Marcel Méchali

XCDT1 is required for the assembly of pre-replicative complexes in Xenopus laevis.

In eukaryotic cells, chromosomal DNA replication begins with the formation of pre-replication complexes at replication origins. Formation and maintenance of pre-replication complexes is dependent upon CDC6 (ref. 1), a protein which allows assembly of MCM2–7 proteins, which are putative replicative helicases. The functional assembly of MCM proteins into chromatin corresponds to replication licensing. Removal of these proteins from chromatin in S phase is crucial in origins firing regulation. We have identified a protein that is required for the assembly of pre-replication complexes, in a screen for maternally expressed genes in Xenopus. This factor (XCDT1) is a relative of fission yeast cdt1, a protein proposed to function in DNA replication, and is the first to be identified in vertebrates. Here we show, using Xenopus in vitro systems, that XCDT1 is required for chromosomal DNA replication. XCDT1 associates with pre-replicative chromatin in a manner dependent on ORC protein and is removed from chromatin at the time of initiation of DNA synthesis. Immunodepletion and reconstitution experiments show that XCDT1 is required to load MCM2–7 proteins onto pre-replicative chromatin. These findings indicate that XCDT1 is an essential component of the system that regulates origins firing during S phase.

Transition in Specification of Embryonic Metazoan DNA Replication Origins

In early Xenopus embryos, in which ribosomal RNA genes (rDNA) are not transcribed, rDNA replication initiates and terminates at 9- to 12-kilobase pair intervals, with no detectable dependence on specific DNA sequences. Resumption of ribosomal RNA (rRNA) synthesis at late blastula and early gastrula is accompanied by a specific repression of replication initiation within transcription units; the frequency of initiation within intergenic spacers remains as high as in early blastula. These results demonstrate that for rRNA genes, circumscribed zones of replication initiation emerge in intergenic DNA during the time in metazoan development when the chromatin is remodeled to allow gene transcription.

Eukaryotic DNA replication origins: many choices for appropriate answers

At each cell division in humans, 30,000–50,000 DNA replication origins are activated, and it remains unclear how they are selected and recognized by replication factors. DNA replication in multicellular organisms must accommodate variations in growth conditions and DNA damage. It must also adapt to changes in chromatin organization associated with cell differentiation and development. The selection of replication origins in metazoans seems to involve multiple choices, with the appropriate answers depending on the identity of the cell or the conditions of growth. This suggests that during evolution, the use of replication origins became more controlled by epigenetic mechanisms affecting chromosome dynamics and expression than by DNA synthesis per se.

Mitotic Remodeling of the Replicon and Chromosome Structure

Animal cloning by nuclear-transfer experiments frequently fails due to the inability of transplanted nuclei to support normal embryonic development. We show here that the formation of mitotic chromosomes in the egg context is crucial for adapting differentiated nuclei for early development. Differentiated erythrocyte nuclei replicate inefficiently in Xenopus eggs but do so as rapidly as sperm nuclei if a prior single mitosis is permitted. This mitotic remodeling involves a topoisomerase II-dependent shortening of chromatin loop domains and an increased recruitment of replication initiation factors onto chromatin, leading to a short interorigin spacing characteristic of early developmental stages. It also occurs within each early embryonic cell cycle and dominantly regulates initiation of DNA replication for the subsequent S phase. These results indicate that mitotic conditioning is crucial to reset the chromatin structure of differentiated adult donor cells for embryonic DNA replication and suggest that it is an important step in nuclear cloning.

Specification of a DNA replication origin by a transcription complex

In early Xenopus development, transcription is repressed and DNA replication initiates at non-specific sites. Here, we show that a site-specific DNA replication origin can be induced in this context by the assembly of a transcription domain. Deletion of the promoter element abolishes site-specific initiation, and its relocalization to an ectopic site induces a new origin of replication. This process does not require active transcription, and specification of the origin occurs mainly through a decrease in non-specific initiation at sites distant from the promoter. Finally, chromatin immunoprecipitation experiments suggest that site-specific acetylation of histones favours the selection of the active DNA replication origin. We propose that the specification of active DNA replication origins occurs by secondary epigenetic events and that the programming of chromatin for transcription during development contributes to this selection in higher eukaryotes.

