels does not result from broken bubbles.

Analysis of an origin of DNA amplification in Sciara coprophila by a novel three-dimensional gel method

The replication origin region for DNA amplification in Sciara coprophila DNA puff II/9A was analyzed with a novel three-dimensional (3D) gel method. Our 3D gel method involves running a neutral/neutral 2D gel and then cutting out vertical gel slices from the area containing replication intermediates, rotating these slices 90 degrees to form the third dimension, and running an alkaline gel for each of the slices. Therefore, replication intermediates are separated into forks and bubbles and then are resolved into parental and nascent strands. We used this technique to determine the size of forks and bubbles and to confirm the location of the major initiation region previously mapped by 2D gels to a 1-kb region. Furthermore, our 3D gel analyses suggest that only one initiation event in the origin region occurs on a single DNA molecule and that the fork arc in the composite fork-plus-bubble pattern in neutral/neutral 2D gels does not result from broken bubbles.

Searching for replication origins in mammalian DNA

The attempts at identifying precise replication origins (ori) in mammalian DNA have been pursued mainly through physico-chemical and biochemical approaches, in view of the essential failure of the search for autonomously replicating sequences in cultured cells. These approaches involve the mapping of short stretches of nascent DNA, the identification of the regions where either leading or lagging strands switch polarity, or the localization of replication intermediates by two-dimensional gel electrophoresis. Due to the complexity of animal cell genomes, most of these studies have been performed on amplified domains and with the use of synchronization procedures. The results obtained have been controversial. In order to avoid the use of experimental procedures potentially affecting the physiological mechanism of DNA replication, we have developed a method for the localization of ori in single-copy loci in exponentially growing cells. This method entails the absolute quantification of the abundance of selected DNA fragments along a genomic region within samples of newly synthesized DNA by competitive polymerase chain reaction (PCR); the latter is immune to all the uncontrollable variables which severely affect the reproducibility of conventional PCR. The application of this method to SV40 ori-driven plasmid replication precisely identifies the known ori localization. Using the same approach, we have mapped an ori for bi-directional DNA replication in a 13.7-kb locus of human chromosome 19 encoding lamin B2.

Isolation and cloning of putative mouse DNA replication initiation sites: binding to nuclear protein factors

By using an original two-step technique (trioxsalen crosslinking/immunoprecipitation) we were able to isolate in a single-stranded form a fraction of mouse DNA enriched in putative Replication Initiation Sequences (RIS). The isolated and purified single-strand fragments were made double-stranded in vitro and were cloned in pUC12 to prepare a confined RIS library. 30 randomly selected RIS inserts were subjected to gel mobility shift assay using nuclear extracts either from dividing, or from quiescent mouse cells. Twelve out of the 30 RIS fragments showed specific binding to proteins present in nuclear extract from dividing cells, while none were retarded by extracts from quiescent cells. RIS12, RIS18 and RIS30 were sequenced and it was found that they were A+T rich and contained different regulatory elements. By using a two step procedure (Heparin-sepharose chromatography/DNA affinity chromatography) we isolated the protein factor that specifically binds to RIS12. It appeared as a double band with apparent molecular masses of 63 and 65 kD.

DNase-sensitive chromatin structure near a chromosomal origin of bidirectional replication of the avian alpha-globin locus

We used an in vitro nuclear run-off replication assay to analyze the direction of replication in a 13-kb region 5' to the avian alpha-globin genes. Previous work from this laboratory suggested that the alpha-globin genes of 5-day chick red blood cells and avian MSB cells replicate in vivo in the transcriptional direction, possibly from a chromosomal origin near the alpha pi-globin gene. Here we extend those studies by showing that replication forks move divergently from an 8-kb region of alpha-globin 5'-flanking DNA. One potential zone for the initiation of bidirectional replication was located approximately 2.5 kb 5' to the alpha pi-globin gene in both of these cell types. Additionally, a barrier to replication fork movement, which may be located in a second origin zone, was found approximately 5 kb farther upstream. Both in 5-day RBCs, where the alpha-globin genes are expressed, and in MSB cells where they are not expressed, DNase I hypersensitive structures were found approximately 5 kb 5' to the alpha pi-globin gene, in the putative replication initiation domain. Another DNase I hypersensitive site was confirmed to exist in 5-day RBC nuclei upstream of the transcribed alpha pi-globin gene. These results suggest that replication of the alpha-globin genes initiates in the nearby 5'-flanking DNA of this locus in a region marked by distinct chromatin structures.

