Functional interactions of an archaeal sliding clamp with mammalian clamp loader and DNA polymerase delta.

BACKGROUND: By the total genome sequencing of several archaeal organisms, it has been confirmed that many archaeal proteins related to genetic information systems, including DNA replication, transcription and translation, have similar sequences to those of eukaryotes. In eukaryotic DNA replication, proliferating cell nuclear antigen (PCNA) works in clamping DNA polymerases on the DNA template and accomplishes a processive DNA synthesis. Archaea encode PCNA homologues in their genomes and Pyrococcus furiosus PCNA (PfuPCNA) stimulates the DNA synthesizing activities of the DNA polymerases, Pol I and Pol II, in this organism. RESULTS: We have demonstrated that PfuPCNA interacts functionally with calf thymus DNA polymerase delta (Pol delta) and stimulates its activity. Moreover, human replication factor C (RFC) enhances the PfuPCNA-dependent DNA synthesis activity of Pol delta, indicating that human RFC works as the clamp loader for PfuPCNA. These results showed that the three-dimensional structures of archaral PCNA and RFC are actually similar enough to their eukaryotic counterparts to allow a molecular substitution between the two biological domains, albeit at a lower efficiency. CONCLUSIONS: We found that the archaeal molecule interacts functionally with the eukaryotic members in the DNA replication process. This finding supports the idea that studies on the DNA replication mechanism of archaeal organisms will provide many important clues for understanding of the intricate molecular recognition that is inherent to the DNA replication machinery in Eukarya.

In vitro reconstitution of the end replication problem.

The end replication problem hypothesis proposes that the ends of linear DNA cannot be replicated completely during lagging strand DNA synthesis. Although the idea has been widely accepted for explaining telomere attrition during cell proliferation, it has never been directly demonstrated. In order to take a biochemical approach to understand how linear DNA ends are replicated, we have established a novel in vitro linear simian virus 40 DNA replication system. In this system, terminally biotin-labeled linear DNAs are conjugated to avidin-coated beads and subjected to replication reactions. Linear DNA was efficiently replicated under optimized conditions, and replication products that had replicated using the original DNA templates were specifically analyzed by purifying bead-bound replication products. By exploiting this system, we showed that while the leading strand is completely synthesized to the end, lagging strand synthesis is gradually halted in the terminal approximately 500-bp region, leaving 3' overhangs. This result is consistent with observations in telomerase-negative mammalian cells and formally demonstrates the end replication problem. This study provides a basis for studying the details of telomere replication.

The human homologue of fission Yeast cdc27, p66, is a component of active human DNA polymerase delta.

An essential eukaryotic DNA polymerase, DNA polymerase delta (pol delta), synthesizes DNA processively in the presence of proliferating cell nuclear antigen (PCNA). Recently, a 66 kDa polypeptide (p66) that displays significant homology within its PCNA binding domain to that of fission yeast cdc27 was identified as a component of mouse and calf thymus pol delta. Our studies show that p66 interacts tightly with other subunits of pol delta during size fractionation of human cell extracts, and co-immunoprecipitates with these subunits along with PCNA-dependent polymerase activity. Active human pol delta could be reconstituted by co-expressing p125, p50, and p66 recombinant baculoviruses, but not by co-expressing p125 and p50 alone. Interaction studies demonstrated that p66 stabilizes the association between p125 and p50. Pull-down assays with PCNA-linked beads demonstrated that p66 increases the overall affinity of pol delta for PCNA. These results indicate that p66 is a functionally important subunit of human pol delta that stabilizes the pol delta complex and increases the affinity of pol delta for PCNA.

Atomic force microscopy with carbon nanotube probe resolves the subunit organization of protein complexes.

