Eukaryotic Replication Origins Research Articles

Identification of short 'eukaryotic' Okazaki fragments synthesized from a prokaryotic replication origin.

Although archaeal genomes encode proteins similar to eukaryotic replication factors, the hyperthermophilic archaeon Pyrococcus abyssi replicates its circular chromosome at a high rate from a single origin (oriC) as in Bacteria. In further elucidating the mechanism of archaeal DNA replication, we have studied the elongation step of DNA replication in vivo. We have detected, in two main archaeal phyla, short RNA-primed replication intermediates whose structure and length are very similar to those of eukaryotic Okazaki fragments. Mapping of replication initiation points further showed that discontinuous DNA replication in P. abyssi starts at a well-defined site within the oriC recently identified in this hyperthermophile. Short Okazaki fragments and a high replication speed imply a very efficient turnover of Okazaki fragments in Archaea. Archaea therefore have a unique replication system showing mechanistic similarities to both Bacteria and Eukarya.

Initiation of DNA Replication in Cells of Higher Eukaryotes

In this review, the problems concerning initiation of DNA replication in higher eukaryotes are discussed, with special emphasis on the methods of replication origin mapping and biological tests for the activity of DNA replication origins in higher eukaryotes. Protein factors interacting with replication origins are considered in detail. The main events of replication initiation in higher eukaryotes are briefly analyzed. New data on the control of replication timing of large genomic regions are discussed.

14-3-3s are DNA-replication proteins.

14-3-3 proteins are conserved multifunctional molecules, involved in many biological processes. Several 14-3-3 isoforms were recently shown to be cruciform DNA-binding proteins, which is a new activity ascribed to the 14-3-3 family. As cruciform-binding proteins, 14-3-3 proteins are putatively involved in the regulation of DNA replication. Inverted repeat sequences that are able to extrude into cruciform structures are a common feature of replication origins in both prokaryotes and eukaryotes. The involvement of cruciform structures in the initiation of DNA replication has been demonstrated. A leading model of 14-3-3 function proposes that they facilitate critical protein-protein interactions, thus serving as a central component of a wide variety of cellular processes.

Where it all starts: eukaryotic origins of DNA replication.

Chromosomal origins of DNA replication in eukaryotic cells not only are crucial for understanding the basic process of DNA duplication but also provide a tool to analyze how cell cycle regulators are linked to the replication machinery. During the past decade much progress has been made in identifying replication origins in eukaryotic genomes. More recently, replication initiation point (RIP) mapping has allowed us to detect start sites for DNA synthesis at the nucleotide level and thus to monitor replication initiation events at the origin very precisely. Beyond giving us the precise positions of start sites, the application of RIP mapping in yeast and human cells has revealed a single, defined start point at which replication initiates, a scenario very reminiscent of transcription initiation. More importantly, studies in yeast have shown that the binding site for the initiator, the origin recognition complex (ORC), lies immediately adjacent to the replication start point, which suggests that ORC directs the initiation machinery to a distinct site. Therefore, in our pursuit of identifying ORC-binding sites in higher eukaryotes, RIP mapping may lead the way.

Repression of origin assembly in metaphase depends on inhibition of RLF-B/Cdt1 by geminin.

Eukaryotic replication origins are 'licensed' for replication early in the cell cycle by loading Mcm(2-7) proteins. As chromatin replicates, Mcm(2-7) are removed, thus preventing the origin from firing again. Here we report the purification of the RLF-B component of the licensing system and show that it corresponds to Cdt1. RLF-B/Cdt1 was inhibited by geminin, a protein that is degraded during late mitosis. Immunodepletion of geminin from metaphase extracts allowed them to assemble licensed replication origins. Inhibition of CDKs in metaphase stimulated origin assembly only after the depletion of geminin. These experiments suggest that geminin-mediated inhibition of RLF-B/Cdt1 is essential for repressing origin assembly late in the cell cycle of higher eukaryotes.

Multiple sites of replication initiation in the human beta-globin gene locus.

The cell cycle-dependent, ordered assembly of protein prereplicative complexes suggests that eukaryotic replication origins determine when genomic replication initiates. By comparison, the factors that determine where replication initiates relative to the sites of prereplicative complex formation are not known. In the human globin gene locus previous work showed that replication initiates at a single site 5' to the ss-globin gene when protein synthesis is inhibited by emetine. The present study has examined the pattern of initiation around the genetically defined ss-globin replicator in logarithmically growing HeLa cells, using two PCR-based nascent strand assays. In contrast to the pattern of initiation detected in emetine-treated cells, analysis of the short nascent strands at five positions spanning a 40 kb globin gene region shows that replication initiates at more than one site in non-drug-treated cells. Quantitation of nascent DNA chains confirmed that replication begins at several locations in this domain, including one near the initiation region (IR) identified in emetine-treated cells. However, the abundance of short nascent strands at another initiation site approximately 20 kb upstream is approximately 4-fold as great as that at the IR. The latter site abuts an early S phase replicating fragment previously defined at low resolution in logarithmically dividing cells.

