Two membrane sites for DNA synthesis in Pneumococcus.

Summary A DNA membrane fraction extracted from pneumococci can be separated into two subfractions with respect to macromolecular composition and DNA synthesis by centrifugation in a 30–60% w/v neutral sucrose gradient. Each fraction can be rebanded in a sucrose gradient or centrifuged to equilibrium in a CsCl density gradient without altering the ability of the fractions to synthesize DNA. The fast sedimenting (heavy) fraction contains 45% of the DNA, and the bulk of the phospholipid, protein, and RNA. The light fraction contains 50% of the DNA, and lower, but significant amounts of phospholipid, RNA, and protein. Both fractions contain a DNA replication complex consisting of a number of enzymes involved in synthesizing DNA or DNA precursors, as well as RNA polymerase activity. However, the specific activity of DNA polymerase in the light fraction is much greater than that in the heavy fraction. In addition, the following results suggest that the former is concerned primarily with replication of the genome while the latter has characteristics of a repair function for the genome. (1) newly synthesized DNA can be detected within 30 s in the light fraction but not until 4 min in the heavy fraction. (2) an RNA-DNA single-stranded hybrid can be demonstrated during initial stages of DNA synthesis in the light, but not heavy fraction. (3) extensive semiconservative DNA replication occurs in the light fraction, whereas little such replication is detected in the heavy fraction. (4) DNA polymerase activity in the light fraction has several of the characteristics of a polymerase identified by others as being concerned with normal DNA replication, such as inhibition by N-ethylmaleimide, and relatively high rates of chain elongation (4.9×10⁴ nucleotides/min). In contrast, DNA polymerase activity in the heavy fraction has characteristic properties associated with DNA polymerase I, a possible repair enzyme. These include higher activity for a d(A-T)n template than that detected in the light fraction, no effect of N-ethylmaleimide, and relatively low rates of chain elongation (9×10³ nucleotides/min).     

Purification of DNA polymerase delta as an essential simian virus 40 DNA replication factor.

DNA replication from the SV40 origin can be reconstituted in vitro using purified SV40 large T antigen, cellular topoisomerases I and II, replication factor A (RF-A), proliferating cell nuclear antigen (PCNA), replication factor C (RF-C), and a phosphocellulose fraction (IIA) made from human cell extracts (S100). Fraction IIA contains all DNA polymerase activity required for replication in vitro in addition to other factors. A newly identified factor has been purified from fraction IIA. This factor is required for complete reconstitution of SV40 DNA replication and co-purifies with a PCNA-stimulated DNA polymerase activity. This DNA polymerase activity is sensitive to aphidicolin, but is not inhibited by butylanilinodeoxyadenosine triphosphate or by monoclonal antibodies which block synthesis by DNA polymerase alpha. The polymerase activity is synergistically stimulated by the combination of RF-A, PCNA, and RF-C in an ATP-dependent manner. Purified calf thymus polymerase delta can fully replace the purified factor in DNA replication assays. We conclude that this factor, required for reconstitution of SV40 DNA replication in vitro, corresponds to human DNA polymerase delta.     

Pea chloroplast DNA primase: characterization and role in initiation of replication

A DNA primase activity was isolated from pea chloroplasts and examined for its role in replication. The DNA primase activity was separated from the majority of the chloroplast RNA polymerase activity by linear salt gradient elution from a DEAE-cellulose column, and the two enzyme activities were separately purified through heparin-Sepharose columns. The primase activity was not inhibited by tagetitoxin, a specific inhibitor of chloroplast RNA polymerase, or by polyclonal antibodies prepared against purified pea chloroplast RNA polymerase, while the RNA polymerase activity was inhibited completely by either tagetitoxin or the polyclonal antibodies. The DNA primase activity was capable of priming DNA replication on single-stranded templates including poly(dT), poly(dC), M13mp19, and M13mp19_+ 2.1, which contains the AT-rich pea chloroplast origin of replication. The RNA polymerase fraction was incapable of supporting incorporation of ³H-TTP in in vitro replication reactions using any of these single-stranded DNA templates. Glycerol gradient analysis indicated that the pea chloroplast DNA primase (115–120 kDa) separated from the pea chloroplast DNA polymerase (90 kDa), but is much smaller than chloroplast RNA polymerase. Because of these differences in size, template specificity, sensitivity to inhibitors, and elution characteristics, it is clear that the pea chloroplast DNA primase is an distinct enzyme form RNA polymerase. In vitro replication activity using the DNA primase fraction required all four rNTPs for optimum activity. The chloroplast DNA primase was capable of priming DNA replication activity on any single-stranded M13 template, but shows a strong preference for M13mp19+2.1. Primers synthesized using M13mp19+2.1 are resistant to DNase I, and range in size from 4 to about 60 nucleotides.     

