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.     

Origin recognition and the chromosome cycle

Prior to the initiation of DNA replication, chromosomes must establish a biochemical mark that permits the recruitment in S phase of the DNA replication machinery that copies DNA. The process of chromosome replication in eukaryotes also must be coordinated with segregation of the duplicated chromosomes to daughter cells during mitosis. Protein complexes that utilize ATP coordinate events at origins of DNA replication and later they participate in the initiation of DNA replication. In eukaryotes, some of these proteins also play a part in later processes that ensure accurate inheritance of chromosomes in mitosis, including spindle attachment of chromosomes, accurate duplication of centrosomes and cytokinesis. A perspective of how ATP-dependent proteins accomplish this task in eukaryotes is discussed.     

Metazoan origins of DNA replication: Regulation through dynamic chromatin structure

DNA replication in eukaryotes is initiated at multiple replication origins distributed over the entire genome, which are normally activated once per cell cycle. Due to the complexity of the metazoan genome, the study of metazoan replication origins and their activity profiles has been less advanced than in simpler genome systems. DNA replication in eukaryotes involves many protein–protein and protein–DNA interactions, occurring in multiple stages. As in prokaryotes, control over the timing and frequency of initiation is exerted at the initiation site. A prerequisite for understanding the regulatory mechanisms of eukaryotic DNA replication is the identification and characterization of the cis‐acting sequences that serve as replication origins and the trans‐acting factors (proteins) that interact with them. Furthermore, in order to understand how DNA replication may become deregulated in malignant cells, the distinguishing features between normal and malignant origins of DNA replication as well as the proteins that interact with them must be determined. Based on advances that were made using simple genome model systems, several proteins involved in DNA replication have been identified. This review summarizes the current findings about metazoan origins of DNA replication and their interacting proteins as well as the role of chromatin structure in their regulation. Furthermore, progress in origin identification and isolation procedures as well as potential mechanisms to inhibit their activation in cancer development and progression are discussed. J. Cell. Biochem. 106: 512–520, 2009. © 2009 Wiley‐Liss, Inc.     

Initiation of eukaryotic DNA replication: conservative or liberal?

The mechanism for initiation of eukaryotic DNA replication is highly conserved: the proteins required to initiate replication, the sequence of events leading to initiation, and the regulation of initiation are remarkably similar throughout the eukaryotic kingdom. Nevertheless, there is a liberal attitude when it comes to selecting initiation sites. Differences appear to exist in the composition of replication origins and in the way proteins recognize these origins. In fact, some multicellular eukaryotes (the metazoans) can change the number and locations of initiation sites during animal development, revealing that selection of initiation sites depends on epigenetic as well as genetic parameters. Here we have attempted to summarize our understanding of this process, to identify the similarities and differences between single cell and multicellular eukaryotes, and to examine the extent to which origin recognition proteins and replication origins have been conserved among eukaryotes. Published 2000 Wiley-Liss, Inc.     

Replication initiation and DNA topology: The twisted life of the origin

Genomic propagation in both prokaryotes and eukaryotes is tightly regulated at the level of initiation, ensuring that the genome is accurately replicated and equally segregated to the daughter cells. Even though replication origins and the proteins that bind onto them (initiator proteins) have diverged throughout the course of evolution, the mechanism of initiation has been conserved, consisting of origin recognition, multi‐protein complex assembly, helicase activation and loading of the replicative machinery. Recruitment of the multiprotein initiation complexes onto the replication origins is constrained by the dense packing of the DNA within the nucleus and unusual structures such as knots and supercoils. In this review, we focus on the DNA topological barriers that the multi‐protein complexes have to overcome in order to access the replication origins and how the topological state of the origins changes during origin firing. Recent advances in the available methodologies to study DNA topology and their clinical significance are also discussed. J. Cell. Biochem. 110: 35–43, 2010. © 2010 Wiley‐Liss, Inc.     

Le modèle du réplicon est-il applicable aux eucaryotes supérieurs?