Elements in the immunoglobulin heavy-chain enhancer directly regulate simian virus 40 ori-dependent DNA replication

In a previous study, we showed that the immunoglobulin heavy-chain (IgH) enhancer (IgHe) is near or in an initiation zone of chromosomal DNA replication, which is preferentially active in B cells (K. Ariizumi, Z. Wang, and P. W. Tucker, Proc. Natl. Acad. Sci. USA 90:3695-3699, 1993). This suggests the existence of a functional relationship between IgHe-mediated transcription and DNA replication. To test this theory, we utilized simian virus 40 (SV40) DNA replication as a model of chromosomal replication. IgHe or its operationally divisible domains (5'-En, core, and 3'-En) were introduced into SV40 minichromosomes (IgHe-SV40). Results of replication assays with IgHe-SV40 replicons indicated that the 5'-En and 3'-En activated or suppressed SV40 DNA replication regardless of the presence of SV40 enhancers or promoters in these replicons. The activity did not reside in IgHe core sequences. The results suggested that the 5'- and 3'-En regulated SV40 replication through direct interaction with the origin, not through suppression at the SV40 enhancer and/or promoter. In an effort to identify elements within the 5'-En motif that contributed to this effect, we found that the E site, but not microE5 and microE2 boxes, upregulated DNA replication. Our results provide another possible regulatory function for the 5'-En and 3'-En domains besides transcriptional suppression of IgHe.

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.

Elements in the immunoglobulin heavy-chain enhancer directly regulate simian virus 40 ori-dependent DNA replication

In a previous study, we showed that the immunoglobulin heavy-chain (IgH) enhancer (IgHe) is near or in an initiation zone of chromosomal DNA replication, which is preferentially active in B cells (K. Ariizumi, Z. Wang, and P. W. Tucker, Proc. Natl. Acad. Sci. USA 90:3695-3699, 1993). This suggests the existence of a functional relationship between IgHe-mediated transcription and DNA replication. To test this theory, we utilized simian virus 40 (SV40) DNA replication as a model of chromosomal replication. IgHe or its operationally divisible domains (5'-En, core, and 3'-En) were introduced into SV40 minichromosomes (IgHe-SV40). Results of replication assays with IgHe-SV40 replicons indicated that the 5'-En and 3'-En activated or suppressed SV40 DNA replication regardless of the presence of SV40 enhancers or promoters in these replicons. The activity did not reside in IgHe core sequences. The results suggested that the 5'- and 3'-En regulated SV40 replication through direct interaction with the origin, not through suppression at the SV40 enhancer and/or promoter. In an effort to identify elements within the 5'-En motif that contributed to this effect, we found that the E site, but not microE5 and microE2 boxes, upregulated DNA replication. Our results provide another possible regulatory function for the 5'-En and 3'-En domains besides transcriptional suppression of IgHe.

Location and characterization of autonomously replicating sequences from chromosome VI of Saccharomyces cerevisiae

We have reported the isolation of linking clones of HindIII and EcoRI fragments, altogether spanning a 230-kb continuous stretch of chromosome VI. The presence or absence of autonomously replicating sequence (ARS) activities in all of these fragments has been determined by using ARS searching vectors containing CEN4. Nine ARS fragments were identified, and their positions were mapped on the chromosome. Structures essential for and/or stimulative to ARS activity were determined for the ARS fragments by deletions and mutations. The organization of functional elements composed of core and stimulative sequences was found to be variable. Single core sequences were identified in eight of nine ARSs. The remaining ARS (ARS603) essential element is composed of two core-like sequences. The lengths of 3'- and 5'-flanking stimulative sequences required for the full activity of ARSs varied from ARS to ARS. Five ARSs required more than 100 bp of the 3'-flanking sequence as stimulative sequences, while not more than 79 bp of the 3' sequence was required by the other three ARSs. In addition, five ARSs had stimulative sequences varying from 127 to 312 bp in the 5'-flanking region of the core sequence. In general, these stimulative activities were correlated with low local delta Gs of unwinding, suggesting that the low local delta G of an ARS is an important element for determining the efficiency of initiation of replication of ARS plasmids.

