Replication initiates in a broad zone in the amplified CHO dihydrofolate reductase domain

We have used two complementary two-dimensional gel electrophoretic methods to localize replication inititation sites and to determine replication fork direction in the amplified 240 kb dihydrofolate reductase domain of the methotrexate-resistant CHO cell line CHOC 400. Surprisingly, our analysis indicates that replication begins at many sites in several restriction fragments distributed throughout a previously defined 28 kb initiation locus, including a fragment containing a matrix attachment region. Initiation sites were not detected in regions lying upstream or downstream of this locus. Our results suggest that initiation reactions in mammalian chromosomal origins may be more complex than in the origins of simple microorganisms.     

Two early replicated,developmentally controlled genes of Physarum display different patterns of DNA replication by two-dimensional agarose gel electrophoresis

The nature of replication origins in eukaryotic chromosomes has been examined in some detail only in yeast, Drosophila, and mammalian cells. We have used highly synchronous cultures of plasmodia of the myxomycete Physarum and two-dimensional agarose gel electrophoresis to examine replication of two developmentally controlled, early replicated genes over time in S-phase. A single, discrete origin of replication was found within 4.8 kb of the LAV1-5 gene, which encodes a homolog of profilin. In contrast, the LAV1-2 gene appears to be surrounded by several origins. Two origins were identified within a 15 kb chromosomal domain and appear to be inefficiently used. Replication forks collide at preferred sites within this domain. These terminating structures are long lived, persisting for at least 2 h of the 3 h S-phase. Analysis of restriction fragment length polymorphisms (RFLPs) within the LAV1-2 domain indicates that replication of alleles on different parental chromosomes is a highly coordinated process. Our studies of the these two early replicated, plasmodium-specific genes indicate that both a fixed, narrow origin region and a broader zone containing two closely spaced origins of DNA replication occur in Physarum.     

Multiple origins of replication in the dihydrofolate reductase amplicons of a methotrexate-resistant chinese hamster cell line.

We recently showed that replication initiates in the early S period at two closely spaced zones in the 240-kilobase (kb) dihydrofolate reductase (DHFR) amplicon of the methotrexate-resistant Chinese hamster ovary cell line CHOC 400. Both of these initiation loci (ori-beta and ori-gamma) have previously been cloned in a recombinant cosmid. In this study, we identified a third early-firing initiation locus (ori-alpha) in the much larger DHFR amplicon of the independently isolated methotrexate-resistant Chinese hamster cell line DC3F-A3/4K (A3/4K). We describe the molecular cloning of this newly identified locus and demonstrate by chromosomal walking that ori-alpha lies approximately 240 kb upstream from ori-beta. Using overlapping cosmid clones for more than 450 kb of DNA sequence from this region of the DHFR domain, we have monitored the replication pattern of the amplicons in synchronized A3/4K cells. These studies suggest that ori-alpha, ori-beta, and ori-gamma are the only early-firing initiation sites in this 450-kb sequence. In addition, we have been able to roughly localize the termini between ori-alpha and ori-beta and between ori-alpha and the next origin in the 5' direction. Thus, we have now isolated the equivalent of three early-firing replicons (including their origins) from a well-characterized chromosomal domain. With these tools, it should be possible to determine those properties that are shared by the origins and termini of different replicons and which are therefore likely to be functionally significant.     

Densely methylated DNA islands in mammalian chromosomal replication origins.

Densely methylated DNA sequence islands, designated DMIs, have been observed in two Chinese hamster cell chromosomal replication origins by using a PCR-based chemical method of detection. One of the origins, oriS14, is located within or adjacent to the coding sequence for ribosomal protein S14 on chromosome 2q, and the other, ori-beta, is approximately 17 kbp downstream of the dhfr (dihydrofolic acid reductase) locus on chromosome 2p. The DMI in oriS14 is 127 bp long, and the DMI in ori-beta is 516 bp long. Both DMIs are bilaterally methylated (i.e., all dCs are modified to 5-methyl dC) only in cells that are replicating their DNA. When cell growth and DNA replication are arrested, methylation of CpA, CpT, and CpC dinucleotides is lost and the sequence islands display only a subset of their originally methylated CpG dinucleotides. Several possible roles for DMI-mediated regulation of mammalian chromosomal origins are considered.     