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.     

Evidence for contamination of origin DNA isolated after an in vivo treatment of mammalian cells with 4,5′,8-trimethylpsoralen

We have studied the effect of in vivo treatment with trioxsalen on DNA replication in mammalian cells. In vitro cultured bovine liver cells were exposed to two or four cycles of treatment with 45 μM trioxsalen followed by irradiation with long-wave ultraviolet light. Thymidine incorporation was reduced by about 95% during the first hour after a double treatment. A large proportion of the label was released in alkaline sucrose gradients as a low molecular weight fraction (average length about 500 nucleotides) which was supposed to consist of replication origins containing DNA fragments. From the relative quantities of this DNA obtained at different times of the S phase we concluded that it contains a considerable but not precisely determinable proportion of non-origin DNA. We also find that the fraction is contaminated by a large excess of non-replicating bulk DNA.     

Initiation of DNA synthesis in a high molecular weight fraction of Xenopus egg extract.

Xenopus egg extract was fractionated by gel-filtration column chromatography and DNA synthetic activity was examined using double-stranded DNA as a template. The major activity eluted had an apparent molecular mass of about 300 kDa. Product analyses showed that de novo DNA synthesis occurs with formation of replication bubbles, thereby suggesting that this fraction catalyzes the initiation of DNA replication. Activities of DNA polymerase α-primase and DNA helicase overlapped with the DNA synthetic activity, but the elution profiles of the enzymes differed from that of the DNA synthetic activity. Therefore, this 300-kDa fraction may contain a component which differs from the above enzymes yet is essential for initiation of DNA replication.     

Evidence for contamination of origin DNA isolated after an in vivo treatment of mammalian cells with 4,5',8-trimethylpsoralen

We have studied the effect of in vivo treatment with trioxsalen on DNA replication in mammalian cells. In vitro cultured bovine liver cells were exposed to two or four cycles of treatment with 45 microM trioxsalen followed by irradiation with long-wave ultraviolet light. Thymidine incorporation was reduced by about 95% during the first hour after a double treatment. A large proportion of the label was released in alkaline sucrose gradients as a low molecular weight fraction (average length about 500 nucleotides) which was supposed to consist of replication origins containing DNA fragments. From the relative quantities of this DNA obtained at different times of the S phase we concluded that it contains a considerable but not precisely determinable proportion of non-origin DNA. We also find that the fraction is contaminated by a large excess of non-replicating bulk DNA.     

A unique subpopulation of murine DNA polymerase alpha/primase specifically interacts with polyomavirus T antigen and stimulates DNA replication.

Murine cells or cell extracts support the replication of plasmids containing the replication origin (ori-DNA) of polyomavirus (Py) but not that of simian virus 40 (SV40), whereas human cells or cell extracts support the replication of SV40 ori-DNA but not that of Py ori-DNA. It was shown previously that fractions containing DNA polymerase alpha/primase from permissive cells allow viral ori-DNA replication to proceed in extracts of nonpermissive cells. To extend these observations, the binding of Py T antigen to both the permissive and nonpermissive DNA polymerase alpha/primase was examined. Py T antigen was retained by a murine DNA polymerase alpha/primase but not by a human DNA polymerase alpha/primase affinity column. Likewise, a Py T antigen affinity column retained DNA polymerase alpha/primase activity from murine cells but not from human cells. The murine fraction which bound to the Py T antigen column was able to stimulate Py ori-DNA replication in the nonpermissive extract. However, the DNA polymerase alpha/primase activity in this murine fraction constituted only a relatively small proportion (approximately 20 to 40%) of the total murine DNA polymerase alpha/primase that had been applied to the column. The DNA polymerase alpha/primase purified from the nonbound murine fraction, although far more replete in this activity, was incapable of supporting Py DNA replication. The two forms of murine DNA polymerase alpha/primase also differed in their interactions with Py T antigen. Our data thus demonstrate that there are two distinct populations of DNA polymerase alpha/primase in murine cells and that species-specific interactions between T antigen and DNA polymerases can be identified. They may also provide the basis for initiating a novel means of characterizing unique subpopulations of DNA polymerase alpha/primase.     