Thirty-five years ago, the Replicon model was proposed by Jacob, Brenner and Cuzin to explain the regulation of the Escherichia coli DNA replication. In this model, a genetic element, the replicator, would function as a target for a positive-acting initiator protein to drive the initiation of replication. This simple idea has been extremely useful in providing a framework to explain how the initiation of DNA replication occurs in all organisms. The identification of autonomously replicating sequences (ARSs) in budding yeast was the first extension of the Replicon model to eukaryotic chromosomes. In the higher eukaryotes, many biochemically defined replication start sites have been identified; nevertheless there is little genetic data indicating that these sites contain DNA sequences that are essential for replication. Moreover, in early Xenopus or Drosophila embryos, specific DNA sequences are not required either for initiating DNA replication or for preventing rereplication within a single cell cycle. This apparently fundamental difference between replicators in yeast and metazoan embryos may be more superficial than initially thought. In fact, during the past several years, an eukaryotic initiator conserved from yeast to man and also present in embryonic cells, the origin recognition complex (ORC), has been characterized, suggesting that the initiation mechanism should be essentially the same in prokaryotes and eukaryotes. In addition, the efficient once-per-cell-cycle replication of DNA is ensured in eukaryotes by a simple two-step mechanism in which the assembly of stable prereplicative complexes (PreRCs) at origins precedes and is temporally separated from the firing of these origins. Regulation of this process by cyclin-dependent kinases ensures that when origins fire, the cell is no longer competent to form new PreRCs. Now, it is important to understand how these complexes are remodeled or disassembled during replication initiation to trigger the transition from a stable origin-bound complex to a mobile replication machine.     

Control of DNA replication: regulation and activation of eukaryotic replicative helicase, MCM

DNA replication is a key event of cell proliferation and the final target of signal transduction induced by growth factor stimulation. It is also strictly regulated during the ongoing cell cycle so that it occurs only once during S phase and that all the genetic materials are faithfully duplicated. DNA replication may be arrested or temporally inhibited due to a varieties of internal and external causes. Cells have developed intricate mechanisms to cope with the arrested replication forks to minimize the adversary effect on the stable maintenance of genetic materials. Helicases play a central role in DNA replication. In eukaryotes, MCM (minichromosome maintenance) protein complex plays essential roles as a replicative helicase. MCM4-6-7 complex possesses intrinsic DNA helicase activity which translocates on single-stranded DNA form 3' to 5'. Mammalian MCM4-6-7 helicase and ATPase activities are specifically stimulated by the presence of thymine-rich single-stranded DNA sequences onto which it is loaded. The activation appears to depend on the thymine content of this single-strand, and sequences derived from human replication origins can serve as potent activators of the MCM helicase. MCM is a prime target of Cdc7 kinase, known to be essential for activation of replication origins. We will discuss how the MCM may be activated at the replication origins by template DNA, phosphorylation, and interaction with other replicative proteins, and will present a model of how activation of MCM helicase by specific sequences may contribute to selection of replication initiation sites in higher eukaryotes.     

Flexibility and governance in eukaryotic DNA replication

Eukaryotic DNA replication begins at numerous but often poorly characterized sequences called origins, which are distributed fairly regularly along chromosomes. The elusive and idiosyncratic nature of origins in higher eukaryotes is now understood as resulting from a strong epigenetic influence on their specification, which provides flexibility in origin selection and allows for tailoring the dynamics of chromosome replication to the specific needs of cells. By contrast, the factors that assemble in trans to make these origins competent for replication and the kinases that trigger initiation are well conserved. Genome-wide and single-molecule approaches are being developed to elucidate the dynamics of chromosome replication. The notion that a well-coordinated progression of replication forks is crucial for many aspects of the chromosome cycle besides simply duplication begins to be appreciated.     

