Analysis on origin recognition complex containing Orc5p with defective Walker A motif

Orc5p is one of six proteins that make up the origin recognition complex (ORC), a candidate initiator of chromosomal DNA replication in eukaryotes. To investigate the role of ATP binding to Orc5p in cells, we constructed orc5-A, a strain of Saccharomyces cerevisiae having a mutation in the Walker A motif of Orc5p (K43E). The strain showed temperature-sensitive growth. Incubation at a nonpermissive temperature (37 degrees C) caused accumulation of cells with nearly 2C DNA content. Overproduction of Orc4p, another subunit of ORC, suppresses this temperature sensitivity, but overproduction of other subunits did not. Overproduction of Orc4p did not suppress the temperature sensitivity of another orc5 mutant, orc5-1, whose mutation, L331P, is outside the ATP-binding motif. These results suggest that Orc4p is specifically involved in ATP binding to Orc5p itself or its function in DNA replication. Immunoblotting experiments revealed that in the orc5-A strain at a nonpermissive temperature, all ORC subunits gradually disappeared, suggesting that ORC5-A becomes degraded at nonpermissive temperatures. We therefore consider that ATP binding to Orc5p is involved in efficient ORC formation and that Orc4p is involved in this process.     

Mechanism for the degradation of origin recognition complex containing Orc5p with a defective Walker A motif and its suppression by over-production of Orc4p in yeast cells

Orc5p is one of six subunits constituting the ORC (origin recognition complex), a possible initiator of chromosomal DNA replication in eukaryotes. Orc5p contains a Walker A motif. We recently reported that a strain of Saccharomyces cerevisiae having a mutation in Orc5p's Walker A motif (orc5-A), showed cell-cycle arrest at G2/M and degradation of ORC at high temperatures (37 degrees C). Over-production of Orc4p, another subunit of ORC, specifically suppressed these phenotypes [Takahashi, Yamaguchi, Yamairi, Makise, Takenaka, Tsuchiya and Mizushima (2004) J. Biol. Chem. 279, 8469-8477]. In the present study, we examined the mechanisms of ORC degradation and of its suppression by Orc4p over-production. In orc5-A, at high temperatures, ORC is degraded by proteasomes; either addition of a proteasome inhibitor, or introduction of a mutation of either tan1-1 or nob1-4 that inhibits proteasomes, prevented ORC degradation. Introduction of the tan1-1 mutation restored cell cycle progression, suggesting that the defect was due to ORC degradation by proteasomes. Yeast two-hybrid and co-immunoprecipitation analyses suggested that Orc5p interacts preferentially with Orc4p and that the orc5-A mutation diminishes this interaction. We suggest that this interaction is mediated by the C-terminal region of Orc4p, and the N-terminal region of Orc5p. Based on these observations, we consider that ATP binding to Orc5p is required for efficient interaction with Orc4p and that, in orc5-A, loss of this interaction at higher temperatures allows proteasomes to degrade ORC, causing growth defects. This model could also explain why over-production of Orc4p suppresses the orc5-A strain's phenotype.     

The origin recognition complex in silencing, cell cycle progression, and DNA replication.

This report describes the isolation of ORC5, the gene encoding the fifth largest subunit of the origin recognition complex, and the properties of mutants with a defective allele of ORC5. The orc5-1 mutation caused temperature-sensitive growth and, at the restrictive temperature, caused cell cycle arrest. At the permissive temperature, the orc5-1 mutation caused an elevated plasmid loss rate that could be suppressed by additional tandem origins of DNA replication. The sequence of ORC5 revealed a potential ATP binding site, making Orc5p a candidate for a subunit that mediates the ATP-dependent binding of ORC to origins. Genetic interactions among orc2-1 and orc5-1 and other cell cycle genes provided further evidence for a role for the origin recognition complex (ORC) in DNA replication. The silencing defect caused by orc5-1 strengthened previous connections between ORC and silencing, and combined with the phenotypes caused by orc2 mutations, suggested that the complex itself functions in both processes.     

