The origin recognition complex in human diseases

ORC (origin recognition complex) serves as the initiator for the assembly of the pre-RC (pre-replication complex) and the subsequent DNA replication. Together with many of its non-replication functions, ORC is a pivotal regulator of various cellular processes. Notably, a number of reports connect ORC to numerous human diseases, including MGS (Meier–Gorlin syndrome), EBV (Epstein–Barr virus)-infected diseases, American trypanosomiasis and African trypanosomiasis. However, much of the underlying molecular mechanism remains unclear. In those genetic diseases, mutations in ORC alter its function and lead to the dysregulated phenotypes; whereas in some pathogen-induced symptoms, host ORC and archaeal-like ORC are exploited by these organisms to maintain their own genomes. In this review, I provide detailed examples of ORC-related human diseases, and summarize the current findings on how ORC is involved and/or dysregulated. I further discuss how these discoveries can be generalized as model systems, which can then be applied to elucidating other related diseases and revealing potential targets for developing effective therapies.     

Phosphorylation of ORC2 protein dissociates origin recognition complex from chromatin and replication origins

During the late M to the G(1) phase of the cell cycle, the origin recognition complex (ORC) binds to the replication origin, leading to the assembly of the prereplicative complex for subsequent initiation of eukaryotic chromosome replication. We found that the cell cycle-dependent phosphorylation of human ORC2, one of the six subunits of ORC, dissociates ORC2, -3, -4, and -5 (ORC2-5) subunits from chromatin and replication origins. Phosphorylation at Thr-116 and Thr-226 of ORC2 occurs by cyclin-dependent kinase during the S phase and is maintained until the M phase. Phosphorylation of ORC2 at Thr-116 and Thr-226 dissociated the ORC2-5 from chromatin. Consistent with this, the phosphomimetic ORC2 protein exhibited defective binding to replication origins as well as to chromatin, whereas the phosphodefective protein persisted in binding throughout the cell cycle. These results suggest that the phosphorylation of ORC2 dissociates ORC from chromatin and replication origins and inhibits binding of ORC to newly replicated DNA.     

Interaction and assembly of murine pre-replicative complex proteins in yeast and mouse cells

Eukaryotic cells coordinate chromosome duplication by the assembly of protein complexes at origins of DNA replication by sequential binding of member proteins of the origin recognition complex (ORC), CDC6, and minichromosome maintenance (MCM) proteins. These pre-replicative complexes (pre-RCs) are activated by cyclin-dependent kinases and DBF4/CDC7 kinase. Here, we carried out a comprehensive yeast two-hybrid screen to establish sequential interactions between two individual proteins of the mouse pre-RC that are probably required for the initiation of DNA replication. The studies revealed multiple interactions among ORC subunits and MCM proteins as well as interactions between individual ORC and MCM proteins. In particular CDC6 was found to bind strongly to ORC1 and ORC2, and to MCM7 proteins. DBF4 interacts with the subunits of ORC as well as with MCM proteins. It was also demonstrated that CDC7 binds to different ORC and MCM proteins. CDC45 interacts with ORC1 and ORC6, and weakly with MCM3, -6, and -7. The three subunits of the single-stranded DNA binding protein RPA show interactions with various ORC subunits as well as with several MCM proteins. The data obtained by yeast two-hybrid analysis were paradigmatically confirmed in synchronized murine FM3A cells by immunoprecipitation of the interacting partners. Some of the interactions were found to be cell-cycle-dependent; however, most of them were cell-cycle-independent. Altogether, 90 protein-protein interactions were detected in this study, 52 of them were found for the first time in any eukaryotic pre-RC. These data may help to understand the complex interplay of the components of the mouse pre-RC and should allow us to refine its structural architecture as well as its assembly in real time.     

Tetrahymena ORC contains a ribosomal RNA fragment that participates in rDNA origin recognition

The Tetrahymena thermophila ribosomal DNA (rDNA) replicon contains dispersed cis-acting replication determinants, including reiterated type I elements that associate with sequence-specific, single-stranded binding factors, TIF1 through TIF4. Here, we show that TIF4, previously implicated in cell cycle-controlled DNA replication and rDNA gene amplification, is the T. thermophila origin recognition complex (TtORC). We further demonstrate that TtORC contains an integral RNA subunit that participates in rDNA origin recognition. Remarkably, this RNA, designated 26T, spans the terminal 282 nts of 26S ribosomal RNA. 26T RNA exhibits extensive complementarity to the type I element T-rich strand and binds the rDNA origin in vivo. Mutations that disrupt predicted interactions between 26T RNA and its complementary rDNA target change the in vitro binding specificity of ORC and diminish in vivo rDNA origin utilization. These findings reveal a role for ribosomal RNA in chromosome biology and define a new mechanism for targeting ORC to replication initiation sites.     

