Ub-family modifications at the replication fork: Regulating PCNA-interacting components

A vast array of proteins is recruited to the replication fork in a dynamic and coordinated manner through physical interactions with Proliferating Cell Nuclear Antigen, PCNA. How this complex exchange of PCNA binding partners is choreographed to ensure proper replication origin licensing, DNA synthesis during normal replication or repair of DNA damage, chromatin assembly, DNA methylation, histone modification, and sister chromatid cohesion is only beginning to be appreciated. In this review, several roles of ubiquitin-related modifications in the recruitment and turnover of PCNA-interacting proteins at the replication fork are considered.     

Interactions of the DNA polymerase and gene 4 protein of bacteriophage T7. Protein-protein and protein-DNA interactions involved in RNA-primed DNA synthesis

Three proteins catalyze RNA-primed DNA synthesis on the lagging strand side of the replication fork of bacteriophage T7. Oligoribonucleotides are synthesized by T7 gene 4 protein, which also provides helicase activity. DNA synthesis is catalyzed by gene 5 protein of the phage, and processivity of DNA synthesis is conferred by Escherichia coli thioredoxin, a protein that is tightly associated with gene 5 protein. T7 DNA polymerase and gene 4 protein associate to form a complex that can be isolated by filtration through a molecular sieve. The complex is stable in 50 mM NaCl but is dissociated by 100 mM NaCl, a salt concentration that does not inhibit RNA-primed DNA synthesis. T7 DNA polymerase forms a stable complex with single-stranded M13 DNA at 50 mM NaCl as measured by gel filtration, and this complex requires 200 mM NaCl for dissociation, a salt concentration that inhibits RNA-primed DNA synthesis. Gene 4 protein alone does not bind to single-stranded DNA. In the presence of MgCl2 and dTTP or beta, gamma-methylene dTTP, a gene 4 protein-M13 DNA complex that is stable at 200 mM NaCl is formed. The affinity of DNA polymerase for both gene 4 protein and single-stranded DNA leads to the formation of a gene 4 protein-DNA polymerase-M13 DNA complex even in the absence of nucleoside triphosphates. However, the binding of each protein to DNA plays an important role in mediating the interaction of the proteins with each other. High concentrations of single-stranded DNA inhibit RNA-primed DNA synthesis by diluting the amount of proteins bound to each template and reducing the frequency of protein-protein interactions. Preincubation of gene 4 protein, DNA polymerase, and M13 DNA in the presence of dTTP forms protein-DNA complexes that most efficiently catalyze RNA-primed DNA synthesis in the presence of excess single-stranded competitor DNA.     

Cell cycle-dependent dynamic association of cyclin/Cdk complexes with human DNA replication proteins

We have previously described the isolation of a replication competent (RC) complex from calf thymus, containing DNA polymerase alpha, DNA polymerase delta and replication factor C. Here, we describe the isolation of the RC complex from nuclear extracts of synchronized HeLa cells, which contains DNA replication proteins associated with cell-cycle regulation factors like cyclin A, cyclin B1, Cdk2 and Cdk1. In addition, it contains a kinase activity and DNA polymerase activities able to switch from a distributive to a processive mode of DNA synthesis, which is dependent on proliferating cell nuclear antigen. In vivo cross-linking of proteins to DNA in synchronized HeLa cells demonstrates the association of this complex to chromatin. We show a dynamic association of cyclins/Cdks with the RC complex during the cell cycle. Indeed, cyclin A and Cdk2 associated with the complex in S phase, and cyclin B1 and Cdk1 were present exclusively in G(2)/M phase, suggesting that the activity, as well the localization, of the RC complex might be regulated by specific cyclin/Cdk complexes.     