Evidence for participation of a multiprotein complex in yeast DNA replication in vitro

Fractions containing a high molecular weight form (Mr approximately equal to 2 X 10(6] of the activity that replicates in vitro both the 2-micron yeast DNA plasmid and the chromosomal autonomously replicating sequence ars 1 can be prepared from cells of the budding yeast Saccharomyces. Protein complexes from the fractions associate in vitro with the replication origins of these DNA elements, as determined by electron microscopy. In the present study, the high molecular weight replicative fraction has been characterized in further detail. The DNA synthetic activity in the high molecular weight fraction was bound to the DNA and could be isolated with it. This binding of the replicating activity to the DNA was greatly reduced in the absence of the 2-micron origins of replication. Association of the protein complexes with DNA depended on the amount of replicating activity added, was sensitive to 0.2 M KCl, and exhibited a requirement for rATP and deoxyribonucleoside triphosphates. It was not blocked, however, by the DNA polymerase inhibitor aphidicolin or by the RNA polymerase inhibitor alpha-amanitin. The lack of inhibition by aphidicolin suggests that the deoxyribonucleoside triphosphates may function as cofactors in the binding of protein complexes to DNA or as substrates for a polymerizing activity such as a primase. Binding of the protein complexes as well as actual DNA replication were heat sensitive in the high molecular weight fraction prepared from the temperature-sensitive mutant of the cell division cycle cdc 8. This suggests that the cdc 8 gene product is present in a replicative protein complex and strengthens the conclusion that the presence of the protein complexes on the DNA is associated with replication. Using independent enzyme assays, several other possible replication proteins (including DNA polymerase I, DNA ligase, DNA primase, and DNA topoisomerase II) have been identified directly in the high molecular weight replicative fraction. All of these results provide support for the idea that a protein complex (or replisome ) is involved in the replication of both the extrachromosomal 2-micron DNA and chromosomal DNA in yeast.     

SELECTIVE INHIBITION BY APHIDICOLIN OF THE ACTIVITY OF DNA POLYMERASE ALPHA LEADS TO BLOCKADE OF DNA SYNTHESIS AND CELL DIVISION IN SEA URCHIN EMBRYOS

Aphidicolin at 2 μg/ml caused 90% inhibition of mitotic cell division of sea urchin embryos at the I-cell stage. However, at 40 μg/ml it did not affect meiotic maturational divisions of starfish oocytes, which do not involve DNA replication. At 2 μg/ml it caused 90% inhibition of incorporation of tritiated thymidine into DNA of sea urchin embryos but did not affect protein or RNA synthesis even at a higher concentration. At 2 μg/ml it also caused 90% inhibition of the activity of DNA polymerase α, obtained from the nuclear fraction of sea urchin embryos, but did not affect the activity of DNA polymerase β or γ. These findings suggest that DNA polymerase α is responsible for replication of DNA in sea urchin embryos.     

Pre-steady state kinetic studies show that an abasic site is a cognate lesion for the yeast Rev1 protein

Rev1 is a eukaryotic DNA polymerase that rescues replication forks stalled at sites of DNA damage by inserting nucleotides opposite the damaged template bases. Yeast genetic studies suggest that Rev1 plays an important role in rescuing replication forks stalled at one of the most common forms of DNA damage, an abasic site; however, steady state kinetic studies suggest that an abasic site acts as a significant block to nucleotide incorporation by Rev1. Here we examined the pre-steady state kinetics of nucleotide incorporation by yeast Rev1 with damaged and non-damaged DNA substrates. We found that yeast Rev1 is capable of rapid nucleotide incorporation, but only a small fraction of the protein molecules possessed this robust activity. We characterized the nucleotide incorporation by the catalytically robust fraction of yeast Rev1 and found that it efficiently incorporated dCTP opposite a template abasic site under pre-steady state conditions. We conclude from these studies that the abasic site is a cognate lesion for Rev1.     

