ATP Binding and Hydrolysis by Mcm2 Regulate DNA Binding by Mcm Complexes

The essential minichromosome maintenance (Mcm) proteins Mcm2 through Mcm7 likely comprise the replicative helicase in eukaryotes. In addition to Mcm2-7, other subcomplexes, including one comprising Mcm4, Mcm6, and Mcm7, unwind DNA. Using Mcm4/6/7 as a tool, we reveal a role for nucleotide binding by Saccharomyces cerevisiae Mcm2 in modulating DNA binding by Mcm complexes. Previous studies have shown that Mcm2 inhibits DNA unwinding by Mcm4/6/7. Here, we show that interaction of Mcm2 and Mcm4/6/7 is not sufficient for inhibition; rather, Mcm2 requires nucleotides for its regulatory role. An Mcm2 mutant that is defective for ATP hydrolysis (K549A), as well as ATP analogues, was used to show that ADP binding by Mcm2 is required to inhibit DNA binding and unwinding by Mcm4/6/7. This Mcm2-mediated regulation of Mcm4/6/7 is independent of Mcm3/5. Furthermore, the importance of ATP hydrolysis by Mcm2 to the regulation of the native complex was apparent from the altered DNA binding properties of Mcm2^KA-7. Moreover, together with the finding that Mcm2_K549A does not support yeast viability, these results indicate that the nucleotide-bound state of Mcm2 is critical in regulating the activities of Mcm4/6/7 and Mcm2-7 complexes.     

The Dbf4-Cdc7 Kinase Promotes Mcm2-7 Ring Opening to Allow for Single-stranded DNA Extrusion and Helicase Assembly

The replication fork helicase in eukaryotes is composed of Cdc45, Mcm2-7, and GINS (CMG). The Dbf4-Cdc7 kinase phosphorylates Mcm2 in vitro, but the in vivo role for Dbf4-Cdc7 phosphorylation of Mcm2 is unclear. We find that budding yeast Dbf4-Cdc7 phosphorylates Mcm2 in vivo under normal conditions during S phase. Inhibiting Dbf4-Cdc7 phosphorylation of Mcm2 confers a dominant-negative phenotype with a severe growth defect. Inhibiting Dbf4-Cdc7 phosphorylation of Mcm2 under wild-type expression conditions also results in impaired DNA replication, substantially decreased single-stranded formation at an origin, and markedly disrupted interaction between GINS and Mcm2-7 during S phase. In vitro, Dbf4-Cdc7 kinase (DDK) phosphorylation of Mcm2 substantially weakens the interaction between Mcm2 and Mcm5, and Dbf4-Cdc7 phosphorylation of Mcm2 promotes Mcm2-7 ring opening. The extrusion of ssDNA from the central channel of Mcm2-7 triggers GINS attachment to Mcm2-7. Thus, Dbf4-Cdc7 phosphorylation of Mcm2 may open the Mcm2-7 ring at the Mcm2-Mcm5 interface, allowing for single-stranded DNA extrusion and subsequent GINS assembly with Mcm2-7.     

Roles of Mcm7 and Mcm4 subunits in the DNA helicase activity of the mouse Mcm4/6/7 complex

Mcm, which is composed of six structurally related subunits (Mcm2-7), is essential for eukaryotic DNA replication. A subassembly of Mcm, the Mcm4/6/7 double-trimeric complex, possesses DNA helicase activity, and it has been proposed that Mcm may function as a replicative helicase at replication forks. We show here that conserved ATPase motifs of Mcm7 are essential for ATPase and DNA helicase activities of the Mcm4/6/7 complex. Because uncomplexed Mcm7 displayed neither ATPase nor DNA helicase activity, Mcm7 contributes to the DNA helicase activity of the Mcm complex through interaction with other subunits. In contrast, the Mcm4/6/7 complex containing a zinc finger mutant of Mcm4 with partially impaired DNA binding activity exhibited elevated DNA helicase activity. The Mcm4/6/7 complex containing this Mcm4 mutant tended to dissociate into trimeric complexes, suggesting that the zinc finger of Mcm4 is involved in subunit interactions of trimers. The Mcm4 mutants lacking the N-terminal 35 or 112 amino acids could form hexameric Mcm4/6/7 complexes, but displayed very little DNA helicase activity. In conjunction with the previously reported essential role of Mcm6 in ATP binding (You, Z., Komamura, Y., and Ishimi, Y. (1999) Mol. Cell. Biol. 19, 8003-8015), our data indicate distinct roles of Mcm4, Mcm6, and Mcm7 subunits in activation of the DNA helicase activity of the Mcm4/6/7 complex.     