An essential role for Orc6 in DNA replication through maintenance of pre-replicative complexes

The heterohexameric origin recognition complex (ORC) acts as a scaffold for the G(1) phase assembly of pre-replicative complexes (pre-RC). Only the Orc1-5 subunits appear to be required for origin binding in budding yeast, yet Orc6 is an essential protein for cell proliferation. Imaging of Orc6-YFP in live cells revealed a punctate pattern consistent with the organization of replication origins into subnuclear foci. Orc6 was not detected at the site of division between mother and daughter cells, in contrast to observations for metazoans, and is not required for mitosis or cytokinesis. An essential role for Orc6 in DNA replication was identified by depleting it at specific cell cycle stages. Interestingly, Orc6 was required for entry into S phase after pre-RC formation, in contrast to previous models suggesting ORC is dispensable at this point in the cell cycle. When Orc6 was depleted in late G(1), Mcm2 and Mcm10 were displaced from chromatin, cells failed to progress through S phase, and DNA combing analysis following bromodeoxyuridine incorporation revealed that the efficiency of replication origin firing was severely compromised.     

Dynamic association of ORCA with prereplicative complex components regulates DNA replication initiation

In eukaryotes, initiation of DNA replication requires the assembly of a multiprotein prereplicative complex (pre-RC) at the origins. We recently reported that a WD repeat-containing protein, origin recognition complex (ORC)-associated (ORCA/LRWD1), plays a crucial role in stabilizing ORC to chromatin. Here, we find that ORCA is required for the G(1)-to-S-phase transition in human cells. In addition to binding to ORC, ORCA associates with Cdt1 and its inhibitor, geminin. Single-molecule pulldown experiments demonstrate that each molecule of ORCA can bind to one molecule of ORC, one molecule of Cdt1, and two molecules of geminin. Further, ORCA directly interacts with the N terminus of Orc2, and the stability of ORCA is dependent on its association with Orc2. ORCA associates with Orc2 throughout the cell cycle, with Cdt1 during mitosis and G(1), and with geminin in post-G(1) cells. Overexpression of geminin results in the loss of interaction between ORCA and Cdt1, suggesting that increased levels of geminin in post-G(1) cells titrate Cdt1 away from ORCA. We propose that the dynamic association of ORCA with pre-RC components modulates the assembly of its interacting partners on chromatin and facilitates DNA replication initiation.     

Genome based identification and analysis of the pre-replicative complex of Arabidopsis thaliana

Eukaryotic DNA replication requires an ordered and regulated machinery to control G1/S transition. The formation of the pre-replicative complex (pre-RC) is a key step involved in licensing DNA for replication. Here, we identify all putative components of the full pre-RC in the genome of the model plant Arabidopsis thaliana. Different from the other eukaryotes, Arabidopsis houses in its genome two putative homologs of ORC1, CDC6 and CDT1. Two mRNA variants of AtORC4 subunit, with different temporal expression patterns, were also identified. Two-hybrid binary interaction assays suggest a primary architectural organization of the Arabidopsis ORC, in which AtORC3 plays a central role in maintaining the complex associations. Expression profiles differ among pre-RC components suggesting the existence of various forms of the complex, possibly playing different roles during development. In addition, the expression of the putative pre-RC genes in non-proliferating plant tissues suggests that they might have roles in processes other than DNA replication licensing.     

ATP hydrolysis by ORC catalyzes reiterative Mcm2-7 assembly at a defined origin of replication

The origin recognition complex (ORC) is a six-subunit, ATP-regulated, DNA binding protein that is required for the formation of the prereplicative complex (pre-RC), an essential replication intermediate formed at each origin of DNA replication. In this study, we investigate the mechanism of ORC function during pre-RC formation and how ATP influences this event. We demonstrate that ATP hydrolysis by ORC requires the coordinate function of the Orc1 and Orc4 subunits. Mutations that eliminate ORC ATP hydrolysis do not support cell viability and show defects in pre-RC formation. Pre-RC formation involves reiterative loading of the putative replicative helicase, Mcm2-7, at the origin. Importantly, preventing ORC ATP hydrolysis inhibits this repeated Mcm2-7 loading. Our findings indicate that ORC is part of a helicase-loading molecular machine that repeatedly assembles Mcm2-7 complexes onto origin DNA and suggest that the assembly of multiple Mcm2-7 complexes plays a critical role in origin function.     

