Attachment of DNA Loops to an Artificial Matrix Does Not Affect the Replication Origin Specificity in Early Development of Xenopus laevis

Replication initiation proceeds in a random fashion in early development of Xenopus laevis. The replication origins become fixed only at later stages of development after the mid-blastula transition. Specification of replication origins occurs at the same time with the specification of the DNA attachment to the nuclear matrix. Replication origins of many species coincide or are located in the vicinity of sites of DNA attachment to the nuclear matrix. The present work was dedicated to development of an experimental system where DNA loops were specifically attached to an artificial matrix and a study of an effect of this attachment on specificity of DNA replication initiation in extracts of Xenopus laevis oocytes. We have found that DNA attachment to the artificial matrix increases the efficacy of DNA replication as compared to the control, but does not affect the replication specificity. It is likely that the transition from non-specific to specific replication is determined by a combination of several factors, and specificity of DNA attachment to a matrix alone is not sufficient for specification of a replication origin.     

Chromosomal replication initiates and terminates at random sequences but at regular intervals in the ribosomal DNA of Xenopus early embryos.

We have analysed the replication of the chromosomal ribosomal DNA (rDNA) cluster in Xenopus embryos before the midblastula transition. Two-dimensional gel analysis showed that replication forks are associated with the nuclear matrix, as in differentiated cells, and gave no evidence for single-stranded replication intermediates (RIs). Bubbles, simple forks and double Ys were found in each restriction fragment analysed, showing that replication initiates and terminates without detectable sequence specificity. Quantification of the results and mathematical analysis showed that the average rDNA replicon replicates in 7.5 min and is 9-12 kbp in length. This time is close to the total S phase duration, and this replicon size is close to the maximum length of DNA which can be replicated from a single origin within this short S phase. We therefore infer that (i) most rDNA origins must be synchronously activated soon in S phase and (ii) origins must be evenly spaced, in order that no stretch of chromosomal DNA is left unreplicated at the end of S phase. Since origins are not specific sequences, it is suggested that this spatially and temporally concerted pattern of initiation matches some periodic chromatin folding, which itself need not rely on DNA sequence.     

Nuclear proteins of quiescent Xenopus laevis cells inhibit DNA replication in intact and permeabilized nuclei

Quiescent cells from adult vertebrate liver and contact-inhibited or serum-deprived tissue cultures are active metabolically but do not carry out nuclear DNA replication and cell division. Replication of intact nuclei isolated from either quiescent Xenopus liver or cultured Xenopus A6 cells in quiescence was barely detectable in interphase extracts of Xenopus laevis eggs, although Xenopus sperm chromatin was replicated with approximately 100% efficiency in the same extracts. Permeabilization of nuclei from quiescent Xenopus liver or cultured Xenopus epithelial A6 cells did not facilitate efficient replication in egg extracts. Moreover, replication of Xenopus sperm chromatin in egg extracts was strongly inhibited by a soluble extract of isolated Xenopus liver nuclei; in contrast, complementary-strand synthesis on single-stranded DNA templates in egg extracts was not affected. Inhibition was specific to endogenous molecules localized preferentially in quiescent as opposed to proliferating cell nuclei, and was not due to suppression of cdk2 kinase activity. Extracts of Xenopus liver nuclei also inhibited growth of sperm nuclei formed in egg extracts. However, the rate and extent of decondensation of sperm chromatin in egg extracts were not affected. The formation of prereplication centers detected by anti-RP-A antibody was not affected by extracts of liver nuclei, but formation of active replication foci was blocked by the same extracts. Inhibition of DNA replication was alleviated when liver nuclear extracts were added to metaphase egg extracts before or immediately after Ca++ ion-induced transition to interphase. A plausible interpretation of our data is that endogenous inhibitors of DNA replication play an important role in establishing and maintaining a quiescent state in Xenopus cells, both in vivo and in cultured cells, perhaps by negatively regulating positive modulators of the replication machinery.     

The relationship between chromosomal origins of replication and the nuclear matrix during the cell cycle

A cytological investigation into the dynamic behaviour of the origins of replication with respect to the nuclear matrix has been carried out on Xenopus laevis cultured cells. In order to preferentially label origins or 'non-origin' regions along DNA fibres, 5-fluoro-2'-deoxyuridine (FUdR)-treated cells were pulsed with [3H]deoxyadenosine in early or late S phase. Samples were then allowed to proceed through the cell cycle for increasing times. The DNA loops were induced in situ to completely uncoil around the nuclear matrix. The autoradiographic analysis shows that, under the experimental conditions used, 'non-origin' regions behave as expected from previous studies, i.e., they associate with the nuclear matrix only when they become part of a replication fork, whereas active origins of replication remain associated with the matrix throughout the cell cycle.     