Cdc7 kinase complex: a key regulator in the initiation of DNA replication

DNA replication results from the action of a staged set of highly regulated processes. Among the stages of DNA replication, initiation is the key point at which all the G1 regulatory signals culminate. Cdc7 kinase is the critical regulator for the ultimate firing of the origins of initiation. Cdc7, originally identified in budding yeast and later in higher eukaryotes, forms a complex with a Dbf4-related regulatory subunit to generate an active kinase. Genetic evidence in mammals demonstrates essential roles for Cdc7 in mammalian DNA replication. Mini-chromosome maintenance protein (MCM) is the major physiological target of Cdc7. Genetic studies in yeasts indicate additional roles of Cdc7 in meiosis, checkpoint responses, maintenance of chromosome structures, and repair. The interplay between Cdc7 and Cdk, another kinase essential for the S phase, is also discussed.     

Activation of budding yeast replication origins and suppression of lethal DNA damage effects on origin function by ectopic expression of the co-chaperone protein Mge1

Initiation of DNA replication in eukaryotes requires the origin recognition complex (ORC) and other proteins that interact with DNA at origins of replication. In budding yeast, the temperature-sensitive orc2-1 mutation alters these interactions in parallel with defects in initiation of DNA replication and in checkpoints that depend on DNA replication forks. Here we show that DNA-damaging drugs modify protein-DNA interactions at budding yeast replication origins in association with lethal effects that are enhanced by the orc2-1 mutation or suppressed by a different mutation in ORC. A dosage suppressor screen identified the budding yeast co-chaperone protein Mge1p as a high copy suppressor of the orc2-1-specific lethal effects of adozelesin, a DNA-alkylating drug. Ectopic expression of Mge1p also suppressed the temperature sensitivity and initiation defect conferred by the orc2-1 mutation. In wild type cells, ectopic expression of Mge1p also suppressed the lethal effects of adozelesin in parallel with the suppression of adozelesin-induced alterations in protein-DNA interactions at origins, stimulation of initiation of DNA replication, and binding of the precursor form of Mge1p to nuclear chromatin. Mge1p is the budding yeast homologue of the Escherichia coli co-chaperone protein GrpE, which stimulates initiation at bacterial origins of replication by promoting interactions of initiator proteins with origin sequences. Our results reveal a novel, proliferation-dependent cytotoxic mechanism for DNA-damaging drugs that involves alterations in the function of initiation proteins and their interactions with DNA.     

Replication origins in metazoan chromosomes: fact or fiction?

The process by which eukaryotic cells decide when and where to initiate DNA replication has been illuminated in yeast, where specific DNA sequences (replication origins) bind a unique group of proteins (origin recognition complex) next to an easily unwound DNA sequence at which replication can begin. The origin recognition complex provides a platform on which additional proteins assemble to form a pre-replication complex that can be activated at S-phase by specific protein kinases. Remarkably, multicellular eukaryotes, such as frogs, flies, and mammals (metazoa), have counterparts to these yeast proteins that are required for DNA replication. Therefore, one might expect metazoan chromosomes to contain specific replication origins as well, a hypothesis that has long been controversial. In fact, recent results strongly support the view that DNA replication origins in metazoan chromosomes consist of one or more high frequency initiation sites and perhaps several low frequency ones that together can appear as a nonspecific initiation zone. Specific replication origins are established during G1-phase of each cell cycle by multiple parameters that include nuclear structure, chromatin structure, DNA sequence, and perhaps DNA modification. Such complexity endows metazoa with the flexibility to change both the number and locations of replication origins in response to the demands of animal development.     

Think global, act local--how to regulate S phase from individual replication origins

All eukaryotes use similar proteins to licence replication origins but, paradoxically, origin DNA is much less conserved. Specific binding sites for these proteins have now been identified on fission yeast and Drosophila chromosomes, suggesting that the DNA-binding activity of the origin recognition complex has diverged to recruit conserved initiation factors on polymorphic replication origins. Once formed, competent origins are activated by cyclin- and Dbf4-dependent kinases. The latter have been shown to control S phase in several organisms but, in contrast to cyclin-dependent kinases, seem regulated at the level of individual origins. Global and local regulations generate specific patterns of DNA replication that help establish epigenetic chromosome states.     