An initiation zone of chromosomal DNA replication located upstream of the c-myc gene in proliferating HeLa cells.

Studies on origins of DNA replication in mammalian cells have long been hampered by a lack of methods sensitive enough for the localization of such origins in chromosomal DNA. We have employed a new method for mapping origins, based on polymerase chain reaction amplification of nascent strand segments, to examine replication initiated in vivo near the c-myc gene in human cells. Nascent DNA, pulse-labeled in unsynchronized HeLa cells, was size fractionated and purified by immunoprecipitation with anti-bromodeoxyuridine antibodies. Lengths of the nascent strands that allow polymerase chain reaction amplification were determined by hybridization to probes homologous to amplified segments and used to calculate the position of the origin. We found that DNA replication through the c-myc gene initiates in a zone centered approximately 1.5 kilobases upstream of exon I. Replication proceeds bidirectionally from the origin, as indicated by comparison of hybridization patterns for three amplified segments. The initiation zone includes segments of the c-myc locus previously reported to drive autonomous replication of plasmids in human cells.     

Enhanced flexibility and aphidicolin-induced DNA breaks near mammalian replication origins: implications for replicon mapping and chromosome fragility

Common fragile sites are chromosomal loci prone to breakage and rearrangement that can be induced by aphidicolin, an inhibitor of DNA polymerases. Within these loci, sites of preferential DNA breaks were proposed to correlate with peaks of enhanced DNA flexibility, the function of which remains elusive. Here we show that mammalian DNA replication origins are enriched in peaks of enhanced flexibility. This finding suggests that the search for these features may help in the mapping of replication origins, and we present evidence supporting this hypothesis. The association of peaks of flexibility with replication origins also suggests that some origins may associate with minor levels of fragility. As shown here, an increased sensitivity to aphidicolin was found near two mammalian DNA replication origins.     

Comparative analysis of the molecular mechanisms controlling the initiation of chromosomal DNA replication in yeast and in mammalian cells

In eukaryotes DNA replication takes place in the S phase of the cell cycle. It initiates from hundreds to thousands of replication origins in a coordinated manner, in order to efficiently duplicate the genome. The sequence of events leading to the onset of DNA replication is conventionally divided in two interdependent processes: licensing-a process during which replication origins acquire replication competence but are kept inactive- and firing-a process during which licensed origins are activated but not re-licensed. In this review we investigate the evolutionary conservation of the molecular machinery orchestrating DNA replication initiation both in yeast and in mammalian cells, highlighting a remarkable conservation of the general architecture of this central biological mechanism. Many steps are conserved down to molecular details and are performed by orthologous proteins with high sequence conservation, while differences in molecular structure of the performing proteins and their interactions are apparent in other steps. Tight regulation of initiation of DNA replication is achieved through protein phosphorylation, exerted mostly by Cyclin-dependent kinases in order to ensure that each chromosome is fully replicated once, and only once, during each cycle, and to avoid the formation of aberrant DNA structures and incorrect chromosomal duplication, that in mammalian cells are a prerequisite for genome instability and tumorigenesis. We then consider a molecular mathematical model of DNA replication, recently proposed by our group in a collaborative project, as a frame of reference to discuss similarities and differences observed in the regulatory program controlling DNA replication initiation in yeast and in mammalian cells and discuss whether they may be dependent upon different functional constraints. We conclude that a systems biology approach, integrating molecular analysis with modeling and computational investigations, is the best choice to investigate the control of DNA replication in mammalian cells.     

DNA replication joins the revolution: whole-genome views of DNA replication in budding yeast

Replication origins, which are responsible for initiating the replication of eukaryotic chromosomal DNAs, are spaced at intervals of 40 to 200 kb. Although the sets of proteins that assemble at replication origins during G(1) to form pre-replicative complexes are highly conserved, the structures of replication origins varies from organism to organism. The identification of replication origins has been a labor-intensive task, requiring the analysis of chromosomal DNA replication intermediates. As a result, only a few replication origins have been identified and studied. In a pair of recently published papers, Raghuraman and colleagues and Wyrick, Aparicio and colleagues provide complementary microarray-based approaches to the identification of replication origins. These genome-wide views of DNA replication in Saccharomyces cerevisiae provide new insights into the way that the genome is duplicated and hold promise for the analysis of other genomes.     

