Novel DNA Binding Properties of the Mcm10 Protein from Saccharomyces cerevisiae

The Mcm10 protein is essential for chromosomal DNA replication in eukaryotic cells. We purified the Saccharomyces cerevisiae Mcm10 (ScMcm10) and characterized its DNA binding properties. Electrophoretic mobility shift assays and surface plasmon resonance analysis showed that ScMcm10 binds stably to both double strand (ds) DNA and single strand (ss) DNA. On short DNA templates of 25 or 50 bp, surface plasmon resonance analysis showed a ∼1:1 stoichiometry of ScMcm10 to dsDNA. On longer dsDNA templates, however, multiple copies of ScMcm10 cooperated in the rapid assembly of a large, stable nucleoprotein complex. The amount of protein bound was directly proportional to the length of the DNA, with an average occupancy spacing of 21–24 bp. This tight spacing is consistent with a nucleoprotein structure in which ScMcm10 is aligned along the helical axis of the dsDNA. In contrast, the stoichiometry of ScMcm10 bound to ssDNA of 20–50 nucleotides was ∼3:1 suggesting that interaction with ssDNA induces the assembly of a multisubunit ScMcm10 complex composed of at least three subunits. The tight packing of ScMcm10 on dsDNA and the assembly of a multisubunit complex on ssDNA suggests that, in addition to protein-DNA, protein-protein interactions may be involved in forming the nucleoprotein complex. We propose that these DNA binding properties have an important role in (i) initiation of DNA replication and (ii) formation and maintenance of a stable replication fork during the elongation phase of chromosomal DNA replication.MCM10 is a ubiquitous, conserved gene essential for DNA replication in eukaryotes. It was first discovered in yeast genetic screens designed to detect mutants defective in DNA synthesis and minichromosome maintenance (1, 2). In vivo, Mcm10 associates with chromatin and chromosomal replication origins in human cells (hMcm10), Xenopus laevis (XMcm10), Schizosaccharomyces pombe (SpMcm10), and Saccharomyces cerevisiae (ScMcm10) (3–6). In S. cerevisiae, initiation of chromosomal replication occurs at multiple specific sites known as autonomously replicating sequences (ARSs)² (7). Mutations in MCM10 enhance the loss rate of plasmids bearing specific ARSs (8), suggesting a function for ScMcm10 in initiation.In eukaryotic systems replication initiation is a cell cycle-regulated process characterized by a multistep sequential loading of ORC, Cdc6, Cdt1, and the Mcm2–7 complex onto the origin in G₁ to form the pre-RC complex. Binding of ORC, Cdc6p, and Cdt1p to chromatin is a prerequisite for the recruitment of Mcm2–7 (9, 10). The next step in the assembly of the initiation replication apparatus in S. cerevisiae involves protein kinases (Cdc28 and Cdc7/Dbf4), and recruitment of Mcm10, Cdc45, and the GINS complex. The mechanism for targeting Mcm10 to replications origins is unknown. However, recent studies in S. cerevisiae have shown that Mcm10 and Mcm2–7 physically interact (6, 11). It is now believed that in late G₁, chromatin-bound Mcm2–7 is responsible for the recruitment of Mcm10 presumably via protein-protein interactions (12). Prior studies in the Xenopus laevis system reached similar conclusions (4). Additional interactions of Mcm10 with other components of the pre-RC cannot be excluded (13).A key step in the initiation of replication is the local melting of an origin DNA sequence, which occurs at the G₁/S transition and throughout the S phase. The mechanism of this essential DNA-melting process is not understood. There is no evidence in S. cerevisiae that the assembled pre-RC complex leads to the melting of an origin DNA sequence. This unwinding may occur only following the recruitment of Mcm10, raising the possibility that Mcm10 is a key component of the initiation machinery responsible for this process. Results of a study in the Xenopus egg extract system (4), which showed that omission of XMcm10 blocks unwinding of plasmid DNA and initiation of DNA replication, are consistent with this notion. An additional function of Mcm10 in initiation is in the recruitment of Cdc45 to replication origins, presumably via Mcm10-Cdc45 physical interactions (5, 14). Cdc45 is believed to be important for the activation of replication origins and the assembly of the replication elongation complex (15). Upon initiation of DNA replication, ScMcm10 moves from the origin to origin-proximal sequences suggesting that ScMcm10 associates with moving replication forks (12) and is consistent with the observation that elevated temperatures cause pausing of replication forks in a mcm10-1 ts mutant (8). Both ScMcm10 and SpMcm10 interact with DNA polymerase α supporting the notion that replication fork movement requires Mcm10. ScMcm10 and polymerase α form a complex on and off the DNA in vivo (12). In S. pombe, SpMcm10 stimulates the activity of polymerase α in vitro and associates with a primase activity (16, 17) that has not been reported in other eukaryotes (18).Previous studies with Mcm10 in other systems showed that Mcm10 binds DNA. Using a filter binding assay Fien and Hurwitz (16) reported that SpMcm10 from S. pombe binds well to ssDNA but barely interacts (20-fold lower affinity) with dsDNA. It has been suggested that binding of SpMcm10 to ssDNA is important for the recruitment of polymerase α (16). Recently, it has been reported that a DNA binding activity is also associated with XMcm10 protein from X. laevis. Measurements of fluorescence anisotropy were used to show binding of XMcm10 to short, 25-nucleotide-long oligonucleotides (18). These studies have shown that XMcm10 has similar affinities for ssDNA and dsDNA. Unlike SpMcm10, which harbors a single DNA-binding domain in the N-terminal half of the protein, XMcm10 seems to contain two distinct domains for binding DNA. The biological implication of having two DNA-binding domains is not clear.It appears that there are differences in the quaternary structure of Mcm10 from different organisms. Although SpMcm10 and XMcm10 may be a homodimer in solution (17, 18), a recent electron microscopy study suggested that human hMcm10 has a hexameric ring structure (19). The same study reported that hMcm10 interacts with ssDNA but failed to bind dsDNA. The differences in structure and DNA binding properties may reflect differences in the function of Mcm10 in various organisms as well as in the protein preparations.Here we report, for the first time, the characterization of the DNA binding properties of purified Mcm10 from S. cerevisiae. We show that ScMcm10 forms a stable complex with dsDNA and ssDNA. In addition, we demonstrate that dsDNA longer than 50 bp sustains oligomerization of ScMcm10. The number of ScMcm10 molecules bound is directly proportional to the size of the dsDNA, suggesting that ScMcm10 is tightly packed on the dsDNA, perhaps in a head to tail oligomeric structure. In contrast to a 25-bp-long dsDNA, which supports the binding of a single copy of ScMcm10, ssDNA containing only 20 nucleotides may sustain binding of as many as three copies of ScMcm10, suggesting that a ScMcm10 complex composed of at least 3 subunits assembles on ssDNA. We believe that these distinct binding properties to dsDNA and ssDNA are important for the ScMcm10 functions in initiation, formation of replication forks, and the maintenance of replication fork progression during chromosomal DNA replication.