Among many scanning probe microscopies, atomic force microscopy (AFM) is a useful technique to analyse the structure of biological materials because of its applicability to non-conductors in physiological conditions with high resolution. However, the resolution has been limited to an inherent property of the technique; tip effect associated with a large radius of the scanning probe. To overcome this problem, we developed a carbon nanotube probe by attaching a carbon nanotube to a conventional scanning probe under a well-controlled process. Because of the constant and small radius of the tip (2.5-10 nm) and the high aspect ratio (1:100) of the carbon nanotube, the lateral resolution has been much improved judging from the apparent widths of DNA and nucleosomes. The carbon nanotube probes also possessed a higher durability than the conventional probes. We further evaluated the quality of carbon nanotube probes by three parameters to find out the best condition for AFM imaging: the angle to the tip axis; the length; and the tight fixation to the conventional tip. These carbon nanotube probes, with high vertical resolution, enabled us to clearly visualize the subunit organization of multi-subunit proteins and to propose structural models for proliferating cell nuclear antigen and replication factor C. This success in the application of carbon nanotube probes provides the current AFM technology with an additional power for the analyses of the detailed structure of biological materials and the relationship between the structure and function of proteins.

ATP-dependent structural change of the eukaryotic clamp-loader protein, replication factor C.

The eukaryotic DNA sliding clamp that keeps DNA polymerase engaged at a replication fork, called proliferating cell nuclear antigen (PCNA), is loaded onto the 3' ends of primer DNA through its interaction with a heteropentameric protein complex called replication factor C (RFC). The ATPase activity of RFC is necessary for formation of a functional PCNA clamp. In the present study, the sensitivity of RFC to partial proteolysis is used to show that addition of ATP, ATPgammaS, or ADP induces different structural changes in RFC. Direct observation by electron microscopy reveals that RFC has a closed two-finger structure called the U form in the absence of ATP. This is converted into a more open C form on addition of ATP. In contrast, the structural changes induced by ATPgammaS or ADP are limited. These results suggest that RFC adapts on opened configuration intermediately after ATP hydrolysis. We further observe that PCNA is held between the two fingers of RFC and propose that the RFC structure change we observe during ATP hydrolysis causes the attached PCNA to form its active ring-like clamp on DNA.

Association of human origin recognition complex 1 with chromatin DNA and nuclease-resistant nuclear structures.

An origin recognition complex (ORC) consisting of six polypeptides has been identified as a DNA replication origin-binding factor in Saccharomyces cerevisiae. Homologues of ORC subunits have been discovered among eukaryotes, and we have prepared monoclonal antibodies against a human homologue of ORC1 (hORC1) to study its localization in human cells. It was thus found to associate with nuclei throughout the cell cycle and to be resistant to nonionic detergent treatment, in contrast to MCM proteins, which are other replication factors, the association of which with nuclei is clearly dependent on the phase of the cell cycle. A characteristic feature of hORC1 is dissociation by NaCl in a narrow concentration range around 0.25 M, suggesting interaction with some specific partner(s) in nuclei. Nuclease treatment experiments and UV cross-linking experiments further indicated interaction with both nuclease-resistant nuclear structures and chromatin DNA. Although its DNA binding was unaffected, some variation in the cell cycle was apparent, the association with nuclear structures being less stable in the M phase. Interestingly, the less stable association occurred concomitantly with hyperphosphorylation of hORC1, suggesting that this hyperphosphorylation may be involved in M phase changes.

PCNA binding proteins.

PCNA (proliferating cell nuclear antigen), originally characterized as a DNA polymerase accessory protein, functions as a DNA sliding clamp for DNA polymerase delta and is an essential component for eukaryotic chromosomal DNA replication. Recent studies have revealed a striking feature of PCNA in its ability to interact with multiple partners, involved, for example, in Okazaki fragment joining, DNA repair, DNA methylation and chromatin assembly. Since these reactions take place mainly on replicating DNA, PCNA has applications as a marker for DNA synthesis. It is of interest that proteins involved in cell cycle regulation may also exhibit PCNA binding activity. For example, the CDK inhibitor, p21 (Cip1/Waf1) interacts with PCNA blocking its activity necessary for DNA replication and also affecting interactions with other PCNA binding proteins. The available data indicate that DNA sliding clamps have generated additional functions with evolution of eukaryotes from simple prokaryotes. In mammalian cells, they play key roles in controlling DNA synthesis reactions and the reorganization of replicated DNA at replication forks. Several cell cycle regulation proteins target these processes by affecting PCNA actions

Effects of a high-affinity antibody fragment on DNA polymerase reactions near a (6-4) photoproduct site.