Location and characterization of autonomously replicating sequences from chromosome VI of Saccharomyces cerevisiae

We have reported the isolation of linking clones of HindIII and EcoRI fragments, altogether spanning a 230-kb continuous stretch of chromosome VI. The presence or absence of autonomously replicating sequence (ARS) activities in all of these fragments has been determined by using ARS searching vectors containing CEN4. Nine ARS fragments were identified, and their positions were mapped on the chromosome. Structures essential for and/or stimulative to ARS activity were determined for the ARS fragments by deletions and mutations. The organization of functional elements composed of core and stimulative sequences was found to be variable. Single core sequences were identified in eight of nine ARSs. The remaining ARS (ARS603) essential element is composed of two core-like sequences. The lengths of 3'- and 5'-flanking stimulative sequences required for the full activity of ARSs varied from ARS to ARS. Five ARSs required more than 100 bp of the 3'-flanking sequence as stimulative sequences, while not more than 79 bp of the 3' sequence was required by the other three ARSs. In addition, five ARSs had stimulative sequences varying from 127 to 312 bp in the 5'-flanking region of the core sequence. In general, these stimulative activities were correlated with low local delta Gs of unwinding, suggesting that the low local delta G of an ARS is an important element for determining the efficiency of initiation of replication of ARS plasmids.

DNA replication of histone gene repeats in Drosophila melanogaster tissue culture cells: multiple initiation sites and replication pause sites

We showed previously that DNA replication initiates at multiple sites in the 5-kb histone gene repeating unit in early embryos of Drosophila melanogaster. The present report shows evidence that replication in the same chromosomal region initiates at multiple sites in tissue culture cells as well. First, we analyzed replication intermediates by the two-dimensional gel electrophoretic replicon mapping method and detected bubble-form replication intermediates for all fragments restricted at different sites in the repeating unit. Second, we analyzed bromodeoxyuridine-labeled nascent strands amplified by the polymerase chain reaction method and detected little differences in the size distribution of nascent strands specific to six short segments located at different sites in the repeating unit. These results strongly suggest that DNA replication initiates at multiple sites located within the repeating unit. We also found several replication pause sites located at 5' upstream regions of some histone genes.

DNA replication of histone gene repeats in Drosophila melanogaster tissue culture cells: multiple initiation sites and replication pause sites

We showed previously that DNA replication initiates at multiple sites in the 5-kb histone gene repeating unit in early embryos of Drosophila melanogaster. The present report shows evidence that replication in the same chromosomal region initiates at multiple sites in tissue culture cells as well. First, we analyzed replication intermediates by the two-dimensional gel electrophoretic replicon mapping method and detected bubble-form replication intermediates for all fragments restricted at different sites in the repeating unit. Second, we analyzed bromodeoxyuridine-labeled nascent strands amplified by the polymerase chain reaction method and detected little differences in the size distribution of nascent strands specific to six short segments located at different sites in the repeating unit. These results strongly suggest that DNA replication initiates at multiple sites located within the repeating unit. We also found several replication pause sites located at 5' upstream regions of some histone genes.

TA-repeat microsatellites are closely associated with ARS consensus sequences in yeast chromosome III

Microsatellites are repeats of very short sequences of DNA, interspersed in the genome. In this paper, the occurrence of the two-base repeat microsatellites has been investigated in the DNA sequence of yeast chromosome III. Only AT-repeats were found at a significantly high frequency. Some of the regions with the highest concentration of AT-repeats were located and further analysed, showing a close association with the core consensus of autonomously replicating sequences.