Dynamics of DNA replication in mammalian somatic cells: nucleotide pool modulates origin choice and interorigin spacing

Selection of active origins and regulation of interorigin spacing are poorly understood in mammalian cells. Using tricolor analysis of combed DNA molecules, we studied an amplified locus containing the known origin, oriGNAI3. We visualized replication firing events at this and other discrete regions and established a strict correlation between AT richness and initiation sites. We found that oriGNAI3 is the prominent origin of the domain, the firing of which correlates with silencing of neighboring sites and establishes large interorigin distances. We demonstrate that cells reversibly respond to a reduction in nucleotide availability by slowing the rate of replication fork progression; in addition, the efficiency of initiation at oriGNAI3 is lowered while other normally dormant origins in the region are activated, which results in an overall increase in the density of initiation events. Thus, nucleotide pools are involved in the specification of active origins, which in turn defines their density along chromosomes.     

Replication of the chicken beta-globin locus: early-firing origins at the 5' HS4 insulator and the rho- and betaA-globin genes show opposite epigenetic modifications

Chromatin structure is believed to exert a strong effect on replication origin function. We have studied the replication of the chicken beta-globin locus, whose chromatin structure has been extensively characterized. This locus is delimited by hypersensitive sites (HSs) that mark the position of insulator elements. A stretch of condensed chromatin and another HS separate the beta-globin domain from an adjacent folate receptor (FR) gene. We demonstrate here that in erythroid cells that express the FR but not the globin genes, replication initiates at four sites within the beta-globin domain, one at the 5' HS4 insulator and the other three near the rho- and beta(A)-globin genes. Three origins consist of G+C-rich sequences enriched in CpG dinucleotides. The fourth origin is A+T rich. Together with previous work, these data reveal that the insulator origin has unmethylated CpGs, hyperacetylated histones H3 and H4, and lysine 4-methylated histone H3. In contrast, opposite modifications are observed at the other G+C-rich origins. We also show that the whole region, including the stretch of condensed chromatin, replicates early in S phase in these cells. Therefore, different early-firing origins within the same locus may have opposite patterns of epigenetic modifications. The role of insulator elements in DNA replication is discussed.     

Regulation of DNA replication within the immunoglobulin heavy-chain locus during B cell commitment

The temporal order of replication of mammalian chromosomes appears to be linked to their functional organization, but the process that establishes and modifies this order during cell differentiation remains largely unknown. Here, we studied how the replication of the Igh locus initiates, progresses, and terminates in bone marrow pro-B cells undergoing B cell commitment. We show that many aspects of DNA replication can be quantitatively explained by a mechanism involving the stochastic firing of origins (across the S phase and the Igh locus) and extensive variations in their firing rate (along the locus). The firing rate of origins shows a high degree of coordination across Igh domains that span tens to hundreds of kilobases, a phenomenon not observed in simple eukaryotes. Differences in domain sizes and firing rates determine the temporal order of replication. During B cell commitment, the expression of the B-cell-specific factor Pax5 sharply alters the temporal order of replication by modifying the rate of origin firing within various Igh domains (particularly those containing Pax5 binding sites). We propose that, within the Igh C(H)-3'RR domain, Pax5 is responsible for both establishing and maintaining high rates of origin firing, mostly by controlling events downstream of the assembly of pre-replication complexes.     

Architecture of the yeast origin recognition complex bound to origins of DNA replication.

In many organisms, the replication of DNA requires the binding of a protein called the initiator to DNA sites referred to as origins of replication. Analyses of multiple initiator proteins bound to their cognate origins have provided important insights into the mechanism by which DNA replication is initiated. To extend this level of analysis to the study of eukaryotic chromosomal replication, we have investigated the architecture of the Saccharomyces cerevisiae origin recognition complex (ORC) bound to yeast origins of replication. Determination of DNA residues important for ORC-origin association indicated that ORC interacts preferentially with one strand of the ARS1 origin of replication. DNA binding assays using ORC complexes lacking one of the six subunits demonstrated that the DNA binding domain of ORC requires the coordinate action of five of the six ORC subunits. Protein-DNA cross-linking studies suggested that recognition of origin sequences is mediated primarily by two different groups of ORC subunits that make sequence-specific contacts with two distinct regions of the DNA. Implications of these findings for ORC function and the mechanism of initiation of eukaryotic DNA replication are discussed.     