Pyrimidine (6-4) pyrimidone photodimers are major photoproducts that have mutagenic and carcinogenic consequences. One major reason for these biological effects of (6-4) photoproducts may be base mispairing/DNA replication errors due to hydrogen bonding to bases opposite these damaged sites. We synthesized a modified 41-mer DNA containing a (6-4) photoproduct using a preformed building block, then employed it as a template for primer extension reactions catalyzed by Klenow fragment and DNA polymerases alpha, beta and delta (pol alpha, pol beta and pol delta). None of these DNA polymerases were able to bypass the (6-4) photoproduct and elongation terminated at or near the 3'-pyrimidone of the photoproduct, depending on the dNTP concentration. When a single-chain Fv (scFv) with high affinity for the (6-4) photoproduct was included in the polymerization reaction, DNA synthesis was inhibited at base positions four, six, eight or eight nucleotides prior to the 3'-pyrimidone by Klenow fragment, pol alpha, pol beta or pol delta, respectively. These results suggest that the scFv can bind to the template DNA containing a (6-4) photoproduct and inhibit extension reactions by polymerases.

Regulation of DNA-replication origins during cell-cycle progression.

We have shown previously that chromosome VI of Saccharomyces cerevisiae contains nine origins of DNA replication that differ in initiation frequency and replicate sequentially during the S phase of the cell cycle. Here we show that there are links between activation of these multiple origins and regulation of S-phase progression. We study the effects of a DNA-damaging agent, methyl methane sulphonate (MMS), and of mutations in checkpoint genes such as rad53 on the activity of origins, measured by two-dimensional gel analysis, and on cell-cycle progression, measured by fluorescence-activated cell sorting. We find that when MMS slows down S-phase progression it also selectively blocks initiation from late origins. A rad53 mutation enhances late and/or inefficient origins and releases the initiation block by MMS. Mutation of rad53 also results in a late origin becoming early replicating. We conclude that rad53 regulates the timing of initiation of replication from late origins during normal cell growth and blocks initiation from late origins in MMS-treated cells. rad53 is, therefore, involved in the cell's surveillance of S-phase progression. We also find that orc2, which encodes subunit 2 of the origin-recognition complex, is involved in suppression of late origins.

Functional sites of human PCNA which interact with p21 (Cip1/Waf1), DNA polymerase delta and replication factor C.

BACKGROUND: PCNA, an eukaryotic DNA sliding clamp interacts with replication factors and the cell cycle protein, p21(Cip1/Waf1) and functions as a molecular switch for DNA elongation. To understand how DNA replication is regulated through PCNA, elucidation of the precise mechanisms of these protein interactions is necessary. RESULTS: Loop-region mutants in which human PCNA sequences were substituted with the corresponding Saccharomyces cerevisiae PCNA regions were prepared. Analysis of their functions, along with previously prepared alanine scanning mutants, demonstrated that some loops interact with DNA polymerase delta (pol delta) and replication factor C (RFC). The p21 binding sites of PCNA, mapped by affinity measurement of the mutant forms, found to be located within a distinct structure of the PCNA monomer, overlap with RFC- and pol delta-interaction sites. Competition between p21 and pol delta or RFC for binding to PCNA results in efficient inhibition of its stimulation of pol delta DNA synthesis and RFC ATPase but not of PCNA loading on DNA by RFC. CONCLUSIONS: Semi-saturated amounts of p21 selectively block formation of the active pol delta complex but not the RFC-PCNA complex at 3'-ends of DNA primers. This differential effect may explain the specific inhibition of DNA replication by p21.

Cell cycle dependent topological changes of chromosomal replication origins in Saccharomyces cerevisiae.