Conditional coupling of leading-strand and lagging-strand DNA synthesis at bacteriophage T4 replication forks

Eight proteins encoded by bacteriophage T4 are required for the replicative synthesis of the leading and lagging strands of T4 DNA. We show here that active T4 replication forks, which catalyze the coordinated synthesis of leading and lagging strands, remain stable in the face of dilution provided that the gp44/62 clamp loader, the gp45 sliding clamp, and the gp32 ssDNA-binding protein are present at sufficient levels after dilution. If any of these accessory proteins is omitted from the dilution mixture, uncoordinated DNA synthesis occurs, and/or large Okazaki fragments are formed. Thus, the accessory proteins must be recruited from solution for each round of initiation of lagging-strand synthesis. A modified bacteriophage T7 DNA polymerase (Sequenase) can replace the T4 DNA polymerase for leading-strand synthesis but not for well coordinated lagging-strand synthesis. Although T4 DNA polymerase has been reported to self-associate, gel-exclusion chromatography displays it as a monomer in solution in the absence of DNA. It forms no stable holoenzyme complex in solution with the accessory proteins or with the gp41-gp61 helicase-primase. Instead, template DNA is required for the assembly of the T4 replication complex, which then catalyzes coordinated synthesis of leading and lagging strands in a conditionally coupled manner.     

PCNA acts as a stationary loading platform for transiently interacting Okazaki fragment maturation proteins

In DNA replication, the leading strand is synthesized continuously, but lagging strand synthesis requires the complex, discontinuous synthesis of Okazaki fragments, and their subsequent joining. We have used a combination of in situ extraction and dual color photobleaching to compare the dynamic properties of three proteins essential for lagging strand synthesis: the polymerase clamp proliferating cell nuclear antigen (PCNA) and two proteins that bind to it, DNA Ligase I and Fen1. All three proteins are localized at replication foci (RF), but in contrast to PCNA, Ligase and Fen1 were readily extracted. Dual photobleaching combined with time overlays revealed a rapid exchange of Ligase and Fen1 at RF, which is consistent with de novo loading at every Okazaki fragment, while the slow recovery of PCNA mostly occurred at adjacent, newly assembled RF. These data indicate that PCNA works as a stationary loading platform that is reused for multiple Okazaki fragments, while PCNA binding proteins only transiently associate and are not stable components of the replication machinery.     

Single-molecule studies of DNA replisome function

Fast and accurate replication of DNA is accomplished by the interactions of multiple proteins in the dynamic DNA replisome. The DNA replisome effectively coordinates the leading and lagging strand synthesis of DNA. These complex, yet elegantly organized, molecular machines have been studied extensively by kinetic and structural methods to provide an in-depth understanding of the mechanism of DNA replication. Owing to averaging of observables, unique dynamic information of the biochemical pathways and reactions is concealed in conventional ensemble methods. However, recent advances in the rapidly expanding field of single-molecule analyses to study single biomolecules offer opportunities to probe and understand the dynamic processes involved in large biomolecular complexes such as replisomes. This review will focus on the recent developments in the biochemistry and biophysics of DNA replication employing single-molecule techniques and the insights provided by these methods towards a better understanding of the intricate mechanisms of DNA replication.     

Stimulation of replicative DNA synthesis by eukaryotic proteins bound to single-stranded DNA]

The paper deals with the effect of the single-strand (ss) DNA-binding proteins (SSB-proteins) from the Ehrlich ascites tumor (EAT) cells and from the eggs of silkworm, as well as the mouse serum blood proteins, having preferential affinity to ss DNA, on the DNA replicative synthesis in the EAT cells permeable for the macromolecules, and, for the silkworm proteins and on the DNA replicative synthesis in the nuclei from the eggs of silkworm proteins and on the DNA replicative synthesis in the nuclei from the eggs of silkworm permeable for macromolecules. SSB-proteins of EAT to considerable extent stimulated the DNA synthesis. At the same time, the other proteins (from the silkworm and from the serum) activated the DNA synthesis in the permeable cells to the less extent. It was found that SSB-proteins from the silkworm had a 1.5-13 fold stimulating effect on the DNA replicative synthesis in the homologous system (in the permeable nuclei). If the permeability for the macromolecules of the cells and nuclei treatment with Triton X-100 may be different, it is supposed that the activation of the DNA synthesis by the exogenous proteins depends on the homologous system of the DNA replicative complex. It is possible that the effect of the serum proteins on the DNA synthesis is connected with the masking of the ss regions of DNA which inhibited DNA-polymerase alpha. Perhaps the mechanisms of the activation of the DNA replicative synthesis by the proteins in vitro with the purified DNA polymerase alpha and in vivo are of different nature and are conditioned by homology of the deoxyribonucleoproteins.     