Evidence for class-specific factors in immunoglobulin isotype switching.

Immunoglobulin class switch recombination (SR) occurs by a B cell-specific, intrachromosomal deletional process between switch regions. We have developed a plasmid-based transient transfection assay for SR to test for the presence of transacting switch activities. The plasmids are novel in that they lack a eukaryotic origin of DNA replication. The recombination activity of these switch substrates is restricted to a subset of B cell lines that support isotype switching on their endogenous loci and to mitogen-activated normal splenic B cells. The factors required for extrachromosomal plasmid recombination are constitutively expressed in proliferating splenic B cells and in B cell lines capable of inducibly undergoing immunoglobulin SR on their chromosomal genes. These studies suggest that mitogens that induce switching on the chromosome induce accessibility rather than switch recombinase activity. Finally, we provide evidence for two distinct switching activities which independently mediate mu-->alpha and mu-->gamma3 SR.

Dispersive Initiation of Replication in the Chinese Hamster Rhodopsin Locus

Several higher eukaryotic replication origins appear to be composed of broad zones of potential nascent strand start sites, while others are more circumscribed, resembling those of yeast, bacteria, and viruses. The most delocalized origin identified so far is ∼55 kb in length and lies between the convergently transcribed dihydrofolate reductase (DHFR) and the 2BE2121 genes on chromosome 2 in the Chinese hamster genome. In some of our studies, we have utilized the rhodopsin origin as an early replicating internal standard for assessing the effects of deleting various parts of the DHFR locus on DHFR origin activity. However, it had not been previously established that the rhodopsin locus was located at a site far enough away to be immune to such deletions, nor had the mechanism of initiation at this origin been characterized. In the present study, we have localized the rhodopsin domain to a pair of small metacentric chromosomes and have used neutral/neutral 2-D gel replicon mapping to show that initiation in this origin is also highly delocalized, encompassing a region more than 50 kb in length that includes the nontranscribed rhodopsin gene itself. The initiation zone is flanked at least on one end by an actively transcribed gene that does not support initiation. Thus, the DHFR and rhodopsin origins belong to a class of complex, polydisperse origins that appears to be unique to higher eukaryotic cells.

Genetic Methods for Characterizing the cis-Acting Components of Yeast DNA Replication Origins

Small circular plasmids containing replication origins and, in some cases, centromeres, can replicate autonomously in the nuclei of all tested yeast species. Because this autonomous replication is dependent on the replication origin within the plasmid, measurements of the efficiency of autonomous replication (by the methods summarized here) permit evaluation of the effects of mutations on origin function. Although alternative methods are available for genetic characterization of replication origins in other organisms, the simplicity of the autonomous replication assay in yeasts has permitted development of the deepest understanding to date of eukaryotic replication origin structure. This information has come primarily from studies with Saccharomyces cerevisiae. However, there are many other yeast species, each with its own variety of replication origins. Use of the methods summarized here to characterize origins in other yeast species is likely to provide additional insights into eukaryotic replication origin structure.

Short DNA fragments without sequence similarity are initiation sites for replication in the chromosome of the yeast Yarrowia lipolytica.

We have previously shown that both a centromere (CEN) and a replication origin are necessary for plasmid maintenance in the yeast Yarrowia lipolytica (). Because of this requirement, only a small number of centromere-proximal replication origins have been isolated from Yarrowia. We used a CEN-based plasmid to obtain noncentromeric origins, and several new fragments, some unique and some repetitive sequences, were isolated. Some of them were analyzed by two-dimensional gel electrophoresis and correspond to actual sites of initiation (ORI) on the chromosome. We observed that a 125-bp fragment is sufficient for a functional ORI on plasmid, and that chromosomal origins moved to ectopic sites on the chromosome continue to act as initiation sites. These Yarrowia origins share an 8-bp motif, which is not essential for origin function on plasmids. The Yarrowia origins do not display any obvious common structural features, like bent DNA or DNA unwinding elements, generally present at or near eukaryotic replication origins. Y. lipolytica origins thus share features of those in the unicellular Saccharomyces cerevisiae and in multicellular eukaryotes: they are discrete and short genetic elements without sequence similarity.