Competition between chromatin and transcription complex assembly regulates gene expression during early development

Xenopus early development is characterized by a generalized absence of transcription, which resumes at the midblastula transition (MBT). We analyzed this regulation using a plasmid containing the c-myc promoter that is under the same developmental control when injected into fertilized eggs. We find that the repression of transcription can be relieved simply by preincubating the reporter plasmid with TATA binding protein (TBP). However, the repression of gene activity normally occurring before the MBT soon becomes dominant over this activation independent of cell cycle phases. This inactivation correlates with chromatin assembly, and titration of chromatin components not only relieves repression of TBP-dependent transcription but also permits the establishment of stable transcription during early development. Our data suggest that the large excess of histones represses gene activity during early development through a dynamic competition between chromatin assembly and transcription complex assembly.

New insights into replication origin characteristics in metazoans.

We recently reported the identification and characterization of DNA replication origins (Oris) in metazoan cell lines. Here, we describe additional bioinformatic analyses showing that the previously identified GC-rich sequence elements form origin G-rich repeated elements (OGREs) that are present in 67% to 90% of the DNA replication origins from Drosophila to human cells, respectively. Our analyses also show that initiation of DNA synthesis takes place precisely at 160 bp (Drosophila) and 280 bp (mouse) from the OGRE. We also found that in most CpG islands, an OGRE is positioned in opposite orientation on each of the two DNA strands and detected two sites of initiation of DNA synthesis upstream or downstream of each OGRE. Conversely, Oris not associated with CpG islands have a single initiation site. OGRE density along chromosomes correlated with previously published replication timing data. Ori sequences centered on the OGRE are also predicted to have high intrinsic nucleosome occupancy. Finally, OGREs predict G-quadruplex structures at Oris that might be structural elements controlling the choice or activation of replication origins.

DNA replication origin activation in space and time

DNA replication begins with the assembly of pre-replication complexes (pre-RCs) at thousands of DNA replication origins during the G1 phase of the cell cycle. At the G1–S-phase transition, pre-RCs are converted into pre-initiation complexes, in which the replicative helicase is activated, leading to DNA unwinding and initiation of DNA synthesis. However, only a subset of origins are activated during any S phase. Recent insights into the mechanisms underlying this choice reveal how flexibility in origin usage and temporal activation are linked to chromosome structure and organization, cell growth and differentiation, and replication stress.

DNA replication origins: from sequence specificity to epigenetics

Site-specific initiation of DNA replication is a conserved function in all organisms. In Escherichia coli and Saccharomyces cerevisiae, DNA replication origins are sequence specific, but in multicellular organisms, origins are not so clearly defined. In this article, I present a model of origin specification by epigenetic mechanisms that allows the establishment of stable chromatin domains, which are characterized by autonomous replication. According to this model, origins of DNA replication help to establish domains of gene expression for the generation of cell diversity.

MCM8 Is an MCM2-7-Related Protein that Functions as a DNA Helicase during Replication Elongation and Not Initiation

MCM2-7 proteins are replication factors required to initiate DNA synthesis and are currently the best candidates for replicative helicases. We show that the MCM2-7-related protein MCM8 is required to efficiently replicate chromosomal DNA in Xenopus egg extracts. MCM8 does not associate with the soluble MCM2-7 complex and binds chromatin upon initiation of DNA synthesis. MCM8 depletion does not affect replication licensing or MCM3 loading but slows down DNA synthesis and reduces chromatin recruitment of RPA34 and DNA polymerase-alpha. Recombinant MCM8 displays both DNA helicase and ATPase activities in vitro. Reconstitution experiments show that ATP binding in MCM8 is required to rescue DNA synthesis in MCM8-depleted extracts. MCM8 colocalizes with replication foci and RPA34 on chromatin. We suggest that MCM8 functions in the elongation step of DNA replication as a helicase that facilitates the recruitment of RPA34 and stimulates the processivity of DNA polymerases at replication foci.