BACKGROUND: The ORC (Origin Recognition Complex) of Saccharomyces cerevisiae is a protein complex for the initiation of replication which interacts with a cis-element, ACS (ARS Consensus Sequence), essential for DNA replication. The protein-DNA complex detected by the DNase I genomic footprinting method has been shown to vary depending on cell cycle progression. Further studies on topological changes of replication origin in vivo caused by ORC association are crucial for an understanding of chromosomal DNA replication in S. cerevisiae. RESULTS: Topological changes in the replication origins of the S. cerevisiae chromosome were studied by an in vivo UV photofootprinting method which is capable of detecting the change in the flexibility of DNA caused by protein binding. The footprinting method detected the inhibition and enhancement of UV-induced pyrimidine dimer formation in A and B1 elements of a chromosomal origin, ARS1, depending on the activity of native ORC subunits. Furthermore, footprint patterns were reproduced in vitro with purified ORC. The inhibition regarding the A element was stronger during the S to late M phase than that during the progression through the G1 phase. Functional CDC6 and MCM5 were required for maintaining the weaker inhibition state in G1-arrested cells. CONCLUSION: The application of in vivo UV photofootprinting in studies of topological changes of S. cerevisiae replication origins revealed the presence of two modes of topological ORC-ACS interaction. The weaker footprint in the G1 phase represents a specific topology of ACS, resulting from an alteration of the ORC-ACS interaction aided by CDC6 and MCM5, and this topological change may make the replication origin competent for initiating DNA replication.

The efficiency and timing of initiation of replication of multiple replicons of Saccharomyces cerevisiae chromosome VI.

BACKGROUND: A complete set of nine ARSs was identified (the tenth ARS in this paper), mapped on chromosome VI of Saccharomyces cerevisiae, and characterized for functional elements. RESULTS: The level of activity of all ARSs as chromosomal replication origins was determined by neutral/neutral 2D gel-electrophoresis. These origins were classified into three groups: (i) three high frequency origins used once nearly every cell cycle, (ii) four intermediate frequency origins used once in two to three cycles and (iii) two low frequency origins used in fewer than 5% of cell cycles. These variations in initiation frequency among origins of chromosome VI are present in three common laboratory wild-type strains. Each origin is initiated at a fixed time and passively replicated by incoming replication forks at a fixed time during a synchronous S phase. Replication of each arm of the chromosome starts from one major origin located one-fifth (left arm) and one-third (right arm) of the distance from the centromere, and expands sequentially in both directions. Two telomere vicinity origins are replicated last. Time of initiation and replication of the last replicating origin, Ori609, was remarkably variable from cell to cell. CONCLUSIONS: Chromosome VI of S. cerevisiae contains nine replication origins that comprise five active replicons under normal cell growth conditions. A clear correlation was found between the efficiency of initiation and the order of replication. The timing of initiation of most origins, except for the first and last, is coincident with the time of passive replication by incoming forks from neighbouring origins.

Characterization of a novel CDC gene (ORC1) partly homologous to CDC6 of Saccharomyces cerevisiae.

A novel cell cycle gene was identified by a computer search for genes partly homologous to known CDC genes, CDC6 of Saccharomyces cerevisiae and CDC18 of Schizosaccharomyces pombe, using the nucleotide sequence data base for S. cerevisiae produced by the Yeast Sequencing Project. The protein sequence coded by the cloned gene was found to be identical to that of purified ORC1 protein. Disruption of the gene and subsequent tetrad analysis revealed that the gene was essential for growth. The function of the gene product was analyzed by depleting the protein from the cell using a mutant haploid strain containing the disrupted ORC1 gene on the chromosome and a galactose-inducible gene coding for HA-tagged ORC1 protein on a single copy plasmid. The HA-tagged protein was expressed during growth in the presence of galactose but began to decrease rapidly upon depletion of galactose. Analysis of the cell cycle progression of the mutant cells by FACS after the removal of galactose from the medium, and microscope observations of cells and their nuclei revealed that the normal progression of 2N cells was immediately impeded as the ORC1 protein started to decrease. This was blocked completely in the cells that had progressed to the S phase under conditions deficient in ORC1 protein followed by cell death. Two-dimensional gel analysis of the replication intermediates after the galactose removal revealed that the depletion of ORC1 protein caused a decrease in the frequency of initiation of chromosomal replication, eventually resulting in the inhibition of replication as a whole. The function of the ORC1 protein in the cell cycle progression of S. cerevisiae is discussed in light of current information on ORC.