Replication of the lagging strand: a concert of at least 23 polypeptides.

DNA replication is one of the most important events in living cells, and it is still a key problem how the DNA replication machinery works in its details. A replication fork has to be a very dynamic apparatus since frequent DNA polymerase switches from the initiating DNA polymerase alpha to the processive elongating DNA polymerase delta occur at the leading strand (about 8 x 10(4) fold on both strands in one replication round) as well as at the lagging strand (about 2 x 10(7) fold on both strands in one replication round) in mammalian cells. Lagging strand replication involves a very complex set of interacting proteins that are able to frequently initiate, elongate and process Okazaki fragments of 180 bp. Moreover, key proteins of this important process appear to be controlled by S-phase check-point proteins. It became furthermore clear in the last few years that DNA replication cannot be considered uncoupled from DNA repair, another very important event for any living organism. The reconstitution of nucleotide excision repair and base excision repair in vitro with purified components clearly showed that the DNA synthesis machinery of both of these macromolecular events are similar and do share many components of the lagging strand DNA synthesis machinery. In this minireview we summarize our current knowledge of the components involved in the execution and regulation of DNA replication at the lagging strand of the replication fork.     

Human Cytomegalovirus Protein pUL117 Targets the Mini-Chromosome Maintenance Complex and Suppresses Cellular DNA Synthesis

Modulation of host DNA synthesis is essential for many viruses to establish productive infections and contributes to viral diseases. Human cytomegalovirus (HCMV), a large DNA virus, blocks host DNA synthesis and deregulates cell cycle progression. We report that pUL117, a viral protein that we recently identified, is required for HCMV to block host DNA synthesis. Mutant viruses in which pUL117 was disrupted, either by frame-shift mutation or by a protein destabilization-based approach, failed to block host DNA synthesis at times after 24 hours post infection in human foreskin fibroblasts. Furthermore, pUL117-deficient virus stimulated quiescent fibroblasts to enter S-phase, demonstrating the intrinsic ability of HCMV to promote host DNA synthesis, which was suppressed by pUL117. We examined key proteins known to be involved in inhibition of host DNA synthesis in HCMV infection, and found that many were unlikely involved in the inhibitory activity of pUL117, including geminin, cyclin A, and viral protein IE2, based on their expression patterns. However, the ability of HCMV to delay the accumulation of the mini-chromosome maintenance (MCM) complex proteins, represented by MCM2 and MCM4, and prevent their loading onto chromatin, was compromised in the absence of pUL117. When expressed alone, pUL117 slowed cell proliferation, delayed DNA synthesis, and inhibited MCM accumulation. Knockdown of MCM proteins by siRNA restored the ability of pUL117-deficient virus to block cellular DNA synthesis. Thus, targeting MCM complex is one mechanism pUL117 employs to help block cellular DNA synthesis during HCMV infection. Our finding substantiates an emerging picture that deregulation of MCM is a conserved strategy for many viruses to prevent host DNA synthesis and helps to elucidate the complex strategy used by a large DNA virus to modulate cellular processes to promote infection and pathogenesis.     

Dissection of RNA-primed DNA synthesis catalyzed by gene 4 protein and DNA polymerase of bacteriophage T7. Coupling of RNA primer and DNA synthesis

Gene 4 protein and DNA polymerase of bacteriophage T7 catalyze RNA-primed DNA synthesis on single-stranded DNA templates. T7 DNA polymerase exhibits an affinity for both gene 4 protein and single-stranded DNA, and gene 4 protein binds stably to single-stranded DNA in the presence of dTTP (Nakai, H. and Richardson, C. C. (1986) J. Biol. Chem. 261, 15208-15216). Gene 4 protein-T7 DNA polymerase-template complexes may be formed in both the presence and absence of nucleoside 5'-triphosphates. The protein-template complexes may be isolated free of unbound proteins and nucleotides by gel filtration and will catalyze RNA-primed DNA synthesis in the presence of ATP, CTP, and the four deoxynucleoside 5'-triphosphates. RNA-primed DNA synthesis may be dissected into separate reactions for primer synthesis and DNA synthesis. Upon incubation of gene 4 protein with single-stranded DNA, ATP, and CTP, a primer-template complex is formed; it is likely that gene 4 protein mediates stable binding of the oligonucleotide to the template. The complex, purified free of unbound proteins and nucleotides, supports DNA synthesis upon addition of DNA polymerase and deoxynucleoside 5'-triphosphates. Association of primers with the template is increased by the presence of dTTP or DNA polymerase during primer synthesis. DNA synthesis supported by primer-template complexes initiates predominantly at gene 4 recognition sequences, indicating that primers are bound to the template at these sites.     