Dephosphorylation of Orc2 by protein phosphatase 1 promotes the binding of the origin recognition complex to chromatin

Phosphorylation of Orc2, one of the six subunits of the origin recognition complex (ORC), by cyclin A/CDK2 during S phase leads to the dissociation of Orc2, Orc3, Orc4, and Orc5 subunits (Orc2–5) from human chromatin and replication origins. Dephosphorylation of the phosphorylated Orc2 by protein phosphatase 1 (PP1) is accompanied by the binding of the dissociated subunits to chromatin. Here we show that PP1 physically interacts with Orc2. The binding of PP1 to Orc2 and the dephosphorylation of Orc2 by PP1 occurred in a cell cycle-dependent manner through an interaction with 119-KSVSF-123, which is the consensus motif for the binding of PP1, of Orc2. The dephosphorylation of Orc2 by PP1 is required for the binding of Orc2 to chromatin. These results support that PP1 dephosphorylates Orc2 to promote the binding of ORC to chromatin and replication origins for the subsequent round of the cell cycle.     

Identification and functional characterization of the nascent RNA contacting residues of the hepatitis C virus RNA-dependent RNA polymerase

Understanding how the hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) interacts with nascent RNA would provide valuable insight into the virus's mechanism for RNA synthesis. Using a peptide mass fingerprinting method and affinity capture of peptides reversibly cross-linked to an alkyn-labeled nascent RNA, we identified a region below the Δ1 loop in the fingers domain of the HCV RdRp that contacts the nascent RNA. A modification protection assay was used to confirm the assignment. Several mutations within the putative nascent RNA binding region were generated and analyzed for RNA synthesis in vitro and in the HCV subgenomic replicon. All mutations tested within this region showed a decrease in primer-dependent RNA synthesis and decreased stabilization of the ternary complex. The results from this study advance our understanding of the structure and function of the HCV RdRp and the requirements for HCV RNA synthesis. In addition, a model of nascent RNA interaction is compared with results from structural studies.     

Expression and characterization of human malaria parasite Plasmodium falciparum origin recognition complex subunit 1

In eukaryotes, the origin recognition complex (ORC) is essential for the initiation of DNA replication. The largest subunit of this complex (ORC1) has a regulatory role in origin activation. Here we report the cloning and functional characterization of Plasmodium falciparum ORC1 homolog. Using immunofluorescence and immunoelectron microscopy, we show here that PfORC1 is expressed in the nucleus during the late trophozoite and schizont stages where maximum amount of DNA replication takes place. Homology modelling of the carboxy terminal region of PfORC1 (781-1033) using Saccharomyces pombe Cdc6/Cdc18 homolog as a template reveals the presence of a similar AAA+ type nucleotide-binding fold. This region shows ATPase activity in vitro that is important for the origin activity. To our knowledge, this is the first evidence of an individual ORC subunit that shows ATPase activity. These observations strongly suggest that PfORC1 might be involved in DNA replication initiation during the blood stage of the parasitic life cycle.     

A viral deubiquitylating enzyme targets viral RNA-dependent RNA polymerase and affects viral infectivity

Selective protein degradation via the ubiquitin-proteasome system (UPS) plays an essential role in many major cellular processes, including host-pathogen interactions. We previously reported that the tightly regulated viral RNA-dependent RNA polymerase (RdRp) of the positive-strand RNA virus Turnip yellow mosaic virus (TYMV) is degraded by the UPS in infected cells, a process that affects viral infectivity. Here, we show that the TYMV 98K replication protein can counteract this degradation process thanks to its proteinase domain. In-vitro assays revealed that the recombinant proteinase domain is a functional ovarian tumour (OTU)-like deubiquitylating enzyme (DUB), as is the 98K produced during viral infection. We also demonstrate that 98K mediates in-vivo deubiquitylation of TYMV RdRp protein--its binding partner within replication complexes--leading to its stabilization. Finally, we show that this DUB activity contributes to viral infectivity in plant cells. The identification of viral RdRp as a specific substrate of the viral DUB enzyme thus reveals the intricate interplay between ubiquitylation, deubiquitylation and the interaction between viral proteins in controlling levels of RdRp and viral infectivity.     