Ciprofloxacin is an inhibitor of the Mcm2-7 replicative helicase

Most currently available small molecule inhibitors of DNA replication lack enzymatic specificity, resulting in deleterious side effects during use in cancer chemotherapy and limited experimental usefulness as mechanistic tools to study DNA replication. Towards development of targeted replication inhibitors, we have focused on Mcm2-7 (minichromosome maintenance protein 2–7), a highly conserved helicase and key regulatory component of eukaryotic DNA replication. Unexpectedly we found that the fluoroquinolone antibiotic ciprofloxacin preferentially inhibits Mcm2-7. Ciprofloxacin blocks the DNA helicase activity of Mcm2-7 at concentrations that have little effect on other tested helicases and prevents the proliferation of both yeast and human cells at concentrations similar to those that inhibit DNA unwinding. Moreover, a previously characterized mcm mutant (mcm4chaos3) exhibits increased ciprofloxacin resistance. To identify more potent Mcm2-7 inhibitors, we screened molecules that are structurally related to ciprofloxacin and identified several that compromise the Mcm2-7 helicase activity at lower concentrations. Our results indicate that ciprofloxacin targets Mcm2-7 in vitro, and support the feasibility of developing specific quinolone-based inhibitors of Mcm2-7 for therapeutic and experimental applications.     

Xenopus Mcm10 is a CDK-substrate required for replication fork stability

During S phase, following activation of the S phase CDKs and the DBF4-dependent kinases (DDK), double hexamers of Mcm2-7 at licensed replication origins are activated to form the core replicative helicase. Mcm10 is one of several proteins that have been implicated from work in yeasts to play a role in forming a mature replisome during the initiation process. Mcm10 has also been proposed to play a role in promoting replisome stability after initiation has taken place. The role of Mcm10 is particularly unclear in metazoans, where conflicting data has been presented. Here, we investigate the role and regulation of Mcm10 in Xenopus egg extracts. We show that Xenopus Mcm10 is recruited to chromatin late in the process of replication initiation and this requires prior action of DDKs and CDKs. We also provide evidence that Mcm10 is a CDK substrate but does not need to be phosphorylated in order to associate with chromatin. We show that in extracts depleted of more than 99% of Mcm10, the bulk of DNA replication still occurs, suggesting that Mcm10 is not required for the process of replication initiation. However, in extracts depleted of Mcm10, the replication fork elongation rate is reduced. Furthermore, the absence of Mcm10 or its phosphorylation by CDK results in instability of replisome proteins on DNA, which is particularly important under conditions of replication stress.     

The N-terminus of Mcm10 is important for interaction with the 9-1-1 clamp and in resistance to DNA damage

Accurate replication of the genome requires the evolutionarily conserved minichromosome maintenance protein, Mcm10. Although the details of the precise role of Mcm10 in DNA replication are still debated, it interacts with the Mcm2-7 core helicase, the lagging strand polymerase, DNA polymerase-α and the replication clamp, proliferating cell nuclear antigen. Loss of these interactions caused by the depletion of Mcm10 leads to chromosome breakage and cell cycle checkpoint activation. However, whether Mcm10 has an active role in DNA damage prevention is unknown. Here, we present data that establish a novel role of the N-terminus of Mcm10 in resisting DNA damage. We show that Mcm10 interacts with the Mec3 subunit of the 9-1-1 clamp in response to replication stress evoked by UV irradiation or nucleotide shortage. We map the interaction domain with Mec3 within the N-terminal region of Mcm10 and demonstrate that its truncation causes UV light sensitivity. This sensitivity is not further enhanced by a deletion of MEC3, arguing that MCM10 and MEC3 operate in the same pathway. Since Rad53 phosphorylation in response to UV light appears to be normal in N-terminally truncated mcm10 mutants, we propose that Mcm10 may have a role in replication fork restart or DNA repair.     

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.     