Processive DNA synthesis by DNA polymerase II mediated by DNA polymerase III accessory proteins.

An interesting property of the Escherichia coli DNA polymerase II is the stimulation in DNA synthesis mediated by the DNA polymerase III accessory proteins beta,gamma complex. In this paper we have studied the basis for the stimulation in pol II activity and have concluded that these accessory proteins stimulate pol II activity by increasing the processivity of the enzyme between 150- and 600-fold. As is the case with pol III, processive synthesis by pol II requires both beta,gamma complex and SSB protein. Whereas the intrinsic velocity of synthesis by pol II is 20-30 nucleotides per s with or without the accessory proteins, the processivity of pol II is increased from approximately five nucleotides to greater than 1600 nucleotides incorporated per template binding event. The effect of the accessory proteins on the rate of replication is far greater on pol III than on pol II; pol III holoenzyme is able to complete replication of circular single-stranded M13 DNA in less than 20 s, whereas pol II in the presence of the gamma complex and beta requires approximately 5 min. We have investigated the effect of beta,gamma complex proteins on bypass of a site-specific abasic lesion by E. coli DNA polymerases I, II, and III. All three polymerases are extremely inefficient at bypass of the abasic lesion. We find limited bypass by pol I with no change upon addition of accessory proteins. pol II also shows limited bypass of the abasic site, dependent on the presence of beta,gamma complex and SSB. pol III shows no significant bypass of the abasic site with or without beta,gamma complex.     

Mode of inhibition of DNA synthesis induced by adenosine diphosphoribosylation of nuclear protein

DNA obtained after complete removal of the proteins from NAD-treated rat liver chromatin possessed template capacity equivalent to that obtained from untreated chromatin. The stepwise extraction of proteins from chromatin affected a gradual removal of labeled ADPR and a parallel decrease of the inhibition. The results of the present study suggest that the inhibition of the template capacity for DNA synthesis following preincubation of chromatin with NAD is dependent upon ADP-ribosylation of the associated proteins. The template capacity of chromatin and nucleoprotein complex (Weiss preparation) for DNA synthesis was inhibited, whereas the capacity for RNA synthesis was apparently not affected.     

Stimulation of the processivity of the DNA polymerase of bacteriophage T4 by the polymerase accessory proteins. The role of ATP hydrolysis

In this paper we examine the role of the DNA polymerase accessory proteins in modulating the processivity of DNA synthesis by the bacteriophage T4-coded five protein "holoenzyme" replication complex in vitro. Primed single-stranded DNA was used as a template for the DNA synthesis reactions, and buffer conditions were chosen to mimic in vivo salt concentrations. We find that the accessory proteins significantly increase the DNA-bound lifetime of the holoenzyme complex but that the maximum lifetime of the complex is still less than 10 s at 22 degrees C. The accessory proteins greatly enhance the processivity of the holoenzyme relative to that of the polymerase alone. ATP hydrolysis catalyzed by the accessory proteins complex is required to achieve this enhancement. We have investigated the temporal relationship between ATP hydrolysis by the accessory proteins and primer elongation by the holoenzyme and find that ATPase activity is required for initial assembly of the holoenzyme complex but not for elongation per se. Thus we conclude that the increased processivity displayed by the holoenzyme in moving through regions of template secondary structure reflects the high intrinsic processivity of the holoenzyme complex itself rather than a requirement for a concomitant ATPase-driven helicase activity during elongation. We have also measured the ATPase activity of the accessory proteins as a function of polymerase concentration and find that the rate of ATP hydrolysis catalyzed by this complex decreases significantly when the accessory proteins are assembled (with polymerase and gene 32 protein) into the five-protein holoenzyme and coupled to primer elongation. Based on these results we discuss mechanisms by which the ATPase activity of the polymerase accessory proteins might stimulate the overall processivity of the holoenzyme.     