Inhibition of DNA synthesis at the hemimethylated pBR322 origin of replication by a cell membrane fraction.

The replication of both ColE1-type plasmids and plasmids bearing the origin of replication of the Escherichia coli chromosome (oriC) has been shown to be inhibited by hemimethylation of adenine residues within GATC sequences. In the case of oriC plasmids, this inhibition was previously shown to be mediated by the specific affinity of the hemimethylated origin DNA for an outer cell membrane fraction. Here, we suggest that a similar mechanism is operating in the case of the ColE1-like plasmid pBR322 as (i) a hemimethylated DNA fragment carrying the promoter for the RNA which primes DNA synthesis (RNAII) is specifically bound by the same membrane fraction and, (ii) the addition of the membrane fraction to a soluble assay of pBR322 replication results in preferential inhibition of initiation on the hemimethylated template. We suggest that membrane sequestration of hemimethylated origin DNA and/or associated replication genes following replication may be a common element restricting DNA replication to precise moments in the cell cycle.     

Enrichment and visualization of small replication units from cultured mammalian cells

DNA from cultured Chinese hamster cells has been fractionated to yield a population of DNA enriched for replicating molecules. Molecules containing replication structures were analyzed by electron microscopy, and replicon size was estimated. The enrichment procedure takes advantage of single-stranded regions characteristic of replicating molecules, and the greater affinity of mercuric ion for single-stranded rather than native DNA. After interaction with low concentrations of HgCl2, DNA with bound mercury is separated from the bulk of the DNA by virtue of its increased buoyant density in an isopycnic Cs2SO4 gradient. When DNA from cells labeled with [3H]thymidine for 45 s is interacted with HgCl2 and banded in Cs2SO4, the DNA with the highest specific activity is found in a dense region of the gradient. The high specific activity DNA behaves kinetically like nascent DNA since the radioactivity can be chased into main band if the cells are incubated for a further 2 h in excess unlabeled thymidine. Electron microscope analysis of the DNA in the enriched fraction confirmed that it contains a substantial fraction of molecules with replication structures. The level of enrichment is about 25-fold compared to unfractionated DNA or DNA taken from the main band of the Hg++/Cs2SO4 gradient. Of the replicating molecules visualized, 85% possessed a single replication structure. All molecules with multiple replication forms contained replicon sizes less than 5 micron, ranging from 0.2 to 4.5 micron. Replicon size was determined by measuring the distance from the center of one replication structure to the center of the adjacent replication structure on the same molecule. The replicons observed in this study are far smaller than can be detected by DNA fiber autoradiography and are in the same size range as the very small replication units reported in embryonic systems.     

Cellular factors required for papillomavirus DNA replication.

In vitro replication of papillomavirus DNA has been carried out with a combination of purified proteins and partially purified extracts made from human cells. DNA synthesis requires the viral E1 protein and the papillomavirus origin of replication. The E2 protein stimulates DNA synthesis in a binding site-independent manner. Papillomavirus DNA replication is also dependent on the cellular factors replication protein A, replication factor C, and proliferating-cell nuclear antigen as well as a phosphocellulose column fraction (IIA). Fraction IIA contains DNA polymerase alpha-primase and DNA polymerase delta. Both of these polymerases are essential for papillomavirus DNA replication in vitro. However, unlike the case with T-antigen-dependent replication from the simian virus 40 origin, purified DNA polymerase alpha-primase and delta cannot efficiently replace fraction IIA in the replication reaction. Hence, additional cellular factors seem to be required for papillomavirus DNA replication. Interestingly, replication factor C and proliferating-cell nuclear antigen are more stringently required for DNA synthesis in the papillomavirus system than in the simian virus 40 in vitro system. These distinctions indicate that there must be mechanistic differences between the DNA replication systems of papillomavirus and simian virus 40.     

