A question of timing: emerging links between transcription and replication

Genome-wide localization of pre-RC sites and identification of replication origins in fission yeast

DNA replication of eukaryotic chromosomes initiates at a number of discrete loci, called replication origins. Distribution and regulation of origins are important for complete duplication of the genome. Here, we determined locations of Orc1 and Mcm6, components of pre-replicative complex (pre-RC), on the whole genome of Schizosaccharomyces pombe using a high-resolution tiling array. Pre-RC sites were identified in 460 intergenic regions, where Orc1 and Mcm6 colocalized. By mapping of 5-bromo-2'-deoxyuridine (BrdU)-incorporated DNA in the presence of hydroxyurea (HU), 307 pre-RC sites were identified as early-firing origins. In contrast, 153 pre-RC sites without BrdU incorporation were considered to be late and/or inefficient origins. Inactivation of replication checkpoint by Cds1 deletion resulted in BrdU incorporation with HU specifically at the late origins. Early and late origins tend to distribute separately in large chromosome regions. Interestingly, pericentromeric heterochromatin and the silent mating-type locus replicated in the presence of HU, whereas the inner centromere or subtelomeric heterochromatin did not. Notably, MCM did not bind to inner centromeres where origin recognition complex was located. Thus, replication is differentially regulated in chromosome domains.

Replication foci dynamics: replication patterns are modulated by S-phase checkpoint kinases in fission yeast

Although the molecular enzymology of DNA replication is well characterised, how and why it occurs in discrete nuclear foci is unclear. Using fission yeast, we show that replication takes place in a limited number of replication foci, whose distribution changes with progression through S phase. These sites define replication factories which contain on average 14 replication forks. We show for the first time that entire foci are mobile, able both to fuse and re-segregate. These foci form distinguishable patterns during S phase, whose succession is reproducible, defining early-, mid- and late-S phase. In wild-type cells, this same temporal sequence can be detected in the presence of hydroxyurea (HU), despite the reduced rate of replication. In cells lacking the intra-S checkpoint kinase Cds1, replication factories dismantle on HU. Intriguingly, even in the absence of DNA damage, the replication foci in cds1 cells assume a novel distribution that is not present in wild-type cells, arguing that Cds1 kinase activity contributes to the spatio-temporal organisation of replication during normal cell growth.

Non-denaturing fluorescence in situ hybridization to find replication origins in a specific genome region on the DNA fiber

Fluorescence in situ hybridization (FISH) is a useful method of determining the replication timing of specific genomic loci in mammals and of delineating replicon structures on DNA fibers in combination with in vivo replication labeling. In the case of simultaneous detection of a FISH probe and replicated forks, however, the DNA fibers are damaged by the DNA denaturation step for FISH detection, and the resulting fragmented fluorescence signals prevent analysis at high resolution. Here we found that hybridization of the probe to the genomic DNA was possible even under non-denaturing condition, but only at the time its genomic region replicated. Using the method designated non-denaturing FISH, we determined the replication timing of a specific BAC clone and the standard clones, and found that at least one replication origin exists within the genomic region covered by its BAC clone as an example.

Mapping of an origin of DNA replication in the promoter of fragile X gene FMR1

An origin of bidirectional DNA replication was mapped to the promoter of the FMR1 gene in human chromosome Xq27.3, which has been linked to the fragile X syndrome. This origin is adjacent to a CpG island and overlaps the site of expansion of the triplet repeat (CGG) at the fragile X instability site, FRAXA. The promoter region of FMR2 in the FRAXE site (approximately 600 kb away, in chromosome band Xq28) also includes an origin of replication, as previously described [Chastain II, P.D., Cohen, S.M., Brylawski, B.P., Cordeiro-Stone, M., Kaufman, D.G., 2006. A late origin of DNA replication in the trinucleotide repeat region of the human FMR2 gene. Cell Cycle 5, 869-872]. FMR1 transcripts were detected in foreskin and male fetal lung fibroblasts, while FMR2 transcripts were not. However, both FMR1 and FMR2 were found to replicate late in S phase (approximately 6 h into the S phase of normal human fibroblasts). The position of the origin of replication relative to the CGG repeat, and perhaps the late replication of these genes, might be important factors in the susceptibility to triplet repeat amplification at the FRAXA and FRAXE sites.