Interaction between ORC and Cdt1p of Saccharomyces cerevisiae

Origin recognition complex (ORC), a six-protein complex, is the most likely initiator of chromosomal DNA replication in eukaryotes. Throughout the cell cycle, ORC binds to chromatin at origins of DNA replication and functions as a 'landing pad' for the binding of other proteins, including Cdt1p, to form a prereplicative complex. In this study, we used yeast two-hybrid analysis to examine the interaction between Cdt1p and every ORC subunit. We observed potent interaction with Orc6p, and weaker interaction with Orc2p and Orc5p. Coimmunoprecipitation assay confirmed that Cdt1p interacted with Orc6p, as well as with Orc1p and Orc2p. We mapped the C-terminal region, and a middle region of Orc6p (amino acids residues 394-435, and 121-175, respectively), as important for interaction with Cdt1p. Cdt1p was purified to examine its direct interaction with ORC, and its effect on the activity of ORC. Glutathione-S-transferase pull-down analysis revealed that Cdt1p binds directly to ORC. Cdt1p neither bound to origin DNA and ATP nor affected ORC-binding to origin DNA and ATP. These results suggest that interaction of Cdt1p with ORC is involved in the formation of the prereplicative complex, rather than in regulation of the activity of ORC.     

ATP-dependent Pre-replicative Complex Assembly Is Facilitated by Adk1p in Budding Yeast

Pre-replicative complex (pre-RC) assembly is a critical part of the mechanism that controls the initiation of DNA replication, and ATP binding and hydrolysis by multiple pre-RC proteins are essential for pre-RC assembly and activation. Here, we demonstrate that Adk1p (adenylate kinase 1 protein) plays an important role in pre-RC assembly in Saccharomyces cerevisiae. Isolated from a genetic screen, adk1^G20S cells with a mutation within the nucleotide-binding site were defective in replication initiation. adk1Δ cells were viable at 25 °C but not at 37°C. Flow cytometry indicated that both the adk1-td (temperature-inducible degron) and adk1^G20S mutants were defective in S phase entry. Furthermore, Adk1p bound to chromatin throughout the cell cycle and physically interacted with Orc3p, whereas the Adk1^G20S protein had a reduced ability to bind chromatin and Orc3p without affecting the cellular ATP level. In addition, Adk1p associated with replication origins by ChIP assay. Finally, Adk1-td protein depletion prevented pre-RC assembly during the M-to-G₁ transition. We suggest that Adk1p regulates ATP metabolism on pre-RC proteins to promote pre-RC assembly and activation.     

Site-specific interaction of the murine pre-replicative complex with origin DNA: assembly and disassembly during cell cycle transit and differentiation

Eukaryotic DNA replication initiates at origins of replication by the assembly of the highly conserved pre-replicative complex (pre-RC). However, exact sequences for pre-RC binding still remain unknown. By chromatin immunoprecipitation we identified in vivo a pre-RC-binding site within the origin of bidirectional replication in the murine rDNA locus. At this sequence, ORC1, -2, -4 and -5 are bound in G1 phase and at the G1/S transition. During S phase, ORC1 is released. An ATP-dependent and site-specific assembly of the pre-RC at origin DNA was demonstrated in vitro using partially purified murine pre-RC proteins in electrophoretic mobility shift assays. By deletion experiments the sequence required for pre-RC binding was confined to 119 bp. Nucleotide substitutions revealed that two 9 bp sequence elements, CTCGGGAGA, are essential for the binding of pre-RC proteins to origin DNA within the murine rDNA locus. During myogenic differentiation of C2C12 cells, we demonstrated a reduction of ORC1 and ORC2 by immunoblot analyses. ChIP analyses revealed that ORC1 completely disappears from chromatin of terminally differentiated myotubes, whereas ORC2, -4 and -5 still remain associated.     

Characterization of an essential Orc2p-associated factor that plays a role in DNA replication.

The Saccharomyces cerevisiae Orc2 protein is a subunit of the origin recognition complex, ORC, which binds in a sequence-specific manner to yeast origins of DNA replication. With screens for orc2-1 synthetic lethal mutations and Orc2p two-hybrid interactors, a novel Orc2p-associated factor (Oaf1p) was identified. OAF1 is essential, its gene product is localized to the nucleus, and an oaf1 temperature-sensitive mutant arrests as large budded cells with a single nucleus. The mutant oaf1-2, isolated in the synthetic lethal screen, loses plasmids containing a single origin of DNA replication at a high rate, but it maintains plasmids carrying multiple potential origins of DNA replication. In addition, the OAF1 gene product tagged with the hemagglutinin antigen epitope binds to a DNA affinity column containing covalently linked tandem repeats of an essential origin element. These results suggest a role for OAFI in the initiation of DNA replication. Mutant alleles of cdc7 and cdc14 were also isolated in the orc2-1 synthetic lethal screen. Cdc7p, like Oaf1p, also interacts with Orc2p in two-hybrid assays.     