Nucleotide channel of RNA-dependent RNA polymerase used for intermolecular uridylylation of protein primer

Poliovirus VPg is a 22 amino acid residue peptide that serves as the protein primer for replication of the viral RNA genome. VPg is known to bind directly to the viral RNA-dependent RNA polymerase, 3D, for covalent uridylylation, yielding mono and di-uridylylated products, VPg-pU and VPg-pUpU, which are subsequently elongated. To model the docking of the VPg substrate to a putative VPg-binding site on the 3D polymerase molecule, we performed a variety of structure-based computations followed by experimental verification. First, potential VPg folded structures were identified, yielding a suite of predicted beta-hairpin structures. These putative VPg structures were then docked to the region of the polymerase implicated by genetic experiments to bind VPg, using grid-based and fragment-based methods. Residues in VPg predicted to affect binding were identified through molecular dynamics simulations, and their effects on the 3D-VPg interaction were tested computationally and biochemically. Experiments with mutant VPg and mutant polymerase molecules confirmed the predicted binding site for VPg on the back side of the polymerase molecule during the uridylylation reaction, opposite to that predicted to bind elongating RNA primers.     

Metazoan origin selection: origin recognition complex chromatin binding is regulated by CDC6 recruitment and ATP hydrolysis

Using a plasmid competition assay, we have measured the stability of origin recognition complex (ORC) associated with sperm chromatin under physiological conditions. Under conditions in which pre-RCs are formed, both ORC and CDC6 dissociate from sperm chromatin with a relatively fast t(1/2) of 15 min. ORC dissociation from chromatin is regulated through the recruitment of CDC6 and MCM proteins as well as ATP hydrolysis. The t(1/2) for ORC alone in the absence of Cdc6 is 40 min and increases 8-fold to >2 h when Cdc6 is present. Strikingly, the presence of a non-hydrolyzable ATP derivative, ATPgammaS, not only increases both ORC and CDC6 t(1/2) but also inhibits the loading of MCM. The very stable association of ORC and Cdc6 with chromatin in this sequence-independent replication system suggests that origin selection in metazoans cannot be strictly dependent on the interaction of ORCs with specific DNA binding sequences.     

Architecture of the human origin recognition complex

All the human homologs of the six subunits of Saccharomyces cerevisiae origin recognition complex have been reported so far. However, not much has been reported on the nature and the characteristics of the human origin recognition complex. In an attempt to purify recombinant human ORC from insect cells infected with baculoviruses expressing HsORC subunits, we found that human ORC2, -3, -4, and -5 form a core complex. HsORC1 and HsORC6 subunits did not enter into this core complex, suggesting that the interaction of these two subunits with the core ORC2-5 complex is extremely labile. We found that the C-terminal region of ORC2 interacts directly with the N-terminal region of ORC3. The C-terminal region of ORC3 was, however, necessary to bring ORC4 and ORC5 into the core complex. A fragment containing the N-terminal 200 residues of ORC3 (ORC3N) competitively inhibited the ORC2-ORC3 interaction. Overexpression of this fragment in U2OS cells blocked the cells in G(1), providing the first evidence that a mammalian ORC subunit is important for the G(1)-S transition in mammalian cells.     

Assembly of the human origin recognition complex

The six-subunit origin recognition complex (ORC) was originally identified in the yeast Saccharomyces cerevisiae. Yeast ORC binds specifically to origins of replication and serves as a platform for the assembly of additional initiation factors, such as Cdc6 and the Mcm proteins. Human homologues of all six ORC subunits have been identified by sequence similarity to their yeast counterparts, but little is known about the biochemical characteristics of human ORC (HsORC). We have extracted HsORC from HeLa cell chromatin and probed its subunit composition using specific antibodies. The endogenous HsORC, identified in these experiments, contained homologues of Orc1-Orc5 but lacked a putative homologue of Orc6. By expressing HsORC subunits in insect cells using the baculovirus system, we were able to identify a complex containing all six subunits. To explore the subunit-subunit interactions that are required for the assembly of HsORC, we carried out extensive co-immunoprecipitation experiments with recombinant ORC subunits expressed in different combinations. These studies revealed the following binary interactions: HsOrc2-HsOrc3, HsOrc2-HsOrc4, HsOrc3-HsOrc4, HsOrc2-HsOrc6, and HsOrc3-HsOrc6. HsOrc5 did not form stable binary complexes with any other HsORC subunit but interacted with sub-complexes containing any two of subunits HsOrc2, HsOrc3, or HsOrc4. Complex formation by HsOrc1 required the presence of HsOrc2, HsOrc3, HsOrc4, and HsOrc5 subunits. These results suggest that the subunits HsOrc2, HsOrc3, and HsOrc4 form a core upon which the ordered assembly of HsOrc5 and HsOrc1 takes place. The characterization of HsORC should facilitate the identification of human origins of DNA replication.     