Regulated replication of DNA microinjected into eggs of Xenopus laevis

Purified circular DNA of SV40 or polyoma virus has been injected into unfertilized eggs of Xenopus laevis. Injected DNA initiates and completes multiple rounds of semiconservative replication while observing cellular regulatory signals. Thus replication initiation of double-stranded templates is induced after the oocyte is matured in vitro by progesterone. Only one round of replication of injected DNA is observed in a single cell cycle. When protein synthesis is inhibited unreplicated molecules continue to initiate replication at an undiminished rate, but reinitiation on previously replicated molecules is completely and selectively abolished. The DNA sequence requirements for the replication of injected DNA have been investigated. A variety of procaryotic DNA molecules and circularized fragments of SV40 or polyoma DNA replicate, regardless of whether they contain the viral origin of DNA replication. These results suggest that a specialized DNA sequence is not essential for the initiation of semiconservative DNA replication in the Xenopus embryo, nor is a specialized sequence essential for the mechanism which prevents reinitiation on a molecule which has already replicated within a cell cycle. The possibility is discussed that viral origins of replication are not valid models for the eucaryotic chromosome but are adaptations for uncoupling viral replication from the mechanism which prevents reinitiation within a cell cycle.     

Initiation of DNA replication requires the RECQL4 protein mutated in Rothmund-Thomson syndrome

How the replication machinery is loaded at origins of DNA replication is poorly understood. Here, we implicate in this process the Xenopus laevis homolog (xRTS) of the RECQL4 helicase mutated in Rothmund-Thomson syndrome. xRTS, which bears homology to the yeast replication factors Sld2/DRC1, is essential for DNA replication in egg extracts. xRTS can be replaced in extracts by its human homolog, while RECQL4 depletion from mammalian cells induces proliferation failure, suggesting an evolutionarily conserved function. xRTS accumulates on chromatin during replication initiation, after prereplication-complex (pre-RC) proteins, Cut5, Sld5, or Cdc45 but before replicative polymerases. xRTS depletion suppresses the loading of RPA, the ssDNA binding protein that marks unwound origins before polymerase recruitment. However, xRTS is unaffected by xRPA depletion. Thus, xRTS functions after pre-RC formation to promote loading of replication factors at origins, a previously unrecognized activity necessary for initiation. This role connects defective replication initiation to a chromosome-fragility disorder.     

Initiation of replication at specific origins in DNA molecules microinjected into unfertilized eggs of the frog Xenopus laevis

Initiation of DNA replication at specific origins was observed by electron microscopy after microinjection of pXlr11, pXlr14 or Col E1 plasmid DNA molecules into unfertilized eggs of the frog, Xenopus laevis. These results are in apparent contradiction with published reports (Harland and Laskey, Cell 21, 761-771, 1980; Laskey and Harland, Cell 24, 283-284, 1981) that specific origin sites were not used in Xenopus laevis eggs. We suggest that eucaryotic origins exist that both increase the probability of replication of contiguous sequences and determine the site at which replication is most likely to begin.     

Remodeling of chromatin loops does not account for specification of replication origins during Xenopus development

We have investigated the possible relationship between replicons and chromatin loops during Xenopus development. In early embryos, replication of the ribosomal RNA genes (rDNA) can initiate at apparently any sequence. Nevertheless, the need for a regular spacing of replication origins suggests that some periodic chromatin folding might dictate which sites are actually used for initiation. After the midblastula transition, replication initiation is restricted to the rDNA intergenic spacers. A remodeling of chromatin folding could account for this change in origin usage. Here, it is reported that nuclear matrix anchorage of the Xenopus rDNA occurs at multiple, apparently random sequences, throughout embryonic development as well as in adult cells. In vitro matrix rebinding assays confirmed the lack of specific anchoring sequences in the rDNA, before as well as after specific replication origins are established. Thus, no change in loop attachment sites could explain the change in origin usage at this locus. Nonspecific loop anchorage was a special feature of the rDNA locus, since the same nuclear matrices were able selectively to bind the scaffold attachment region (SAR) of the Drosophila histone gene cluster in vitro. Blastula and gastrula nuclear matrices bound a higher amount of SAR sequences than matrices from later stages or adult cells. This developmental change in SAR binding might explain the increase in size of the bulk of genomic DNA loops that occurs after the gastrula stage. However, no change in chromatin loop organization that could explain the midblastula stage transition from small to large replicons was observed. Received: 15 January 1998; in revised form: 4 March 1998 / Accepted: 9 March 1998     