Dependence of ORC silencing function on NatA-mediated Nalpha acetylation in Saccharomyces cerevisiae

N(alpha) acetylation is one of the most abundant protein modifications in eukaryotes and is catalyzed by N-terminal acetyltransferases (NATs). NatA, the major NAT in Saccharomyces cerevisiae, consists of the subunits Nat1p, Ard1p, and Nat5p and is necessary for the assembly of repressive chromatin structures. Here, we found that Orc1p, the large subunit of the origin recognition complex (ORC), required NatA acetylation for its role in telomeric silencing. NatA functioned genetically through the ORC binding site of the HMR-E silencer. Furthermore, tethering Orc1p directly to the silencer circumvented the requirement for NatA in silencing. Orc1p was N(alpha) acetylated in vivo by NatA. Mutations that abrogated its ability to be acetylated caused strong telomeric derepression. Thus, N(alpha) acetylation of Orc1p represents a protein modification that modulates chromatin function in S. cerevisiae. Genetic evidence further supported a functional link between NatA and ORC: (i) nat1Delta was synthetically lethal with orc2-1 and (ii) the synthetic lethality between nat1Delta and SUM1-1 required the Orc1 N terminus. We also found Sir3p to be acetylated by NatA. In summary, we propose a model by which N(alpha) acetylation is required for the binding of silencing factors to the N terminus of Orc1p and Sir3p to recruit heterochromatic factors and establish repression.     

Genetic analysis of human Orc2 reveals specific domains that are required in vivo for assembly and nuclear localization of the origin recognition complex

Eukaryotic DNA replication begins with the binding of a six subunit origin recognition complex (ORC) to DNA. To study the assembly and function of mammalian ORC proteins in their native environment, HeLa cells were constructed that constitutively expressed an epitope-tagged, recombinant human Orc2 subunit that had been genetically altered. Analysis of these cell lines revealed that Orc2 contains a single ORC assembly domain that is required in vivo for interaction with all other ORC subunits, as well as two nuclear localization signals (NLSs) that are required for ORC accumulation in the nucleus. The recombinant Orc2 existed in the nucleus either as an ORC-(2-5) or ORC-(1-5) complex; no other combinations of ORC subunits were detected. Moreover, only ORC-(1-5) was bound to the chromatin fraction, suggesting that Orc1 is required in vivo to load ORC-(2-5) onto chromatin. Surprisingly, recombinant Orc2 suppressed expression of endogenous Orc2, revealing that mammalian cells limit the intracellular level of Orc2, and thereby limit the amount of ORC-(2-5) in the nucleus. Because this suppression required only the ORC assembly and NLS domains, these domains appear to constitute the functional domain of Orc2.     

Yeast two-hybrid analysis of the origin recognition complex of Saccharomyces cerevisiae: interaction between subunits and identification of binding proteins

Origin recognition complex (ORC), a six-protein complex (Orc1p-6p), is the most likely initiator of chromosomal DNA replication in eukaryotes. Although ORC of Saccharomyces cerevisiae has been studied extensively from biochemical and genetic perspectives, its quaternary structure remains unknown. Previous studies suggested that ORC has functions other than DNA replication, such as gene silencing, but the molecular mechanisms of these functions have not been determined. In this study, we used yeast two-hybrid analysis to examine the interaction between ORC subunits and to search for ORC-binding proteins. As well as the known Orc4p-Orc5p interaction, we revealed strong interactions between Orc2p and Ord3p (2p-3p), Orc2p and Ord5p (2p-5p), Orc2p and Ord6p (2p-6p) and Orc3p and Ord6p (3p-6p) and weaker interactions between Orc1p and Ord4p (1p-4p), Orc3p and Ord4p (3p-4p), Orc2p and Ord3p (3p-5p) and Orc5p and Ord3p (5p-6p). These results suggest that 2p-3p-6p may form a core complex. Orc2p and Orc6p are phosphorylated in vivo, regulating initiation of DNA replication. However, replacing the phosphorylated amino acid residues with others that cannot be phosphorylated, or that mimic phosphorylation, did not affect subunit interactions. We also identified several proteins that interact with ORC subunits; Sir4p and Mad1p interact with Orc2p; Cac1p and Ykr077wp with Orc3p; Rrm3p and Swi6p with Orc5p; and Mih1p with Orc6p. We discuss roles of these interactions in functions of ORC.     

