On the specificity of interaction between the Saccharomyces cerevisiae clamp loader replication factor C and primed DNA templates during DNA replication

Replication factor C (RFC) catalyzes assembly of circular proliferating cell nuclear antigen clamps around primed DNA, enabling processive synthesis by DNA polymerase during DNA replication and repair. In order to perform this function efficiently, RFC must rapidly recognize primed DNA as the substrate for clamp assembly, particularly during lagging strand synthesis. Earlier reports as well as quantitative DNA binding experiments from this study indicate, however, that RFC interacts with primer-template as well as single- and double-stranded DNA (ssDNA and dsDNA, respectively) with similar high affinity (apparent K(d) approximately 10 nm). How then can RFC distinguish primed DNA sites from excess ssDNA and dsDNA at the replication fork? Further analysis reveals that despite its high affinity for various DNA structures, RFC selects primer-template DNA even in the presence of a 50-fold excess of ssDNA and dsDNA. The interaction between ssDNA or dsDNA and RFC is far less stable than between primed DNA and RFC (k(off) > 0.2 s(-1) versus 0.025 s(-1), respectively). We propose that the ability to rapidly bind and release single- and double-stranded DNA coupled with selective, stable binding to primer-template DNA allows RFC to scan DNA efficiently for primed sites where it can pause to initiate clamp assembly.     

Discontinuous DNA replication of Drosophila melanogaster is primed by octaribonucleotide primer.

To investigate the precise structure of eucaryotic primer RNA made in vivo, short DNA chains isolated from nuclei of Drosophila melanogaster embryos were analyzed. Post-labeling of 5' ends of short DNA chains with polynucleotide kinase and [gamma-32P]ATP revealed that 7% of the DNA fragments were covalently linked with mono- to octaribonucleotide primers at their 5' ends. Octaribonucleotides, the major component (ca. 30%), formed the cap structure in the reaction with vaccinia guanylyltransferase and [alpha-32P]GTP, indicating that they were the intact primer RNA with tri- (or di-) phosphate termini, and the shorter ribooligomers were degradation intermediates. The intact primers started with purine (A/G ratio, 4:1), and the starting few ribonucleotide residues were rich in A.     

Bacteriophage lambda replication proteins: formation of a mixed oligomer and binding to the origin of lambda DNA

Summary The purified bacteriophage replication proteins O and P sediment separately in metrizamide gradients of low ionic strength as dimers. Together they interact with each other forming an oligomer, composed of two molecules of O and one molecule of P. The O-P oligomer is active in the in vitro replication of ori-containing DNA.Equilibrium sedimentation in preformed metrizamide density gradients under conditions that separate DNA-protein complexes from free proteins was employed in order to study possible interactions among the replication proteins and ori DNA. It was found that the P protein binds specifically to ori-containing plasmid DNA only in the presence of O protein. About 100 molecules of O and 10 molecules of P form a complex with the ori DNA. The DNA-O-P complex was shown to be active in an in vitro replication system.Since the physical interactions between ori and O and between P and the Escherichia coli dnaB replication protein are well documented, the evidence for a O-P interaction presented in this paper provides the missing link in the molecular mechanism that enables to direct the host replication machinery to the replication of its own DNA.     

Modeling the mechanics of a DNA oligomer

DNA stretching and strand separation have been studied by molecular mechanics using an oligomer which has been the subject of nanomanipulation experiments (Noy et al., Chem. Biol. 4, 519, 1997). Adiabatic mapping of conformational energy carried out as a function of stretching leads to force/extension curves in good correlation with the experimental results. Other types of deformation are also modeled and compared with the experimental results obtained on polymeric DNA. The results highlight overall similarities, but point to thermodynamic differences and also to local base sequence effects which can be expected to play an important role at the level of biologically induced structural deformations.     

The coupling of epigenome replication with DNA replication

In multicellular organisms, each cell contains the same DNA sequence, but with different epigenetic information that determines the cell specificity. Semi-conservative DNA replication faithfully copies the parental nucleotide sequence into two DNA daughter strands during each cell cycle. At the same time, epigenetic marks such as DNA methylation and histone modifications are either precisely transmitted to the daughter cells or dynamically changed during S-phase. Recent studies indicate that in each cell cycle, many DNA replication related proteins are involved in not only genomic but also epigenomic replication. Histone modification proteins, chromatin remodeling proteins, histone variants, and RNAs participate in the epigenomic replication during S-phase. As a consequence, epigenome replication is closely linked with DNA replication during S-phase.     

Sequence-specific functions of the early palindrome domain within the SV40 core origin of replication.

The early palindrome domain within the SV40 core origin of replication is essential for the initiation of replication. Studies with single point mutants in this region suggested that the early palindrome domain does not function as a cruciform structure, but may be involved in the initiation of SV40 DNA replication in a sequence-specific manner. Two mutants, base-substituted at a primase initiation site nucleotide 5214, showed dramatic decreases in DNA replication in monkey cells. Despite earlier reports to the contrary, disruption of the cruciform configuration or polypyrimidine tract does not invariably lead to lack of replication function, as some mutants unable to form this structure replicate normally. Gel retention assays and DNase I footprinting with the nuclear proteins of monkey cells showed that the 5'GAGGC3' pentanucleotide repeats on either side of early palindrome domain interact with monkey nuclear protein. The early palindrome domain may affect the interaction of SV40 DNA with nuclear protein, and participate in SV40 DNA replication.     