Structure-function relationship of the eukaryotic DNA replication factor, proliferating cell nuclear antigen.

Proliferating cell nuclear antigen (PCNA) is essential for eukaryotic DNA replication and functions as a processivity factor of DNA polymerase delta (pol delta). Due to the functional and structural similarity with the beta-subunit of Escherichia coli DNA polymerase III, it has been proposed that PCNA would act as a molecular clamp during DNA synthesis. By site-directed mutagenesis and biochemical analyses, we have studied the functional domains of human PCNA required for stimulation of replication factor C (RF-C) ATPase and DNA synthesis by pol delta. Short deletions from either the N or C termini caused drastic changes in extraction and chromatographic behaviors, suggesting that both of these terminal regions are crucial to fold the tertiary structure of PCNA. The short C-terminal stretch from Lys254 to Glu256 is necessary for stimulation of RF-C ATPase activity, but not for stimulation of DNA synthesis by pol delta. Nine basic amino acids that are essential for activating DNA synthesis by pol delta are positioned at the internal alpha-helices of PCNA. This result is in good agreement with the observation that PCNA has a ring structure similar to the beta-subunit and clamps a template DNA through this positively charged internal surface. Several other charged amino acids are also required to stimulate either RF-C ATPase or pol delta DNA synthesis. Some of them are positioned at loops which are exposed on one of the side surface of PCNA adjacent to the C-terminal loop. In addition, the beta-sheets composing the intermolecular interface of the trimeric PCNA are important for interaction with pol delta. Therefore, the outer surface of PCNA has multiple functional surfaces which are responsible for the interaction with multiple factors. Furthermore, the two side surfaces seem to be functionally distinguishable, and this may determine the orientation of tracking PCNA along the DNA.

Isolation of human DNA-unwinding elements as sites of DNA polymerase alpha/primase entry.

Human DNA libraries were screened for DNA synthesis activity in vitro using purified DNA polymerase alpha/primase and a viral DNA helicase (simian virus 40 large tumor antigen). Three clones exhibited a high activity distinguishable from the rest. The DNA synthesis was dependent on negative supertwisting and initiated at a unique region in the human DNA insert. Functional subclone DNA fragments which could be shortened to less than 1 kb are located in the initiation region. Binding with a single-stranded DNA-binding protein and digestion with nuclease P1 demonstrated that these DNAs have a highly single-stranded nature at a certain site in a closed circular plasmid. The minimal functional sequences coincide with the single-stranded region and contain a characteristic dinucleotide repeat sequence. These repeats have an extremely low free energy for DNA strand separation and are defined as DNA-unwinding elements, which are frequently observed at regions flanking replication origins in Escherichia coli and Saccharomyces cerevisiae chromosomes. We suggest that such a repeating sequence would have an important role during initiation of DNA replication and function as a site to recruit replication proteins.

Three envelope proteins of hepatitis B virus: large S, middle S, and major S proteins needed for the formation of Dane particles.

The infectious particles of hepatitis B virus are called Dane particles and consist of viral nucleic acid encapsulated within a core particle that is enveloped by virus-coded surface proteins. The major S protein constitutes a significant fraction of these surface proteins. In addition, there are two other related proteins (large S and middle S), but their role in envelope formation has not yet been elucidated. We modified the translation initiation codon ATG of each of the envelope proteins by site-directed mutagenesis and found that mutant genomes that did not produce one or two of these proteins were unable to form Dane particles. The particles released into the culture medium by such mutants did not carry DNA. Synthesis of virus-coded RNA still occurred normally, and core particles carrying DNA accumulated intracellularly. The DNA in such core particles was mostly in the double-stranded open circular form, in contrast to the normal situation in which the particles contain mostly RNA and its complementary single-stranded DNA or else contain linear DNA that is partially single stranded and otherwise duplex. The role of the large S and middle S proteins in the formation of Dane particles is discussed.