Structural anatomy of telomere OB proteins

Telomere DNA-binding proteins protect the ends of chromosomes in eukaryotes. A subset of these proteins are constructed with one or more OB folds and bind with G+T-rich single-stranded DNA found at the extreme termini. The resulting DNA-OB protein complex interacts with other telomere components to coordinate critical telomere functions of DNA protection and DNA synthesis. While the first crystal and NMR structures readily explained protection of telomere ends, the picture of how single-stranded DNA becomes available to serve as primer and template for synthesis of new telomere DNA is only recently coming into focus. New structures of telomere OB fold proteins alongside insights from genetic and biochemical experiments have made significant contributions towards understanding how protein-binding OB proteins collaborate with DNA-binding OB proteins to recruit telomerase and DNA polymerase for telomere homeostasis. This review surveys telomere OB protein structures alongside highly comparable structures derived from replication protein A (RPA) components, with the goal of providing a molecular context for understanding telomere OB protein evolution and mechanism of action in protection and synthesis of telomere DNA.     

Structural anatomy of telomere OB proteins

Telomere DNA-binding proteins protect the ends of chromosomes in eukaryotes. A subset of these proteins are constructed with one or more OB folds and bind with G+T-rich single-stranded DNA found at the extreme termini. The resulting DNA-OB protein complex interacts with other telomere components to coordinate critical telomere functions of DNA protection and DNA synthesis. While the first crystal and NMR structures readily explained protection of telomere ends, the picture of how single-stranded DNA becomes available to serve as primer and template for synthesis of new telomere DNA is only recently coming into focus. New structures of telomere OB fold proteins alongside insights from genetic and biochemical experiments have made significant contributions towards understanding how protein-binding OB proteins collaborate with DNA-binding OB proteins to recruit telomerase and DNA polymerase for telomere homeostasis. This review surveys telomere OB protein structures alongside highly comparable structures derived from replication protein A (RPA) components, with the goal of providing a molecular context for understanding telomere OB protein evolution and mechanism of action in protection and synthesis of telomere DNA.     

DNA replication by bacteriophage T4 proteins. The T4 43, 32, 44--62, And 45 proteins are required for strand displacement synthesis at nicks in duplex DNA.

The T4 bacteriophage gene 43 (T4 DNA polymerase), 32 (DNA helix-destabilizing protein), and 45 proteins and the complex of the gene 44 and 62 proteins are all required for DNA synthesis beginning at single-stranded breaks in duplex DNA. This synthesis occurs by strand displacement and is not dependent on ribonucleotides, the T4 gene 41 protein, or the T4 initiating protein, each of which is required to begin new chains on single-stranded templates. Electron microscopic analysis shows that duplex molecules with long single-stranded branches are the predominant products of this strand displacement synthesis.     

ClpX protein of Escherichia coli activates bacteriophage Mu transposase in the strand transfer complex for initiation of Mu DNA synthesis.

During transposition bacteriophage Mu transposase (MuA) catalyzes the transfer of a DNA strand at each Mu end to target DNA and then remains tightly bound to the Mu ends. Initiation of Mu DNA replication on the resulting strand transfer complex (STC1) requires specific host replication proteins and host factors from two partially purified enzyme fractions designated Mu replication factors alpha and beta (MRFalpha and beta). Escherichia coli ClpX protein, a molecular chaperone, is a component required for MRFalpha activity, which removes MuA from DNA for the establishment of a Mu replication fork. ClpX protein alters the conformation of DNA-bound MuA and converts STC1 to a less stable form (STC2). One or more additional components of MRFalpha (MRFalpha2) displace MuA from STC2 to form a nucleoprotein complex (STC3), that requires the specific replication proteins and MRFbeta for Mu DNA synthesis. MuA present in STC2 is essential for its conversion to STC3. If MuA is removed from STC2, Mu DNA synthesis no longer requires MRFalpha2, MRFbeta and the specific replication proteins. These results indicate that ClpX protein activates MuA in STC1 so that it can recruit crucial host factors needed to initiate Mu DNA synthesis by specific replication enzymes.