Scoring schemes of palindrome clusters for more sensitive prediction of replication origins in herpesviruses

Many empirical studies show that there are unusual clusters of palindromes, closely spaced direct and inverted repeats around the replication origins of herpesviruses. In this paper, we introduce two new scoring schemes to quantify the spatial abundance of palindromes in a genomic sequence. Based on these scoring schemes, a computational method to predict the locations of replication origins is developed. When our predictions are compared with 39 known or annotated replication origins in 19 herpesviruses, close to 80% of the replication origins are located within 2% of the genome length. A list of predicted locations of replication origins in all the known herpesviruses with complete genome sequences is reported.     

On the origin of oligomer forms of polyoma DNA

Polyoma virus DNA synthesized in the presence of puromycin or cycloheximide contains an increased proportion of oligomers and molecules having a reduced number of tertiary turns. When doses of inhibitors producing a sub-maximal effect are used, molecules with an anomalous tertiary structure are more frequent among the oligomers than among the monomers. It is suggested that protein synthesis inhibitors modify the balance of factors controlling the topological constraints imposed on replicating molecules. Hence, final closure of the chains upon completion of replication would result in the formation of a mature product with an altered tertiary structure which sometimes fails to segregate into two daughter molecules.     

The distribution and properties of RNA primed initiation sites of DNA synthesis at the replication origin of Escherichia coli chromosome.

RNA-linked DNA molecules were obtained from E. coli dnaCts cells synchronously initiating a new round of chromosome replication. The deoxynucleotides at the transition from primer RNA to DNA were 32P-labeled, and their positions were located on the nucleotide sequence of 1.4 kb genomic region (position -906 to +493) including the oriC and its leftside flanking region. In the r-strand (the counterclockwise strand), many strong transition sites were mapped in the left half portion of the oriC and a few weak sites in the left outside region. In the 1-strand (the clockwise strand), no transition sites were found inside the oriC but many weak sites were found in the left outside region. The results support the initiation mechanism in which the first leading strand synthesis starts with the r-strand counterclockwise from the oriC that is followed by the 1-strand synthesis on the displaced template strand on the left of oriC. Primer RNA molecules attached to the strong r-strand transition sites were only a few residues in length. Properties of the transition sites were discussed.     

Evidence that discontinuous DNA replication in Escherichia coli is primed by approximately 10 to 12 residues of RNA starting with a purine

Intact primer RNA for discontinuous DNA replication of Escherichia coli has been detected by specific labeling in vitro of its 5'-terminal tri- (or di-) phosphate group with vaccinia guanylyltransferase and [alpha-32P]GTP. A mutant defective either in RNase H or in both RNase H and DNA polymerase I accumulated about 10 or 30 times more intact primer RNA, respectively, than wild-type cells. The primers started with purine in an A to G ratio of 5 and the most abundant 5'-terminal dinucleotide sequence was (p)ppA-Pu. The chain length of the intact primer RNA was approximately 10 to 12 nucleotide residues. The structural properties of the E. coli primer RNa resemble those of the eukaryotic primer RNA.     

Eukaryotic oligomer frequencies are correlated with certain DNA helical parameters

Nucleotide sequences were converted into purine (R)-pyrimidine (Y) series and divided into several groups, embracing higher and lower organisms. The frequencies of R-Y doublets, triplets and quartets in each were calculated. Whereas eukaryotes uniformly show RR + YY greater than RY + YR, in bacteria and phage no such relationship is observed. The triplet and quartet patterns in higher organisms differ from those seen in prokaryotes. In the higher organisms a correlation is observed between the frequencies of triplets and quartets and some DNA structural parameters. Specifically, the most frequent triplets are those with minimal torsion angle deviations from a regular B-DNA. The most frequent quartets are those with minimal roll angle deviations. No such correlations are observed in prokaryotes. We therefore propose that in eukaryotic DNA, tight, smooth packaging imposes sequence constraints.     

A rapid method for determining sequences in DNA by primed synthesis with DNA polymerase

A simple and rapid method for determining nucleotide sequences in single-stranded DNA by primed synthesis with DNA polymerase is described. It depends on the use of Escherichia coli DNA polymerase I and DNA polymerase from bacteriophage T4 under conditions of different limiting nucleoside triphosphates and concurrent fractionation of the products according to size by ionophoresis on acrylamide gels. The method was used to determine two sequences in bacteriophage φX174 DNA using the synthetic decanucleotide A-G-A-A-A-T-A-A-A-A and a restriction enzyme digestion product as primers.     

Thermodynamics of interaction of a fluorescent DNA oligomer with the anti-tumour drug netropsin.

Fluorescence spectroscopy was used to study the interaction between the minor-groove-binding drug netropsin and the self-complementary oligonucleotide d(CTGAnPTTCAG)2 containing the fluorescent base analogue 2-aminopurine (nP). The binding of netropsin to this oligonucleotide causes strong quenching of the 2-aminopurine fluorescence, observed by steady-state as well as time-resolved spectroscopy. From fluorescence titrations, binding isotherms were recorded and evaluated. The parameters showed one netropsin binding site/oligonucleotide duplex and an association constant of about 10(5) M-1 at 25 degrees C, 3-4 orders of magnitude weaker than for an exclusive adenine/thymine host sequence. From the temperature dependence of the association constant the thermodynamic parameters were obtained as delta G = -29 kJ/mol, delta H = -12 kJ/mol and delta S = +55 J.mol-1.K-1 at 25 degrees C. These parameters resemble those of the interaction of poly[(dG-dC).(dG-dC)] with netropsin, indicating a mainly entropy-driven reaction. The amino group of 2-aminopurine, like that of guanine, resides in the minor groove of DNA. Therefore the relatively weak binding of netropsin to d(CTGAnPTTCAG)2 is probably related to partial blockage of the tight fit of netropsin into the preferred minor groove of an exclusive adenine/thymine host sequence.