Uncoupling global and fine-tuning replication timing determinants for mouse pericentric heterochromatin

Mouse chromocenters are clusters of late-replicating pericentric heterochromatin containing HP1 bound to trimethylated lysine 9 of histone H3 (Me₃K9H3). Using a cell-free system to initiate replication within G1-phase nuclei, we demonstrate that chromocenters acquire the property of late replication coincident with their reorganization after mitosis and the establishment of a global replication timing program. HP1 dissociated during mitosis but rebound before the establishment of late replication, and removing HP1 from chromocenters by competition with Me₃K9H3 peptides did not result in early replication, demonstrating that this interaction is neither necessary nor sufficient for late replication. However, in cells lacking the Suv39h1,2 methyltransferases responsible for K9H3 trimethylation and HP1 binding at chromocenters, replication of chromocenter DNA was advanced by 10–15% of the length of S phase. Reintroduction of Suv39h1 activity restored the later replication time. We conclude that Suv39 activity is required for the fine-tuning of pericentric heterochromatin replication relative to other late-replicating domains, whereas separate factors establish a global replication timing program during early G1 phase.

Eukaryotic DNA Replication in a Chromatin Context

There has been remarkable progress in the last 20 years in defining the molecular mechanisms that regulate initiation of DNA synthesis in eukaryotic cells. Replication origins in the DNA nucleate the ordered assembly of protein factors to form a prereplication complex (preRC) that is poised for DNA synthesis. Transition of the preRC to an active initiation complex is regulated by cyclin-dependent kinases and other signaling molecules, which promote further protein assembly and activate the mini chromosome maintenance helicase. We will review these mechanisms and describe the state of knowledge about the proteins involved. However, we will also consider an additional layer of complexity. The DNA in the cell is packaged with histone proteins into chromatin. Chromatin structure provides an additional layer of heritable information with associated epigenetic modifications. Thus, we will begin by describing chromatin structure, and how the cell generally controls access to the DNA. Access to the DNA requires active chromatin remodeling, specific histone modifications, and regulated histone deposition. Studies in transcription have revealed a variety of mechanisms that regulate DNA access, and some of these are likely to be shared with DNA replication. We will briefly describe heterochromatin as a model for an epigenetically inherited chromatin state. Next, we will describe the mechanisms of replication initiation and how these are affected by constraints of chromatin. Finally, chromatin must be reassembled with appropriate modifications following passage of the replication fork, and our third major topic will be the reassembly of chromatin and its associated epigenetic marks. Thus, in this chapter, we seek to bring together the studies of replication initiation and the studies of chromatin into a single holistic narrative.

Profiling of DNA replication timing in unsynchronized cell populations

Profiling chromatin in a particular cell type provides a valuable 'signature' for cell identity and developmental stage. One approach has been to assay and use the timing of DNA replication across a panel of loci as an indicator of chromatin structure. This epigenetic profiling used on pluripotent embryonic stem (ES) cells has reliably distinguished them from cells that have a more restricted lineage potential. Thus, such an approach may become increasingly useful for understanding the molecular basis of pluripotency and lineage induction, especially in the context of stem-cell therapy. Here I describe in detail the DNA replication timing method, whereby unsynchronized cell populations are pulse-labeled with 5-bromo-2'-deoxyuridine (BrdU), fractionated according to cell-cycle stage and the abundance of candidate sequences within newly replicated DNA is determined by PCR. This robust protocol has been used consistently by several laboratories and might offer some advantages over conventional transcription-based profiling for characterizing cell populations. The procedure requires 3-4 d to complete.