Model system for DNA replication of a plasmid DNA containing the autonomously replicating sequence from Saccharomyces cerevisiae

A negatively supercoiled plasmid DNA containing autonomously replicating sequence (ARS) 1 from Saccharomyces cerevisiae was replicated with the proteins required for simian virus 40 DNA replication. The proteins included simian virus 40 large tumor antigen as a DNA helicase, DNA polymerase alpha.primase, and the multisubunit human single-stranded DNA-binding protein from HeLa cells; DNA gyrase from Escherichia coli, which relaxes positive but not negative supercoils, was included as a "swivelase." DNA replication started from the ARS region, proceeded bidirectionally with the synthesis of leading and lagging strands, and resulted in the synthesis of up to 10% of the input DNA in 1 h. The addition of HeLa DNA topoisomerase I, which relaxes both positive and negative supercoils, to this system inhibited DNA replication, suggesting that negative supercoiling of the template DNA is required for initiation. These results suggest that DNA replication starts from the ARS region where the DNA duplex is unwound by torsional stress; this unwound region can be recognized by a DNA helicase with the assistance of the multisubunit human single-stranded DNA-binding protein.

Replication initiates at a confined region during DNA amplification in Sciara DNA puff II/9A

Two independent two-dimensional (2D) gel methods were used to map an origin of replication that is developmentally regulated by the steroid hormone ecdysone, namely an origin for DNA puff amplification in the fungus fly Sciara coprophila. Initiation of replication was found to occur within a small region of no larger than 6 kb by use of the neutral/neutral 2D gel method. Neutral/alkaline 2D gel analyses support the results of the neutral/neutral 2D gels and further define within the origin region an approximately 1-kb area where the majority of replication initiates. This is the first example of an origin of replication in multicellular eukaryotes that has been mapped by 2D gels to such a small defined region. Moreover, replication can be seen by the neutral/alkaline 2D gel method to proceed bidirectionally outward from this replication origin region. These data are consistent with an onion-skin mechanism whereby multiple rounds of DNA replication initiate at a specific origin of replication for Sciara DNA puff amplification.

Suppression of tyrosinase gene expression by bromodeoxyuridine in Syrian hamster melanoma cells is not due to its incorporation into upstream or coding sequences of the tyrosinase gene

5-Bromodeoxyuridine (BrdU), a thymidine analog, suppresses melanogenesis in Syrian hamster melanoma cells. Tyrosinase, which is the key enzyme for the synthesis of melanin, is suppressed by exposure to BrdU, and the drop in enzyme activity is correlated with a drop in tyrosinase mRNA level. In order to investigate whether suppression of tyrosinase mRNA by BrdU is due to BrdU substitution into coding sequences or upstream sequences of the tyrosinase gene, we carried out stable and transient transfection assays with constructs containing either the human tyrosinase cDNA sequence under the control of a nontyrosinase promoter or a chloramphenicol acetyltransferase (CAT) reporter gene under the control of 5' flanking sequences of the mouse tyrosinase gene. When the plasmid containing the tyrosinase cDNA was stably transfected into mouse fibroblasts, tyrosinase activity in the transfectants was not suppressed by BrdU. Since BrdU would be incorporated into the tyrosinase cDNA integrated in these transfectants, the results suggest that BrdU suppression of tyrosinase gene expression is not due to its incorporation into coding sequences of the tyrosinase gene. When plasmids with tyrosinase regulatory sequences were transfected into melanoma cells for transient expression assays, CAT gene expression was suppressed by BrdU. Because the CAT plasmids do not contain a mammalian origin of replication and should not replicate under the conditions of transient transfection, BrdU would not be incorporated into the DNA of those plasmids. Therefore, these results suggest that the suppression of tyrosinase gene expression by BrdU also is not due to the incorporation of BrdU into upstream sequences of the tyrosinase gene.