Radiation effects on DNA synthesis in a defined chromosomal replicon.

It has recently been shown that the tumor suppressor p53 mediates a signal transduction pathway that responds to DNA damage by arresting cells in the late G1 period of the cell cycle. However, the operation of this pathway alone cannot explain the 50% reduction in the rate of DNA synthesis that occurs within 30 min of irradiation of an asynchronous cell population. We are using the amplified dihydrofolate reductase (DHFR) domain in the methotrexate-resistant CHO cell line, CHOC 400, as a model replicon in which to study this acute radiation effect. We first show that the CHOC 400 cell line retains the classical acute-phase response but does not display the late G1 arrest that characterizes the p53-mediated checkpoint. Using a two-dimensional gel replicon-mapping method, we then show that when asynchronous cultures are irradiated with 900 cGy, initiation in the DHFR locus is completely inhibited within 30 min and does not resume for 3 to 4 h. Since initiation in this locus occurs throughout the first 2 h of the S period, this result implies the existence of a p53-independent S-phase damage-sensing pathway that functions at the level of individual origins. Results obtained with the replication inhibitor mimosine define a position near the G1/S boundary beyond which cells are unable to prevent initiation at early-firing origins in response to irradiation. This is the first direct demonstration at a defined chromosomal origin that radiation quantitatively down-regulates initiation.     

A potential role for mini-chromosome maintenance (MCM) proteins in initiation at the dihydrofolate reductase replication origin.

Mini-chromosome maintenance (MCM) proteins were originally identified in yeast, and homologues have been identified in several other eukaryotic organisms, including mammals. These findings suggest that the mechanisms by which eukaryotic cells initiate and regulate DNA replication have been conserved throughout evolution. However, it is clear that many mammalian origins are much more complex than those of yeast. An example is the Chinese hamster dihydrofolate reductase (DHFR) origin, which resides in the spacer between the DHFR and 2BE2121 genes. This origin consists of a broad zone of potential sites scattered throughout the 55-kb spacer, with several subregions (e.g. ori-beta, ori-beta', and ori-gamma) being preferred. We show here that antibodies to human MCMs 2-7 recognize counterparts in extracts prepared from hamster cells; furthermore, co-immunoprecipitation data demonstrate the presence of an MCM2-3-5 subcomplex as observed in other species. To determine whether MCM proteins play a role in initiation and/or elongation in Chinese hamster cells, we have examined in vivo protein-DNA interactions between the MCMs and chromatin in the DHFR locus using a chromatin immunoprecipitation (ChIP) approach. In synchronized cultures, MCM complexes associate preferentially with DNA in the intergenic initiation zone early in S-phase during the time that replication initiates. However, significant amounts of MCMs were also detected over the two genes, in agreement with recent observations that the MCM complex co-purifies with RNA polymerase II. As cells progress through S-phase, the MCMs redistribute throughout the DHFR domain, suggesting a dynamic interaction with DNA. In asynchronous cultures, in which replication forks should be found at any position in the genome, MCM proteins were distributed relatively evenly throughout the DHFR locus. Altogether, these data are consistent with studies in yeast showing that MCM subunits localize to origins during initiation and then migrate outward with the replication forks. This constitutes the first evidence that mammalian MCM complexes perform a critical role during the initiation and elongation phases of replication at the DHFR origin in hamster cells.     

One-way PCR-based mapping of a replication initiation point (RIP)

The lamin B2 locus is the only mammalian origin whose replication initiation points (RIPs) have been mapped. Although this paper was published 8 years ago, no further mammalian RIP-mapping studies have been reported, largely due to technical difficulties of ligation-mediated (LM)-PCR used by the authors. Here, we report the development of a simple, one-way PCR-based protocol that allows one to accurately determine RIPs at mammalian origins. The procedure can be completed within 48 h from the time of cell lysis in the agarose gel. Nascent DNA is then isolated from the same gel after DNA is separated by alkaline gel electrophoresis. Subsequently, RIPs are determined by one-way PCR-based primer extension using labeled primers. Using this protocol, we have successfully mapped RIPs in the human DBF4 locus. As one-way PCR is routinely used by many scientists, this protocol will provide a powerful new tool for studying DNA replication in many organisms including mammalian cells.     