Identification of a Compound Origin of Replication at theHMR-E Locus in Saccharomyces cerevisiae

Eukaryotic chromosomal origins of replication are best defined in Saccharomyces cerevisiae. Previous analysis of yeast origins suggests that they are relatively simple structures comprised of three or four small DNA sequence elements contained within approximately 100-200-base pair regions (Gilbert, D. M. (1998) Curr. Opin. Genet. Dev. 8, 194-199). In contrast, the sequence elements that may comprise origins in multicellular eukaryotes are largely unknown. The yeast HMR-E region is both a chromosomal origin of replication and a silencer that represses transcription of adjacent genes through a position effect. The analysis presented here indicated that HMR-E had a novel DNA structure that was more complex than defined for other yeast origins, and thus revealed that there is variation in the structural complexity of yeast origins. In contrast to "simple" yeast origins, the origin at HMR-E consisted of at least three independent subregions that had the capacity to initiate replication. We have termed HMR-E a compound origin to reflect its structural complexity. Furthermore, only one origin within the compound origin was a silencer.

Direct cloning and analysis of DNA sequences from a region of the Chinese hamster genome associated with aphidicolin-sensitive fragility.

Fragile sites are reproducibly expressed and chemically induced decondensations on mitotic chromosomes observed under cytological conditions. They are classified both on the basis of the frequency with which they occur (rare and common) and in terms of the chemical agent used to induce expression in tissue culture cells. Aphidicolin-sensitive common fragile sites appear to be ubiquitous in humans and other mammals and have been considered as candidates of pathological importance. Recently DNA from FRA3B, the most highly expressed constitutive fragile site in the human genome, has been cloned although as yet the cause of the underlying fragility has not been identified. In this study we describe the isolation, using a direct cloning approach, of DNA from a region of the Chinese hamster genome associated with aphidicolin-inducible fragility. Cells of a human-hamster somatic cell hybrid were transfected with a pSV2HPRT vector while exposed to aphidicolin, an inhibitor of DNA polymerases alpha, delta and epsilon. FISH analysis of stable transfectant clones revealed that the ingoing plasmid DNA had preferentially integrated into fragile site-containing chromosomal bands. Plasmid rescue was used to recover DNA sequences flanking one such integration site in the hamster genome. We demonstrate by FISH analysis of metaphase cells induced with aphidicolin that the rescued DNA is from a region of fragility on Chinese hamster chromosome 2, distal to the DHFR locus. Analysis of the DNA sequences flanking the integration site revealed the overall A+T content of the 3,725 bp region sequenced to be 63.3%, with a highly [A].[T]-rich 156 bp region (86.5%) almost adjacent to the integration site. Computational analyses have identified strong homologies to Saccharomyces cerevisiae autonomous replicating sequences (ARS), polypyrimidine tracts, scaffold attachment site consensus sequences and a 24 bp consensus sequence highly conserved in eukaryotic replication origins, all of which appear to cluster around the [A].[T]-rich sequences. This domain also possesses structural characteristics which are common to both prokaryotic and eukaryotic origins of replications, in particular an unusually straight conformation of low thermal stability flanked either side by highly bent DNA segments. Further isolation and characterisation of DNA sequences from common fragile sites will facilitate studies into the underlying nature of these enigmatic regions of the mammalian genome, leading to a greater understanding of chromatin structure.

Studies with artificial extrachromosomal elements in trypanosomatids: Could specificity in the initiation of DNA replication be linked to that in transcription?

Historically, artificial replicons have served as useful models for the definition of regulatory elements involved in chromosomal replication and transmission in yeast and DNA replication in bacteria. Here, Pradeep Patnaik examines what we have learnt so far from the replicative behaviour of various artificial extrachromosomal elements available for trypanosomatids. He highlights the involvement of transcription regulatory elements in virtually every eukaryotic origin of replication analysed in detail and, by drawing upon the extensive literature supporting a close association between DNA replication and transcription, he speculates that the nature and organization of origins of replication on a chromosome also may hold clues to the manner by which an organism regulates gene expression.

An Abf1p C-terminal region lacking transcriptional activation potential stimulates a yeast origin of replication.