Initiation of DNA replication at a nuclear matrix-attached chromatin fraction

It is still unclear what nuclear components support initiation of DNA replication. To address this issue, we developed a cell-free replication system in which the nuclear matrix along with the residual matrix-attached chromatin was used as a substrate for DNA replication. We found out that initiation occurred at late G1 residual chromatin but not at early G1 chromatin and depended on cytosolic and nuclear factors present in S phase cells but not in G1 cells. Initiation of DNA replication occurred at discrete replication foci in a pattern typical for early S phase. To prove that the observed initiation takes place at legitimate DNA replication origins, the in vitro synthesized nascent DNA strands were isolated and analyzed. It was shown that they were enriched in sequences from the core origin region of the early firing, dihydrofolate reductase origin of replication ori-beta and not in distal to the origin sequences. A conclusion is drawn that initiation of DNA replication occurs at discrete sub-chromosomal structures attached to the nuclear matrix.     

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.     

Replication initiation complex formation in the absence of nuclear function in Xenopus

In this article, we study how intercalation-induced changes in chromatin and DNA topology affect chromosomal DNA replication using Xenopus egg extracts. Unexpectedly, intercalation by ethidium or doxorubicin prevents formation of a functional nucleus: although nucleosome formation occurs, DNA decondensation is arrested, membranous vesicles accumulate around DNA but do not fuse to form a nuclear membrane, active transport is abolished and lamins are found on chromatin, but do not assemble into a lamina. DNA replication is inhibited at the stage of initiation complex activation, as shown by molecular combing of DNA and by the absence of checkpoint activation. Replication of single-stranded DNA is not prevented. Surprisingly, in spite of the absence of nuclear function, DNA-replication proteins of pre-replication and initiation complexes are loaded onto chromatin. This is a general phenomenon as initiation complexes could also be seen without ethidium in membrane-depleted extracts which do not form nuclei. These results suggest that DNA or chromatin topology is required for generation of a functional nucleus, and activation, but not formation, of initiation complexes.     

Nuclear matrix support of DNA replication

In higher eukaryotic cells, DNA is tandemly arranged into 10(4) replicons that are replicated once per cell cycle during the S phase. To achieve this, DNA is organized into loops attached to the nuclear matrix. Each loop represents one individual replicon with the origin of replication localized within the loop and the ends of the replicon attached to the nuclear matrix at the bases of the loop. During late G1 phase, the replication origins are associated with the nuclear matrix and dissociated after initiation of replication in S phase. Clusters of several replicons are operated together by replication factories, assembled at the nuclear matrix. During replication, DNA of each replicon is spooled through these factories, and after completion of DNA synthesis of any cluster of replicons, the respective replication factories are dismantled and assembled at the next cluster to be replicated. Upon completion of replication of any replicon cluster, the resulting entangled loops of the newly synthesized DNA are resolved by topoisomerases present in the nuclear matrix at the sites of attachment of the loops. Thus, the nuclear matrix plays a dual role in the process of DNA replication: on one hand, it represents structural support for the replication machinery and on the other, provides key protein factors for initiation, elongation, and termination of the replication of eukaryotic DNA.     

Non-proteolytic inactivation of geminin requires CDK-dependent ubiquitination

In late mitosis and G1, a complex of the essential initiation proteins Mcm2-7 are assembled onto replication origins to 'license' them for initiation. At other times licensing is inhibited by cyclin-dependent kinases (CDKs) and geminin, thus ensuring that origins fire only once per cell cycle. Here we show that, paradoxically, CDKs are also required to inactivate geminin and activate the licensing system. On exit from metaphase in Xenopus laevis egg extracts, CDK-dependent activation of the anaphase-promoting complex (APC/C) results in the transient polyubiquitination of geminin. This ubiquitination triggers geminin inactivation without requiring ubiquitin-dependent proteolysis, and is essential for replication origins to become licensed. This reveals an unexpected role for CDKs and ubiquitination in activating chromosomal DNA replication.     