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.     

丙型肝炎病毒依赖于RNA的RNA聚合酶(RdRp)研究进展

由于缺乏合适的HCV感染细胞模型,严重制约了HCV复制,特别是HCV复制的关键因子依赖于RNA的RNA聚合酶(RdRp)的研究.对HCV序列比较分析并通过异源表达证明NS5B是HCV复制的RdRp.NS5B C端疏水性氨基酸区域以及NS5B与细胞膜形成复合体等影响NS5B溶解性.在合适的反应条件下NS5B可以多种RNA分子为模板催化RNA复制,特别是能有效复制HCV全长(+)RNA.高浓度GTP激活HCV RdRp活性.NS5B N/C端缺失突变和保守性A、B、C区中的点突变影响RdRp活性,但D区345位精氨酸突变为赖氨酸时RdRp活性明显升高.HCV RdRp的发现及其功能研究为HCV药物研究提供了新型靶标.     

Prevalent RNA recognition motif duplication in the human genome

The sequence-specific recognition of RNA by proteins is mediated through various RNA binding domains, with the RNA recognition motif (RRM) being the most frequent and present in >50% of RNA-binding proteins (RBPs). Many RBPs contain multiple RRMs, and it is unclear how each RRM contributes to the binding specificity of the entire protein. We found that RRMs within the same RBP (i.e., sibling RRMs) tend to have significantly higher similarity than expected by chance. Sibling RRM pairs from RBPs shared by multiple species tend to have lower similarity than those found only in a single species, suggesting that multiple RRMs within the same protein might arise from domain duplication followed by divergence through random mutations. This finding is exemplified by a recent RRM domain duplication in DAZ proteins and an ancient duplication in PABP proteins. Additionally, we found that different similarities between sibling RRMs are associated with distinct functions of an RBP and that the RBPs tend to contain repetitive sequences with low complexity. Taken together, this study suggests that the number of RBPs with multiple RRMs has expanded in mammals and that the multiple sibling RRMs may recognize similar target motifs in a cooperative manner.     

Kinetically driven refolding of the hyperstable EBNA1 origin DNA-binding dimeric beta-barrel domain into amyloid-like spherical oligomers

The Epstein-Barr nuclear antigen 1 (EBNA1) is essential for DNA replication and episome segregation of the viral genome, and participates in other gene regulatory processes of the Epstein-Barr virus in benign and malignant diseases related to this virus. Despite the participation of other regions of the protein in evading immune response, its DNA binding, dimeric beta-barrel domain (residues 452-641) is necessary and sufficient for the main functions. This domain has an unusual topology only shared by another viral origin binding protein (OBP), the E2 DNA binding domain of papillomaviruses. Both the amino acid and DNA target sequences are completely different for these two proteins, indicating a link between fold conservation and function. In this work we investigated the folding and stability of the DNA binding domain of EBNA1 OBP and found it is extremely resistant to chemical, temperature, and pH denaturation. The thiocyanate salt of guanidine is required for obtaining a complete transition to a monomeric unfolded state. The unfolding reaction is extremely slow and shows a marked uncoupling between tertiary and secondary structure, indicating the presence of intermediate species. The Gdm.SCN unfolded protein refolds to fully soluble and spherical oligomeric species of 1.2 MDa molecular weight, with identical fluorescence centre of spectral mass but different intensity and different secondary structure. The refolded spherical oligomers are substantially less stable than the native recombinant dimer. In keeping with the substantial structural rearrangement in the oligomers, the spherical oligomers do not bind DNA, indicating that the DNA binding site is either disrupted or participates in the oligomerization interface. The puzzling extreme stability of a dimeric DNA binding domain from a protein from a human infecting virus in addition to a remarkable kinetically driven folding where all molecules do not return to the most stable original species suggests a co-translational and directional folding of EBNA1 in vivo, possibly assisted by folding accessory proteins. Finally, the oligomers bind Congo red and thioflavin-T, both characteristic of repetitive beta-sheet elements of structure found in amyloids and their soluble precursors. The stable nature of the "kinetically trapped" oligomers suggest their value as models for understanding amyloid intermediates, their toxic nature, and the progress to amyloid fibers in misfolding diseases. The possible role of the EBNA1 spherical oligomers in the virus biology is discussed.