Although it has been demonstrated that eukaryotic cellular origins of DNA replication may harbor stimulatory elements that bind transcription factors, how these factors stimulate origin function is unknown. In Saccharomyces cerevisiae , the transcription factor Abf1p stimulates origin function of ARS121 and ARS1 . In the results presented here, an analysis of Abf1p function has been carried out utilizing LexA(BD)-Abf1p fusion proteins and an ARS 121 derivative harboring LexA DNA-binding sites. A minimal region which stimulates origin function mapped to 50 amino acids within the C-terminus of Abf1p. When tested for transcriptional activation of a LacZ reporter gene, the same LexA(BD)-Abf1p fusion protein had negligible transcriptional activation potential. Therefore, stimulation of ARS 121 may occur independently of a transcriptional activation domain. It has been previously observed that the Gal4p, Rap1p DNA-binding sites and the LexA-Gal4p fusion protein can replace the role of Abf1p in stimulating ARS 1 . Here we show that the stimulatory function of Abf1p at ARS 121 cannot be replaced by these alternative DNA-binding sites and the potent chimeric transcriptional activator LexA(BD)-Gal4(AD)p . Hence, these results strongly suggest that the Abf1p stimulation of replication may differ for ARS 121 and ARS 1 , and imply specificity in the Abf1p/ARS 121 relationship.

Late gene expression from the Epstein-Barr virus BcLF1 and BFRF3 promoters does not require DNA replication in cis.

Late gene expression follows and is dependent upon lytic replication of the viral genome. Although experimental evidence is lacking, lytic viral DNA replication is believed to remove modifications or binding factors from the genome which serve to repress late gene expression during latency or the early lytic cycle. We have developed a reporter assay to begin characterizing the mechanisms that regulate late gene expression in Epstein-Barr virus (EBV). In this model system, the activities of late promoter-reporter fusions are measured following transient transfection into tissue culture cells expressing EBV during different stages of the lytic cycle. This system faithfully recapitulates late expression patterns from the endogenous virus, implicating specific cis-active sequences in the control of late gene expression. In addition, these promoters respond only indirectly to the viral immediate-early transactivator, ZEBRA. This indirect response is mediated by other viral or virally induced activities downstream of ZEBRA in the lytic cascade. In this system, late gene expression is sensitive to inhibitors of the viral DNA polymerase such as phosphonoacetic acid, although the reporters lack a eukaryotic origin of replication and are not replicated under the assay conditions. Thus, replication of the transcriptional template is not a prerequisite for expression with late kinetics, a finding inconsistent with the current models which posit a cis-active relationship between lytic EBV DNA replication and late gene expression. Rather, analysis of this system has revealed a trans relationship between late gene expression and viral DNA replication and highlights the indirect and complex link between these two events.

The Search for Origins of DNA Replication

The past decade has witnessed an explosion of new information about the nature of DNA replication in eukaryotic cells. Much of this information has resulted from the advent of novel methods for identifying and characterizing origins of DNA replication in the genomes of viruses, plasmids, and cells. These methods can map with remarkable precision sites where replication begins. In addition, they provide assays for origin activity that can be used to identify the sequence of events leading to the formation and activation of prereplication complexes at specific sites in chromosomal DNA. I summarize briefly the current view of eukaryotic replication origins and the methods that have been used to identify and characterize them. Selected methods that show promise for future applications are then described in detail in subsequent articles.

Reconstitution of a Functional Bovine Papillomavirus Type 1 Origin of Replication Reveals a Modular Tripartite Replicon with an Essential AT-Rich Element

A functional replication origin was reconstituted using oligonucleotide cassettes corresponding to three sequence subelements within the Bovine Papillomavirus Type 1 (BPV-1) replication origin: the 23-bp AT-rich region (ATR), the 18-bp binding site for the viral replication initiator protein E1 (E1BS), and a binding site for the viral transcriptional transactivator and replication enhancer protein E2 (E2BS). Replication of the reconstituted origin depended on heterologous expression of both the E1 and E2 proteins and on the presence of both the E1BS and E2BS, indicating that it is functionally analogous to the authentic BPV-1 origin. In addition, pairwise testing of subelement combinations revealed that the ATR was also essential and that a functional origin required at least one copy of all three subelements. While the E1BS and E2BS are sequence-specific elements, the function of the BPV-1 ATR could be at least partially substituted with heterologous AT-rich sequences, suggesting that the role of this element is primarily AT content-dependent rather than sequence-dependent. A stringent requirement for the ATR was also observed in the context of an authentic minimal origin sequence confirming that it is an intrinsic property of the BPV-1 origin and not simply an artifact of the reconstitution system. This study indicates that the minimal functional BPV-1 origin shares the tripartite modular organization characteristic of other simple eukaryotic replication origins. The reconstitution system described now provides a convenient approach to define the physical and functional interrelationships between the three subelements in a systematic fashion.