Immunoglobulin heavy chain enhancer is located near or in an initiation zone of chromosomal DNA replication

In several animal viruses, enhancers have been implicated in both DNA replication and transcriptional activation. The linkage of the two mechanisms appears intimate, in that common DNA binding factors can be shared. The immunoglobulin heavy chain (Igh) intronic [heavy chain joining region (JH)-mu chain constant region (C mu)] enhancer (E mu) is required for tissue-specific transcription of Igh genes and is essential for somatic recombination of diversity (D) and J segments. We show here that E mu is located at or near an origin of chromosomal DNA replication, which is more active in B lymphocytes than fibroblasts. E mu does not fulfill two criteria demonstrated for some cellular origins. E mu can initiate but not maintain autonomous replicating activity in B cells. E mu is unable to impart early replication timing to a transfected VDJ-C mu Igh locus in B cells. Instead we propose that E mu-associated ori activity contributes to tissue-specific Igh expression through local effects on chromatin structure leading to subsequent accessibility of transcription and/or recombination factors for the enhancer.

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.

Two alleles of a developmentally regulated alpha-tubulin locus in Physarum polycephalum replicate on different schedules

The replication timing of a pair of natural alleles was compared at two alpha-tubulin loci of the Physarum plasmodium. Taking advantage of the naturally synchronous cell cycle of nuclei within the syncytial plasmodium, we analyzed the replication schedule of specific DNA fragments to a resolution of 10-min intervals within a 3-h S phase. At this level of resolution, differences in replication timing between polymorphic alleles at the same locus can be detected in a heterozygote. Specifically, the 3' region of the altA1 allele completes replication at between 20 and 40 min of S phase. The same region of the altA2 allele completes replication at between 40 and 80 min of S phase. In contrast, both alleles at the altB locus replicate concurrently within the first 10 to 15 min of S phase. Previous studies showed that both altA and altB are expressed in the plasmodium, their message levels peaking at mitosis, just minutes before the onset of S phase. However, altB message is detected at substantially higher levels than altA message on Northern (RNA) blots. The temporal windows over which the altA alleles each replicate are very broad in comparison with the levels of mitotic synchrony and altB replication synchrony in a single plasmodium. The allele-specific replication schedule of the altA locus demonstrates that the temporal organization of replicons is not strictly conserved between homologous chromosomes.

Two alleles of a developmentally regulated alpha-tubulin locus in Physarum polycephalum replicate on different schedules

The replication timing of a pair of natural alleles was compared at two alpha-tubulin loci of the Physarum plasmodium. Taking advantage of the naturally synchronous cell cycle of nuclei within the syncytial plasmodium, we analyzed the replication schedule of specific DNA fragments to a resolution of 10-min intervals within a 3-h S phase. At this level of resolution, differences in replication timing between polymorphic alleles at the same locus can be detected in a heterozygote. Specifically, the 3' region of the altA1 allele completes replication at between 20 and 40 min of S phase. The same region of the altA2 allele completes replication at between 40 and 80 min of S phase. In contrast, both alleles at the altB locus replicate concurrently within the first 10 to 15 min of S phase. Previous studies showed that both altA and altB are expressed in the plasmodium, their message levels peaking at mitosis, just minutes before the onset of S phase. However, altB message is detected at substantially higher levels than altA message on Northern (RNA) blots. The temporal windows over which the altA alleles each replicate are very broad in comparison with the levels of mitotic synchrony and altB replication synchrony in a single plasmodium. The allele-specific replication schedule of the altA locus demonstrates that the temporal organization of replicons is not strictly conserved between homologous chromosomes.

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.

Temporal order of DNA replication in the H-2 major histocompatibility complex of the mouse

As an approach to mapping replicons in an extended chromosomal region, the temporal order of DNA replication was analyzed in the murine major histocompatibility gene complex (MHC). Replicating DNA from T-lymphoma and myelomonocyte cell lines was density labeled with bromodeoxyuridine and extracted from cells which had been fractionated into different stages of S phase by centrifugal elutriation. The replicating DNA from each fraction of S phase was separated from nonreplicating DNA on density gradients, blotted, and hybridized with 34 specific MHC probes. The earliest replication occurred in the vicinity of transcribed genes K, HAM1 and HAM2, RD, B144, D, L, T18, and T3. The temporal order of replication of groups of DNA segments suggests the location of five or six replicons within the H-2 complex, some of which appear to be either unidirectional or markedly asymmetric. The rates of replication through each of these apparent replicons appear to be similar. The TL region of the S49.1 T-lymphoma cells, which contains at least three transcribed genes, replicates earlier than the inactive TL region of WEHI-3 myelomonocytic cells. These results provide further evidence of a relationship between transcription and the initiation of DNA replication in mammalian cells. The mouse MHC examined in this study is the largest chromosomal region (> 2,000 kb) measured for timing of replication to date.