The midblastula transition defines the onset of Y RNA-dependent DNA replication in Xenopus laevis

Noncoding Y RNAs are essential for the initiation of chromosomal DNA replication in mammalian cell extracts, but their role in this process during early vertebrate development is unknown. Here, we use antisense morpholino nucleotides (MOs) to investigate Y RNA function in Xenopus laevis and zebrafish embryos. We show that embryos in which Y RNA function is inhibited by MOs develop normally until the midblastula transition (MBT) but then fail to replicate their DNA and die before gastrulation. Consistent with this observation, Y RNA function is not required for DNA replication in Xenopus egg extracts but is required for replication in a post-MBT cell line. Y RNAs do not bind chromatin in karyomeres before MBT, but they associate with interphase nuclei after MBT in an origin recognition complex (ORC)-dependent manner. Y RNA-specific MOs inhibit the association of Y RNAs with ORC, Cdt1, and HMGA1a proteins, suggesting that these molecular associations are essential for Y RNA function in DNA replication. The MBT is thus a transition point between Y RNA-independent and Y RNA-dependent control of vertebrate DNA replication. Our data suggest that in vertebrates Y RNAs function as a developmentally regulated layer of control over the evolutionarily conserved eukaryotic DNA replication machinery.     

DNA unwinding is an Mcm complex-dependent and ATP hydrolysis-dependent process

Minichromosome maintenance proteins (Mcm) are essential in all eukaryotes and are absolutely required for initiation of DNA replication. The eukaryotic and archaeal Mcm proteins have conserved helicase motifs and exhibit DNA helicase and ATP hydrolysis activities in vitro. Although the Mcm proteins have been proposed to be the replicative helicase, the enzyme that melts the DNA helix at the replication fork, their function during cellular DNA replication elongation is still unclear. Using nucleoplasmic extract (NPE) from Xenopus laevis eggs and six purified polyclonal antibodies generated against each of the Xenopus Mcm proteins, we have demonstrated that Mcm proteins are required during DNA replication and DNA unwinding after initiation of replication. Quantitative depletion of Mcms from the NPE results in normal replication and unwinding, confirming that Mcms are required before pre-replicative complex assembly and dispensable thereafter. Replication and unwinding are inhibited when pooled neutralizing antibodies against the six different Mcm2-7 proteins are added during NPE incubation. Furthermore, replication is blocked by the addition of the Mcm antibodies after an initial period of replication in the NPE, visualized by a pulse of radiolabeled nucleotide at the same time as antibody addition. Addition of the cyclin-dependent kinase 2 inhibitor p21(cip1) specifically blocks origin firing but does not prevent helicase action. When p21(cip1) is added, followed by the non-hydrolyzable analog ATPgammaS to block helicase function, unwinding is inhibited, demonstrating that plasmid unwinding is specifically attributable to an ATP hydrolysis-dependent function. These data support the hypothesis that the Mcm protein complex functions as the replicative helicase.     

Geminin becomes activated as an inhibitor of Cdt1/RLF-B following nuclear import

During late mitosis and early interphase, origins of replication become "licensed" for DNA replication by loading Mcm2-7 complexes. Mcm2-7 complexes are removed from origins as replication forks initiate replication, thus preventing rereplication of DNA in a single cell cycle. Premature origin licensing is prevented in metaphase by the action of geminin, which binds and inhibits Cdt1/RLF-B, a protein that is required for the loading of Mcm2-7. Recombinant geminin that is added to Xenopus egg extracts is efficiently degraded upon exit from metaphase. Here, we show that recombinant and endogenous forms of Xenopus geminin behave differently from one another, such that a significant proportion of endogenous geminin escapes proteolysis upon exit from metaphase. During late mitosis and early G1, the surviving population of endogenous geminin does not associate with Cdt1/RLF-B and does not inhibit licensing. Following nuclear assembly, geminin is imported into nuclei and becomes reactivated to bind Cdt1/RLF-B. This reactivated geminin provides the major nucleoplasmic inhibitor of origin relicensing during late interphase. Since the initiation of replication at licensed origins depends on nuclear assembly, our results suggest an elegant and novel mechanism for preventing rereplication of DNA in a single cell cycle.