Interactions and subcellular distribution of DNA replication initiation proteins in eukaryotic cells

For initiation of eukaryotic DNA replication the origin recognition complex (ORC) associates with chromatin sites and constitutes a landing pad allowing Cdc6, Cdt1 and MCM proteins to accomplish the pre-replication complex (pre-RC). In S phase, the putative MCM helicase is assumed to move away from the ORC to trigger DNA unwinding. By using the fluorescence-based assays bioluminescence resonance energy transfer (BRET) and bimolecular fluorescence complementation (BiFC) we show in live mammalian cells that one key interaction in pre-RC assembly, the interaction between Orc2 and Orc3, is not restricted to the nucleus but also occurs in the cytoplasm. BRET assays also revealed a direct interaction between Orc2 and nuclear localization signal (NLS)-depleted Orc3. Further, we assessed the subcellular distribution of Orc2 and Orc3 in relation to MCM proteins Mcm3 and Mcm6 as well as to a key protein involved in elongation of DNA replication, proliferating nuclear cell antigen (PCNA). Our findings illustrate the spatial complexity of the elaborated process of DNA replication as well as that the BRET and BiFC techniques are novel tools that could contribute to our understanding of the processes at the very beginning of the duplication of the genome.     

Analysis of mutant origin recognition complex with reduced ATPase activity in vivo and in vitro

In eukaryotes, ORC (origin recognition complex), a six-protein complex, is the most likely initiator of chromosomal DNA replication. ORC belongs to the AAA(+) (ATPases associated with a variety of cellular activities) family of proteins and has intrinsic ATPase activity derived from Orc1p, one of its subunits. To reveal the role of this ATPase activity in Saccharomyces cerevisiae (baker's yeast) ORC, we mutated the Orc1p sensor 1 and sensor 2 regions, which are important for ATPase activity in AAA(+) proteins. Plasmid-shuffling analysis revealed that Asn(600), Arg(694) and Arg(704) are essential for the function of Orc1p. In yeast cells, overexpression of Orc1R694Ep inhibited growth, caused inefficient loading of MCM (mini-chromosome maintenance complex of proteins) and slowed the progression of S phase. In vitro, purified ORC-1R [ORC with Orc1R694Ep (Orc1p Arg(694)-->Glu mutant)] has decreased ATPase activity in the presence or absence of origin DNA. However, other activities (ATP binding and origin DNA binding) were indistinguishable from those of wild-type ORC. The present study showed that Arg(694) of the Orc1p subunit is important for the ATPase activity of ORC and suggests that this ATPase activity is required for efficient MCM loading on to origin DNA and for progression of S phase.     

The BAH domain facilitates the ability of human Orc1 protein to activate replication origins in vivo

Selection of initiation sites for DNA replication in eukaryotes is determined by the interaction between the origin recognition complex (ORC) and genomic DNA. In mammalian cells, this interaction appears to be regulated by Orc1, the only ORC subunit that contains a bromo-adjacent homology (BAH) domain. Since BAH domains mediate protein-protein interactions, the human Orc1 BAH domain was mutated, and the mutant proteins expressed in human cells to determine their affects on ORC function. The BAH domain was not required for nuclear localization of Orc1, association of Orc1 with other ORC subunits, or selective degradation of Orc1 during S-phase. It did, however, facilitate reassociation of Orc1 with chromosomes during the M to G1-phase transition, and it was required for binding Orc1 to the Epstein-Barr virus oriP and stimulating oriP-dependent plasmid DNA replication. Moreover, the BAH domain affected Orc1's ability to promote binding of Orc2 to chromatin as cells exit mitosis. Thus, the BAH domain in human Orc1 facilitates its ability to activate replication origins in vivo by promoting association of ORC with chromatin.     

Separable Functions of Orc5 in Replication Initiation and Silencing in Saccharomyces Cerevisiae

Origin recognition complex (ORC) is a six subunit complex that functions as the replication initiator and is required for silencing the HML and HMR loci in the yeast Saccharomyces cerevisiae. The roles of ORC5 in replication initiation and silencing were investigated to determine whether the two roles were mechanistically coincident or separable. Some spontaneous revertants of orc5-1 were functional for replication initiation, but not silencing. Other alleles of ORC5 were obtained that were nonfunctional for replication initiation, but fully competent for silencing. The two types of alleles, when put in the same cell, complemented, establishing two separable functions for ORC5. These data implied that replication initiation at HMR-E was not required for silencing. The data were consistent with a model in which different ORC species functioned at different origins within the genome and that only one Orc5p subunit functioned at any given origin.