Temporal order of DNA replication in the H-2 major histocompatibility complex of the mouse

As an approach to mapping replicons in an extended chromosomal region, the temporal order of DNA replication was analyzed in the murine major histocompatibility gene complex (MHC). Replicating DNA from T-lymphoma and myelomonocyte cell lines was density labeled with bromodeoxyuridine and extracted from cells which had been fractionated into different stages of S phase by centrifugal elutriation. The replicating DNA from each fraction of S phase was separated from nonreplicating DNA on density gradients, blotted, and hybridized with 34 specific MHC probes. The earliest replication occurred in the vicinity of transcribed genes K, HAM1 and HAM2, RD, B144, D, L, T18, and T3. The temporal order of replication of groups of DNA segments suggests the location of five or six replicons within the H-2 complex, some of which appear to be either unidirectional or markedly asymmetric. The rates of replication through each of these apparent replicons appear to be similar. The TL region of the S49.1 T-lymphoma cells, which contains at least three transcribed genes, replicates earlier than the inactive TL region of WEHI-3 myelomonocytic cells. These results provide further evidence of a relationship between transcription and the initiation of DNA replication in mammalian cells. The mouse MHC examined in this study is the largest chromosomal region (> 2,000 kb) measured for timing of replication to date.

Organization of specific DNA sequence elements in the region of the replication origin and matrix attachment site in the chicken alpha-globin gene domain

The distribution of specific DNA sequence elements in a 2.9 kb HindIII fragment of chicken DNA containing the replication origin and the upstream matrix attachment site (MAR) of the alpha-globin gene domain was investigated. The fragment was shown to contain a CR1-type repetitive element and two stably bent DNA sequences. One of them colocalizes with the previously described MAR element and with the recognition site for a proliferating-cell-specific, DNA-binding protein. The melting pattern of a set of subfragments of the region proved to be non random. No correlation between the distribution of readily melting sequences and bent DNA was found. The possible importance of curved, low-melting and repetitive DNA sequences for the organization of the upstream boundary of the alpha-globin gene domain and the function of the replication origin is discussed.

Homeotic protein binding sites, origins of replication, and nuclear matrix anchorage sites share the ATTA and ATTTA motifs

Nuclear matrix organizes the mammalian chromatin into loops. This is achieved by binding of nuclear matrix proteins to characteristic DNA landmarks in introns as well as proximal and distal sites flanking the 5' and 3' ends of genes. Matrix anchorage sites (MARs), origins of replication (ORIs), and homeotic protein binding sites share common DNA sequence motifs. In particular, the ATTA and ATTTA motifs, which constitute the core elements recognized by the homeobox domain from species as divergent as flies and humans, are frequently occurring in the matrix attachment sites of several genes. The human apolipoprotein B 3' MAR and a stretch of the Chinese hamster DHFR gene intron and human HPRT gene intron shown to anchor these genes to the nuclear matrix are mosaics of ATTA and ATTTA motifs. Several origins of replication also share these elements. This observation suggests that homeotic proteins which control the expression level of many genes and pattern formation during development are components of the nuclear matrix. Thus, the nuclear matrix, known as the site of DNA replication, might sculpture the crossroads of the differential activation of origins during development and S-phase and the control of gene expression and pattern formation in embryogenesis.

