Purification of a cellular replication factor, RF-C, that is required for coordinated synthesis of leading and lagging strands during simian virus 40 DNA replication in vitro.

Cell extracts (S100) derived from human 293 cells were separated into five fractions by phosphocellulose chromatography and monitored for their ability to support simian virus 40 (SV40) DNA replication in vitro in the presence of purified SV40 T antigen. Three fractions, designated I, IIA, and IIC, were essential. Fraction IIC contained the known replication factors topoisomerases I and II, but in addition contained a novel replication factor called RF-C. The RF-C activity, assayed in the presence of I, IIA, and excess amounts of purified topoisomerases, was detected in both cytosol and nuclear fractions, but was more abundant in the latter fraction. RF-C was purified from the 293 cell nuclear fraction to near homogeneity by conventional column chromatography. The reconstituted reaction mix containing purified RF-C could replicate SV40 origin-containing plasmid DNA more efficiently than could the S100 extract, and the products were predominantly completely replicated, monomer molecules. Interestingly, in the absence of RF-C, early replicative intermediates accumulated and subsequent elongation was aberrant. Hybridization studies with strand-specific, single-stranded M13-SV40 DNAs showed that in the absence of RF-C, abnormal DNA synthesis occurred preferentially on the lagging strand, and leading-strand replication was inefficient. These products closely resembled those previously observed for SV40 DNA replication in vitro in the absence of proliferating-cell nuclear antigen. These results suggest that an elongation complex containing RF-C and proliferating-cell nuclear antigen is assembled after formation of the first nascent strands at the replication origin. Subsequent synthesis of leading and lagging strands at a eucaryotic DNA replication fork can be distinguished by different requirements for multiple replication components, but we suggest that even though the two polymerases function asymmetrically, they normally progress coordinately.

Simian virus 40 DNA replication in vitro: identification of multiple stages of initiation.

A cell-free DNA replication system dependent upon five purified cellular proteins, one crude cellular fraction, and the simian virus 40 (SV40)-encoded large tumor antigen (T antigen) initiated and completed replication of plasmids containing the SV40 origin sequence. DNA synthesis initiated at or near the origin sequence after a time lag of approximately 10 min and then proceeded bidirectionally from the origin to yield covalently closed, monomer daughter molecules. The time lag could be completely eliminated by a preincubation of SV40 ori DNA in the presence of T antigen, a eucaryotic single-stranded DNA-binding protein (replication factor A [RF-A]), and topoisomerases I and II. In contrast, if T antigen and the template DNA were incubated alone, the time lag was only partially decreased. Kinetic analyses of origin recognition by T antigen, origin unwinding, and DNA synthesis suggest that the time lag in replication was due to the formation of a complex between T antigen and DNA called the T complex, followed by formation of a second complex called the unwound complex. Formation of the unwound complex required RF-A. When origin unwinding was coupled to DNA replication by the addition of a partially purified cellular fraction (IIA), DNA synthesis initiated at the ori sequence, but the template DNA was not completely replicated. Complete DNA replication in this system required the proliferating-cell nuclear antigen and another cellular replication factor, RF-C, during the elongation stage. In a less fractionated system, another cellular fraction, SSI, was previously shown to be necessary for reconstitution of DNA replication. The SSI fraction was required in the less purified system to antagonize the inhibitory action of another cellular protein(s). This inhibitor specifically blocked the earliest stage of DNA replication, but not the later stages. The implications of these results for the mechanisms of initiation and elongation of DNA replication are discussed.

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.

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.

Identification of cellular components required for SV40 DNA replication in vitro.

To investigate the cellular proteins involved in simian virus 40 (SV40) replication, extracts derived from human 293 cells have been fractionated into multiple components. When such fractions are combined with the virus-encoded T antigen (TAg) and SV40 origin containing plasmid DNA, efficient and complete replication is achieved, while each fraction alone is inactive. At present, a minimum of eight such cellular components have been identified. Previous experiments have demonstrated one of these to be the cell-cycle-regulated proliferating-cell nuclear antigen (PCNA). As PCNA has been identified as a processivity factor for DNA polymerase delta, we suggest that both polymerases alpha and delta are involved in this system. Three further fractions have been identified. One is a partially purified fraction which, under certain conditions, is required with TAg for the formation of a pre-synthesis complex of proteins at the replication origin. The second of these factors, RF-A, is a complex of three polypeptides which may function as a eucaryotic SSB. The third, RF-C, is a factor which is required, with PCNA, for coordinated leading- and lagging-strand synthesis at the replication fork. Complete synthesis and segregation of the daughter molecules also requires the presence of topoisomerases I and II. These results suggest a model for DNA synthesis which involves multiple stages prior to and during replicative DNA synthesis.