Selective role of the DNA helicase Mcm5 in BMP retrograde signaling during Drosophila neuronal differentiation

The MCM2-7 complex is a highly conserved hetero-hexameric protein complex, critical for DNA unwinding at the replicative fork during DNA replication. Overexpression or mutation in MCM2-7 genes is linked to and may drive several cancer types in humans. In mice, mutations in MCM2-7 genes result in growth retardation and mortality. All six MCM2-7 genes are also expressed in the developing mouse CNS, but their role in the CNS is not clear. Here, we use the central nervous system (CNS) of Drosophila melanogaster to begin addressing the role of the MCM complex during development, focusing on the specification of a well-studied neuropeptide expressing neuron: the Tv4/FMRFa neuron. In a search for genes involved in the specification of the Tv4/FMRFa neuron we identified Mcm5 and find that it plays a highly specific role in the specification of the Tv4/FMRFa neuron. We find that other components of the MCM2-7 complex phenocopies Mcm5, indicating that the role of Mcm5 in neuronal subtype specification involves the MCM2-7 complex. Surprisingly, we find no evidence of reduced progenitor proliferation, and instead find that Mcm5 is required for the expression of the type I BMP receptor Tkv, which is critical for the FMRFa expression. These results suggest that the MCM2-7 complex may play roles during CNS development outside of its well-established role during DNA replication.     

Human Mcm proteins at a replication origin during the G1 to S phase transition

Previous work with yeast cells and with Xenopus egg extracts had shown that eukaryotic pre-replication complexes assemble on chromatin in a step-wise manner whereby specific loading factors promote the recruitment of essential Mcm proteins at pre-bound origin recognition complexes (ORC with proteins Orc1p–Orc6p). While the order of assembly—Mcm binding follows ORC binding—seems to be conserved in cycling mammalian cells in culture, it has not been determined whether mammalian Mcm proteins associate with ORC-bearing chromatin sites. We have used a chromatin immunoprecipitation approach to investigate the site of Mcm binding in a genomic region that has previously been shown to contain an ORC-binding site and an origin of replication. Using chromatin from HeLa cells in G₁ phase, antibodies against Orc2p as well as antibodies against Mcm proteins specifically immunoprecipitate chromatin enriched for a DNA region that includes a replication origin. However, with chromatin from cells in S phase, only Orc2p-specific antibodies immunoprecipitate the origin-containing DNA region while Mcm-specific antibodies immunoprecipitate chromatin with DNA from all parts of the genomic region investigated. Thus, human Mcm proteins first assemble at or adjacent to bound ORC and move to other sites during genome replication.     

Molecular analysis of nutritional and hormonal regulation of female reproduction in the red flour beetle, Tribolium castaneum

Female reproduction includes maturation of oocytes and the synthesis of yolk proteins (vitellogenin, Vg) in the fat body and their deposition into the oocytes. Our recent studies showed that juvenile hormone (JH) regulates Vg synthesis and 20-hydroxyecdysone (20E) regulates oocyte maturation in the red flour beetle (Tribolium castaneum). Here, we report on the role of nutritional signaling on vitellogenesis and oogenesis. Comparison of gene expression between fed and starved beetles by microarray analysis showed the up-regulation of genes involved in energy homeostasis and down-regulation of genes involved in egg production in the starved beetles. The RNA interference (RNAi) aided knock-down in the expression of genes involved in insulin and TOR signaling pathways showed that both these signaling pathways play key roles in Vg synthesis and oocyte maturation. Starvation of female beetles resulted in a block in Vg synthesis but not in the progression of primary oocyte development to the resting stage. Feeding after starvation induced Vg synthesis and the progression of primary oocytes from the resting stage to the mature stage. However, in the beetles where JH or 20E synthesis or action was blocked by RNAi, both Vg synthesis and oocyte maturation were affected suggesting that both these hormones (JH and 20E) and nutritional signaling and their cross-talk regulate vitellogenesis and oogenesis.     

Ctf4p facilitates Mcm10p to promote DNA replication in budding yeast

Ctf4p (chromosome transmission fidelity) has been reported to function in DNA metabolism and sister chromatid cohesion in Saccharomyces cerevisiae. In this study, a ctf4^S143F mutant was isolated from a yeast genetic screen to identify replication-initiation proteins. The ctf4^S143F mutant exhibits plasmid maintenance defects which can be suppressed by the addition of multiple origins to the plasmid, like other known replication-initiation mutants. We show that both ctf4^S143F and ctf4Δ strains have defects in S phase entry and S phase progression at the restrictive temperature of 38 °C. Ctf4p localizes in the nucleus throughout the cell cycle but only starts to bind chromatin at the G1/S transition and then disassociates from chromatin after DNA replication. Furthermore, Ctf4p interacts with Mcm10p physically and genetically, and the chromatin association of Ctf4p depends on Mcm10p. Finally, deletion of CTF4 destabilizes Mcm10p and Pol α in both mcm10-1 and MCM10 cells. These data indicate that Ctf4p facilitates Mcm10p to promote the DNA replication.     