Sld3, which interacts with Cdc45 (Sld4), functions for chromosomal DNA replication in Saccharomyces cerevisiae

Cdc45, which binds to the minichromosomal maintenance (Mcm) proteins, has a pivotal role in the initiation and elongation steps of chromosomal DNA replication in eukaryotes. Here we show that throughout the cell cycle in Saccharomyces cerevisiae, Cdc45 forms a complex with a novel factor, Sld3. Consistently, Sld3 and Cdc45 associate simultaneously with replication origins in the chromatin immunoprecipitation assay: both proteins associate with early-firing origins in G(1) phase and with late-firing origins in late S phase. Moreover, the origin associations of Sld3 and Cdc45 are mutually dependent. The temperature-sensitive sld3 mutation confers a defect in DNA replication at the restrictive temperature and reduces an interaction not only between Sld3 and Cdc45, but also between Cdc45 and Mcm2. These results suggest that the Sld3-Cdc45 complex associates with replication origins through Mcm proteins. At the restrictive temperature in sld3-5 cells, replication factor A, a single-strand DNA binding protein, does not associate with origins. Therefore, the origin association of Sld3-Cdc45 complex is prerequisite for origin unwinding in the initiation of DNA replication.     

Differences in the DNA replication of unicellular eukaryotes and metazoans: known unknowns

Although the basic mechanisms of DNA synthesis are conserved across species, there are differences between simple and complex organisms. In contrast to lower eukaryotes, replication origins in complex eukaryotes lack DNA sequence specificity, can be activated in response to stressful conditions and require poorly conserved factors for replication firing. The response to replication fork damage is monitored by conserved proteins, such as the TIPIN–TIM–CLASPIN complex. The absence of this complex induces severe effects on yeast replication, whereas in higher eukaryotes it is only crucial when the availability of replication origins is limiting. Finally, the dependence of DNA replication on homologous recombination proteins such as RAD51 and the MRE11–RAD50–NBS1 complex is also different; they are dispensable for yeast S‐phase but essential for accurate DNA replication in metazoans under unchallenged conditions. The reasons for these differences are not yet understood. Here, we focus on some of these known unknowns of DNA replication.     

真核细胞染色体DNA复制起始及复制叉稳定性维持的机制

在真核生物中,DNA复制在染色体上特定的多位点起始．当细胞处在晚M及G1期,多个复制起始蛋白依次结合到DNA复制源,组装形成复制前复合体．pre．RC在Gl-S的转折期得到激活,随后,多个直接参与DNA复制又形成的蛋白结合到DNA复制源,启动DNA的复制,形成两个双向的DNA复制又．在染色体上,移动的DNA复制又经常会碰到复制障碍（二级DNA结构、一些蛋白的结合位点、损伤的碱基等）而暂停下来,此时,需要细胞周期检验点的调控来稳定复制叉,否则,会导致复制又垮塌及基因组不稳定．本文就真核细胞染色体DNA复制起始的机制,以及复制又稳定性的维持机制进行简要综述．     

ATM and ATR Check in on Origins: A Dynamic Model for Origin Selection and Activation

Initiation of DNA replication occurs at origins of replication, traditionally defined by specific sequence elements. Sequence-dependent initiation of replication is the rule in prokaryotes and in the yeast Saccharomyces cereviseae. However, sequence-dependent initiation does not appear to be absolutely required in metazoan eukaryotes. Origin firing is instead likely dependent on stochastic initiation from chromatin-defined loci, despite the demonstration of some specific origins. Based on some recent observations in Xenopus laevis egg extracts and in mammalian cell culture, we propose that timing of origin firing is dependent on feedback from active replicons. This dynamic regulation of replication is mediated by sensing of ongoing replication by the DNA-damage checkpoint kinases ATM and ATR, which in turn downregulate neighboring and distal origins and replicons by inhibition of the S-phase kinases Cdk2 and Cdc7 and by inhibition of the replicative Mcm helicase. Origin selection, activation, and replicon progression are therefore constrained in both space and time via feedback from the cell cycle and ongoing replication.