Mitogenic and antimitogenic effects of cholera toxin-mediated cyclic AMP levels in 3T3 cells

The effect of time-controlled exposures to cholera toxin (CT) on intracellular levels of cyclic AMP (cAMP) and on the proliferative response of serum-stimulated 3T3 cells was investigated. Continuous exposure to CT caused up to 8-fold raises in cAMP content and inhibited DNA replication by delaying G1-S transition and by reducing the fraction of cells committed to DNA replication. In contrast, short exposures to CT during G0-G1 transition increased the fraction of cells responding to serum stimulation and potentiated the serum-induced morphological changes in the cell monolayer. A short exposure during late G1 phase, however, inhibited the onset of DNA synthesis but had little effect on ongoing DNA replication. The results indicate that cAMP has diverse and opposite effects on two defined restriction points in cell cycle control. Cyclic AMP was positively involved in the acquisition of the state of competence by quiescent cells (G0-G1 transition) but antagonistic on the onset of DNA replication (G1-S transition) in committed cells. The observations reconcile a number of controversial conclusions regarding the role of cAMP in cell cycle control.     

Requirement of a Cytoplasmic Fraction for Synthesis of SV40 Deoxyribonucleic Acid in Isolated Nuclei*.

About 50% of the SV40 DNA in the process of replication (sv40(ri) dna) completed replication in lysates of infected BSC-1 cells by conversion to covalently closed, superhelical SV40 DNA (SV40(I) DNA). Fractionation of the lysate into nuclear and cytoplasmic components blocked 99% of the synthesis of SV40(I) DNA in the purified nuclei. The reconstituted system, made by adding back the cytoplasmic fraction before incubation at 30 degrees, completely restored the in vitro level of SV40(I) DNA synthesis. Preliminary characterization of the activity found in the cytoplasmic fraction suggested it was a soluble, heat-labile protein (or proteins) with a minimum molecular weight of about 30,000 and an active sulfhydryl group. The activity was present in both infected and uninfected monkey cells, and at a lower level in mouse, hamster, and human cell lines. Neither serum starvation nor cycloheximide treatment of cells diminished the activity in the cytoplasmic fraction. Purified cytoplasmic DNA polymerase from KB cells did not substitute for the cytoplasmic fraction which was required for elongation of newly synthesized DNA strands. In the absence of the cytoplasmic fraction, conversion of 4 S DNA into longer strands was inhibited, and SV40(RI) DNA appeared to be broken specifically at the replication forks.     

A large-tumor-antigen-specific monoclonal antibody inhibits DNA replication of simian virus 40 minichromosomes in an in vitro elongation system.

In productively infected cells, a fraction of large-tumor antigen (T antigen) is tightly bound to replicating simian virus 40 (SV40) minichromosomes and does not dissociate at salt concentrations of greater than 1 M NaCl. We present electronmicrograms demonstrating the presence of T antigen on the replicated sections of replicating SV40 minichromosomes. We also show that the fraction of tightly bound T antigen is recognized by antibodies from mouse tumor serum and, more specifically, by a particular T-antigen-specific monoclonal antibody, PAb 1630. A second T-antigen-specific monoclonal antibody, PAb 101, does not react with the T-antigen fraction remaining on replicating SV40 chromatin at high salt concentrations. We used an in vitro replication system which allows, via semiconservative DNA replication, the completion of in vivo-initiated replicative intermediate DNA molecules. We show that monoclonal antibody PAb 1630, but not monoclonal antibody PAb 101, inhibits viral DNA replication. We discuss the possibility that SV40 T antigen may play a role in chain elongation during SV40 chromatin replication.     

Mutation and DNA replication in Escherichia coli treated with low concentrations of N-methyl-N′-nitro-N-nitrosoguanidine

N-Methyl-N′-nitro-N-nitrosoguanidine (nitrosoguanidine) causes an unexpectedly high frequency of closely linked double mutants because of its specificity for chromosome regions in replication. Low nitrosoguanidine concentrations (1 μg/ml) in liquid cultures allow replication at the normal rate and are mutagenic. It was expected that mutations would be spread over the chromosome as it replicated, but a high frequency of closely linked double mutants was found.If a thymine auxotroph is grown in the presence of 5-bromodeoxyuridine (BUdR) and nitrosoguanidine, then exposed to 313-nm radiation (which destroys BUdR-substituted DNA), the mutation frequency is much higher among survivors than among non-irradiated cells. It is concluded that nitrosoguanidine inhibits DNA replication in a small fraction of the population and that mutations are induced in that same fraction.Nitrosoguanidine treatment leads to a high frequency of closely linked double mutants under all known conditions.