Mapping ubiquitination sites of S. cerevisiae Mcm10

Minichromosome maintenance protein (Mcm) 10 is a part of the eukaryotic replication machinery and highly conserved throughout evolution. As a multivalent DNA scaffold, Mcm10 coordinates the action of proteins that are indispensable for lagging strand synthesis, such as the replication clamp, proliferating cell nuclear antigen (PCNA). The binding between Mcm10 and PCNA serves an essential function during DNA elongation and is mediated by the ubiquitination of Mcm10. Here we map lysine 372 as the primary attachment site for ubiquitin on S. cerevisiae Mcm10. Moreover, we identify five additional lysines that can be ubiquitinated. Mutation of lysine 372 to arginine ablates ubiquitination of overexpressed protein and causes sensitivity to the replication inhibitor hydroxyurea in cells that are S-phase checkpoint compromised. Together, these findings reveal the high selectivity of the ubiquitination machinery that targets Mcm10 and that ubiquitination has a role in suppressing replication stress.     

Mcm10 Self-Association Is Mediated by an N-Terminal Coiled-Coil Domain

Minichromosome maintenance protein 10 (Mcm10) is an essential eukaryotic DNA-binding replication factor thought to serve as a scaffold to coordinate enzymatic activities within the replisome. Mcm10 appears to function as an oligomer rather than in its monomeric form (or rather than as a monomer). However, various orthologs have been found to contain 1, 2, 3, 4, or 6 subunits and thus, this issue has remained controversial. Here, we show that self-association of Xenopus laevis Mcm10 is mediated by a conserved coiled-coil (CC) motif within the N-terminal domain (NTD). Crystallographic analysis of the CC at 2.4 Å resolution revealed a three-helix bundle, consistent with the formation of both dimeric and trimeric Mcm10 CCs in solution. Mutation of the side chains at the subunit interface disrupted in vitro dimerization of both the CC and the NTD as monitored by analytical ultracentrifugation. In addition, the same mutations also impeded self-interaction of the full-length protein in vivo, as measured by yeast-two hybrid assays. We conclude that Mcm10 likely forms dimers or trimers to promote its diverse functions during DNA replication.     

Mcm10 Mediates the Interaction Between DNA Replication and Silencing Machineries

The connection between DNA replication and heterochromatic silencing in yeast has been a topic of investigation for >20 years. While early studies showed that silencing requires passage through S phase and implicated several DNA replication factors in silencing, later works showed that silent chromatin could form without DNA replication. In this study we show that members of the replicative helicase (Mcm3 and Mcm7) play a role in silencing and physically interact with the essential silencing factor, Sir2, even in the absence of DNA replication. Another replication factor, Mcm10, mediates the interaction between these replication and silencing proteins via a short C-terminal domain. Mutations in this region of Mcm10 disrupt the interaction between Sir2 and several of the Mcm2–7 proteins. While such mutations caused silencing defects, they did not cause DNA replication defects or affect the association of Sir2 with chromatin. Our findings suggest that Mcm10 is required for the coupling of the replication and silencing machineries to silence chromatin in a context outside of DNA replication beyond the recruitment and spreading of Sir2 on chromatin.     

The human homolog of Saccharomyces cerevisiae Mcm10 interacts with replication factors and dissociates from nuclease-resistant nuclear structures in G(2) phase

Mcm10 (Dna43), first identified in Saccharomyces cerevisiae, is an essential protein which functions in the initiation of DNA synthesis. Mcm10 is a nuclear protein that is localized to replication origins and mediates the interaction of the Mcm2–7 complex with replication origins. We identified and cloned a human cDNA whose product was structurally homologous to the yeast Mcm10 protein. Human Mcm10 (HsMcm10) is a 98-kDa protein of 874 amino acids which shows 23 and 21% overall similarity to Schizosaccharomyces pombe Cdc23 and S.cerevisiae Mcm10, respectively. The messenger RNA level of HsMcm10 increased at the G₁/S-boundary when quiescent human NB1–RGB cells were induced to proliferate as is the case of many replication factors. HsMcm10 associated with nuclease-resistant nuclear structures throughout S phase and dissociated from it in G₂ phase. HsMcm10 associated with human Orc2 protein when overexpressed in COS-1 cells. HsMcm10 also interacted with Orc2, Mcm2 and Mcm6 proteins in the yeast two-hybrid system. These results suggest that HsMcm10 may function in DNA replication through the interaction with Orc and Mcm2–7 complexes.