The plant amino acid mimosine may inhibit initiation at origins of replication in Chinese hamster cells.

An understanding of replication initiation in mammalian cells has been hampered by the lack of mutations and/or inhibitors that arrest cells just prior to entry into the S period. The plant amino acid mimosine has recently been suggested to inhibit cells at a regulatory step in late G1. We have examined the effects of mimosine on cell cycle traverse in the mimosine [corrected]-resistant CHO cell line CHOC 400. When administered to cultures for 14 h after reversal of a G0 block, the drug appears to arrest the population at the G1/S boundary, and upon its removal cells enter the S phase in a synchronous wave. However, when methotrexate is administered to an actively dividing asynchronous culture, cells are arrested not only at the G1/S interface but also in early and middle S phase. Most interestingly, two-dimensional gel analysis of replication intermediates in the initiation locus of the amplified dihydrofolate reductase domain suggests that mimosine may actually inhibit initiation. Thus, this drug represents a new class of inhibitors that may open a window on regulatory events occurring at individual origins of replication.     

Replication in the amplified dihydrofolate reductase domain in CHO cells may initiate at two distinct sites, one of which is a repetitive sequence element.

To study initiation of DNA replication in mammalian chromosomes, we have established a methotrexate-resistant Chinese hamster ovary cell line (CHOC 400) that contains approximately 1,000 copies of the early replicating dihydrofolate reductase (DHFR) domain. We have previously shown that DNA replication in the prevalent 243-kilobase (kb) amplicon type in this cell line initiates somewhere within a 28-kb region located downstream from the DHFR gene. In an attempt to localize the origin of replication with more precision, we blocked the progress of replication forks emanating from origins at the beginning of the S phase by the introduction of trioxsalen cross-links at 1- to 5-kb intervals in the parental double-stranded DNA. The small DNA fragments synthesized under these conditions (which should be centered around replication origins) were then used as hybridization probes on digests of cosmids and plasmids from the DHFR domain. These studies suggested that in cells synchronized by this regimen, DNA replication initiates at two separate sites within the previously defined 28-kb replication initiation locus, in general agreement with results described in the accompanying paper (T.-H. Leu and J. L. Hamlin, Mol. Cell. Biol. 9:523-531, 1989). One of these sites contains a repeated DNA sequence element that is found at or near many other initiation sites in the genome, since it was also highly enriched in the early replicating DNA isolated from cross-linked CHO cells that contain only two copies of the DHFR domain.     

Binding of AlF-C, an Orc1-binding transcriptional regulator, enhances replicator activity of the rat aldolase B origin

A region encompassing the rat aldolase B gene (aldB) promoter acts as a chromosomal origin of DNA replication (origin) in rat aldolase B-nonexpressing hepatoma cells. To examine replicator function of the aldB origin, we constructed recombinant mouse cell lines in which the rat aldB origin and the mutant derivatives were inserted into the same position at the mouse chromosome 8 by cre-mediated recombination. Nascent strand abundance assays revealed that the rat origin acts as a replicator at the ectopic mouse locus. Mutation of site C in the rat origin, which binds an Orc1-binding protein AlF-C in vitro, resulted in a significant reduction of the replicator activity in the mouse cells. Chromatin immunoprecipitation (ChIP) assays indicated that the reduction of replicator activity was paralleled with the reduced binding of AlF-C and Orc1, suggesting that sequence-specific binding of AlF-C to the ectopic rat origin leads to enhanced replicator activity in cooperation with Orc1. Involvement of AlF-C in replication in vivo was further examined for the aldB origin at its original rat locus and for a different rat origin identified in the present study, which contained an AlF-C-binding site. ChIP assays revealed that both replication origins bind AlF-C and Orc1. We think that the results presented here may represent one mode of origin recognition in mammalian cells.