Human and Xenopus cDNAs encoding budding yeast Cdc7-related kinases: in vitro phosphorylation of MCM subunits by a putative human homologue of Cdc7.

Saccharomyces cerevisiae Cdc7 kinase is essential for initiation of DNA replication, and Hsk1, a related kinase of Schizosaccharomyces pombe, is also required for DNA replication of fission yeast cells. We report here cDNAs encoding Cdc7-related kinases from human and Xenopus (huCdc7 and xeCdc7, respectively). The cloned cDNA for huCdc7 contains an open reading frame consisting of 574 amino acids with a predicted molecular weight of 63,847 that possesses overall amino acid identity of 32% (54% including similar residues) to Cdc7 and Hsk1. huCDC7 is transcribed in the various tissues examined, but most abundantly in testis. Three transcripts of 4.4, 3.5 and 2.4 kb in length are detected. The 3.5 kb transcript is the most predominant and is expressed in all the tissues examined. A cDNA containing a 91 nucleotide insertion at the N-terminal region of huCDC7 is also detected, suggesting the presence of multiple splicing variants. The huCdc7 protein is expressed at a constant level during the mitotic cell cycle and is localized primarily in nuclei in interphase and distributed diffusibly in cytoplasm in the mitotic phase. The wild-type huCdc7 protein expressed in COS7 cells phosphorylates MCM2 and MCM3 proteins in vitro, suggesting that huCdc7 may regulate processes of DNA replication by modulating MCM functions.

Cyclin-dependent kinase and initiation at eukaryotic origins: a replication switch?

A growing body of evidence indicates that cyclin-dependent kinases (CDKs) regulate the activity of eukaryotic origins of replication both positively and negatively. Although the details of this control remain unclear, recent work suggests that CDKs act directly at origins, where they associate with and phosphorylate several key initiator proteins. These data suggest that a CDK-regulated replication switch operates at each origin to ensure that initiation occurs precisely once per cell cycle.

Systemic delivery of human growth hormone or human factor IX in dogs by reintroduced genetically modified autologous bone marrow stromal cells.

Canine bone marrow stromal cells were expanded to numbers in excess of 10(9) cells from the initial 10-20 ml of marrow aspirates and transfected to express high levels of human growth hormone (hGH) in vitro. Ex vivo-modified marrow stromal cells were used in a gene therapy model system for the systemic delivery of transgene products in dogs. Adherent bone marrow stromal cell cultures, established and expanded from iliac crest marrow aspirates from each of 8 dogs, were transfected with a hGH gene plasmid expression vector and shown to express from 0.54-3.84 micrograms/10(6) cells per 24 hr hGH in vitro. The transfected plasmid vector does not possess a eukaryotic origin of replication nor does it possess sequences required for efficient integration into the host cell genome. As such, expression was expected to be transient. Transfected cells were autologously reintroduced into each dog by either infusion into a foreleg vein or directly into iliac crest marrow. In two cases, the stromal cells were cryopreserved following transfection, and subsequently thawed and infused. In one case, the expanded stromal cells were first cryopreserved, and then thawed, recultured, transfected, and infused. Reintroduced cell numbers ranged from 2.2 x 10(7) to 2.6 x 10(9), with total hGH expression capacities ranging from 62 to 1,400 micrograms/24 hr. Plasma of each of the dogs contained detectable hGH for a mean of 3.1 days (SD +/- 0.8 day) ranging from 2 to 5 days following reinfusion of cells. Peak plasma levels ranged from 0.10 to 1.76 ng/ml. Similar hGH expression values, based upon total expression capacity of the cells infused and dog body weight, were obtained for all dogs. Vector-modified stromal cells were detectable, by polymerase chain reaction (PCR) analysis, in the peripheral circulation following reinfusion in all 4 dogs analyzed. In 3 of the dogs, modified stromal cells were detected for 8.5-15 weeks. In addition, modified stromal cells were detected in iliac crest marrow of 2 dogs for 9 and 13 weeks, respectively, following reinfusion. In another experiment, cultured bone marrow stromal cells were transfected with a human factor IX (hFIX) plasmid vector. Modified cells (5.57 x 10(8)), with a total hFIX expression capacity of 281 micrograms/24 hr, were reinfused, resulting in detectable hFIX in plasma continuously for 9 days with a peak level of 8 ng/ml on day 1. These results demonstrate that the ex vivo bone marrow stromal cell system is a potentially powerful method by which to deliver secreted transgene product to the systemic circulation of large animals.