Control of human papillomavirus type 11 origin of replication by the E2 family of transcription regulatory proteins

Replication of human papillomavirus type 11 (HPV-11) DNA requires the full-length viral E1 and E2 proteins (C.-M. Chiang, M. Ustav, A. Stenlund, T. F. Ho, T. R. Broker, and L. T. Chow, Proc. Natl. Acad. Sci. USA 89:5799-5803, 1992). Using transient transfection of subgenomic HPV DNA into hamster CHO and human 293 cells, we have localized an origin of replication (ori) to an 80-bp segment in the upstream regulatory region spanning nucleotide 1. It overlaps the E6 promoter region and contains a short A + T-rich segment and a sequence which is homologous to the binding site of the bovine papillomavirus type 1 (BPV-1) E1 protein in the BPV-1 ori. However, unlike the BPV-1 ori, for which half an E2-responsive sequence (E2-RS) or binding site suffices, an intact binding site is essential for the HPV-11 ori. Replication was more efficient when additional E2-RSs were present. The intact HPV-11 genome also replicated in both cell lines when supplied with E1 and E2 proteins. Expression vectors of transcription repressor proteins that lack the N-terminal domain essential for E2 transcriptional trans activation did not support replication in collaboration with the E1 expression vector. Rather, cotransfection with the repressor expression vectors inhibited ori replication by the E1 and E2 proteins. These results demonstrate the importance of the N-terminal domain of the E2 protein in DNA replication and indicate that the family of E2 proteins positively and negatively regulates both viral DNA replication and E6 promoter transcription.

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 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.

Organization, structure, and function of 95 kb of DNA spanning the murine T-cell receptor C alpha/C delta region

We have analyzed the organization, structure, and function of the murine T-cell receptor C alpha/C delta region. This region spans 94.6 kb of DNA and contains the C alpha and C delta genes, as well as the V delta 5, J delta 2, and 50 different J alpha gene segments. Within this sequence we have identified 15 new J alpha gene segments, 40 new 5' RNA splice signals, and 40 new DNA rearrangement signals for the J alpha gene segments. The murine C alpha/C delta sequence contains an exceptionally high level of coding sequence with over 5.7% of the total sequence found in the exons. This is much more than that found in the beta-globin locus and the HPRT locus. Using the sequence data obtained from the C alpha/C delta region, we have designed simple assays to test for J alpha gene segment transcription and to determine the level of polymorphism for simple repeat sequences among different inbred strains of mice using the polymerase chain reaction. Furthermore, comparisons of this 95 kb of sequence with the available sequence from homologous regions of other species have led to the identification of a highly conserved sequence that is present throughout vertebrates and in the mouse binds lymphocyte-specific nuclear proteins. Comparisons of a 10-kb region, which includes the C alpha gene in human and mouse, average 66% sequence similarity. These studies support the contention that large-scale DNA sequencing projects of homologous regions of mouse and human will provide powerful new tools for studying the biology and evolution of loci such as the T-cell receptor and for identifying and posing new questions about the functions of conserved sequences.

Plasmid replication in Xenopus eggs and egg extracts: a 2D gel electrophoretic analysis

We have examined the replication patterns of ribosomal DNA plasmids in vivo and in vitro using Xenopus eggs. Plasmids carrying different parts of the Xenopus ribosomal DNA sequence were allowed to replicate either in vitro in an egg extract or in vivo after microinjection into unfertilized eggs. The replication intermediates were analyzed by the 2D gel electrophoretic technique of Brewer and Fangman (1), using original or modified electrophoresis conditions. With standard electrophoresis conditions, the patterns obtained for restriction fragments larger than 5 kb were unreliable because of artefactually distorted Y arcs and unrecognizable bubble arcs. Interpretable patterns could nevertheless be obtained using suitably modified electrophoresis parameters. Under these conditions, replication was found to initiate and terminate at multiple, random locations on each plasmid both in vivo and in vitro. However, only one or very few of these potential initiation sites are used during the replication of an individual plasmid molecule. We discuss the possible artefacts and misinterpretations that can result when the 2D electrophoresis parameters are not adapted to the size of the fragment examined. We also discuss the relevance of the random replication mode to the mechanisms and the control of DNA replication in eukaryotes.