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.

Plasmid vectors designed for high-efficiency expression controlled by the portable recA promoter-operator of Escherichia coli.

A novel expression vector using the 236-bp promoter-operator fragment of the recA gene (recApo) of Escherichia coli has been constructed. This DNA fragment contains complete signals for the initiation of RNA synthesis, as well as for regulation by the lexA product, but lacks the coding sequence for the RecA protein. The strength of the recA promoter was examined by assaying beta-galactosidase activity expressed from a cro-lacZ fused gene placed downstream of the promoter. Under noninducing conditions, the promoter was regulated by the LexA protein, and the fused gene was expressed only weakly. Upon induction by nalidixic acid in a recA+ strain, high expression was observed for an extended period. After 5 h under inducing conditions, as much as 11% of the total cellular protein was cro-lacZ product. The expression level was higher than that from promoters of lac, trp, and lambda early genes.

Purification of hepatitis B virus gene X product synthesized in Escherichia coli and its detection in a human hepatoblastoma cell line producing hepatitis B virus.

A fused gene containing 94% of the hepatitis B virus (HBV) open reading frame X was expressed in Escherichia coli, and its 17-kDa product was purified by ion-exchange chromatography. Antibody elicited against the X-gene product reacted with materials proximal to the nuclear membrane of a human hepatoblastoma cell line producing HBV particles. No such reaction was observed with the same cell line that did not produce HBV particles.

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

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.

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.

Multiple replication factors augment DNA synthesis by the two eukaryotic DNA polymerases, alpha and delta.

DNA synthesis by two eukaryotic DNA polymerases, alpha and delta, was studied using a single-strand M13 DNA template primed at a unique site. In the presence of low amounts of either DNA polymerase alpha or delta, DNA synthesis was limited and short DNA strands of approximately 100 bases were produced. Addition of replication factors RF-A, PCNA and RF-C, which were previously shown to be required for SV40 DNA replication in vitro, differentially stimulated the activity of both DNA polymerases. RF-A and RF-C independently stimulated DNA polymerase alpha activity 4- to 6-fold, yielding relatively short DNA strands (less than 1 kb) and PCNA had no effect. In contrast, polymerase delta activity was stimulated co-operatively by PCNA, RF-A and RF-C approximately 25- to 30-fold, yielding relatively long DNA strands (up to 4 kb). Neither RF-C nor RF-A appear to correspond to known polymerase stimulatory factors. RF-A was previously shown to be required for initiation of DNA replication at the SV40 origin. Results presented here suggest that it also functions during elongation. The differential effects of these three replication factors on DNA polymerases alpha and delta is consistent with the model that the polymerases function at the replication fork on the lagging and leading strand templates respectively. We further suggest that co-ordinated synthesis of these strands requires dynamic protein-protein interactions between these replication factors and the two DNA polymerases.

Multiple initiation sites of DNA replication flanking the origin region of lambda dv genome.

Early replicative intermediates of lambda dv plasmid were prepared by an in vitro replication system in the presence of 2',3'-dideoxycytidine 5'-triphosphate, an inhibitor of DNA chain elongation. Short-chain DNAs produced from regions near the replication origin were purified from the intermediates. A fraction of the DNAs was covalently linked to primer RNA. The transition sites from primer RNA to DNA synthesis were mapped along the nucleotide sequence of the genome, by eliminating the RNA by alkaline hydrolysis and labeling the freshly exposed 5' ends of DNA with 32P. The transition sites were found to be located on both sides of the ori region, which includes four 19-base-pair repeats where one of the lambda specific initiator proteins, O, binds. No transition arose within the ori region. The transition sites are multiple on both sides of the ori region and are clustered in one of the two strands in such a way that DNA syntheses from the two sides converge. The frequency of the "leftward" DNA synthesis is several times higher than that of "rightward" synthesis, reflecting the asymmetric bidirectional replication of lambda dv DNA.