Glutamate overcomes the salt inhibition of DNA polymerase III holoenzyme

Even though Escherichia coli can grow in media containing up to 1 M NaCl, one-fifth that amount of NaCl will completely inhibit the in vitro activity of DNA polymerase III holoenzyme. It has been established that the major intracellular ionic osmolytes are potassium and glutamate (Richey, B., Cayley, D. S., Mossing, M. C., Kolka, C., Anderson, C. F., Farrar, T. C., and Record, M. T., Jr. (1987) J. Biol. Chem. 262, 7157-7164). We have found that holoenzyme catalyzes replication efficiently in vitro in up to 1 M potassium glutamate. Two salt effects on the replication of single-stranded DNA were observed. At low salt replicative activity was enhanced and at high salt there was anion-specific inhibition. We have found that DNA polymerase III holoenzyme tolerated 10-fold higher concentrations of glutamate than chloride. The ability of various anions to extend the useful range of salt concentrations followed the order: phosphate less than chloride less than N-Ac-glutamate less than acetate less than glycine less than aspartate less than glutamate. With the exception of phosphate, this order followed the Hofmeister series indicating that the anion-specific effects were due to anions interacting at the protein-water interface at weak anion binding sites. Glutamate did not reverse the inhibition by chloride. The low salt enhancement and high salt inhibition effects were additive for the two anions indicating that they competed for common anion binding sites. The major salt-sensitive step was holoenzyme binding to template rather than the subsequent elongation reaction.     

Structural changes in simian virus 40 chromatin as probed by restriction endonucleases.

The structure of simian virus 40 (SV40) chromatin was probed by treatment with single- and multiple-site bacterial restriction endonucleases. Approximately the same fraction of the chromatin DNA was cleaved by each of three different single-site endonucleases, indicating that the nucleosomes do not have unique positions with regard to specific nucleotide sequences within the population of chromatin molecules. However, the extent of digestion was found to be strongly influenced by salt concentration. At 100 mM NaCl-5 mM MgCl2, only about 20% of the simian virus 40 (SV40) DNA I in chromatin was converted to linear SV40 DNA III. In contrast, at lower concentrations of NaCl (0.05 or 0.01 M), an additional 20 to 30% of the DNA was cleaved. These results suggest that at 100 mM NaCl only the DNA between nucleosomes was accessible to the restriction enzymes, whereas at the lower salt concentrations, DNA within the nucleosome regions became available for cleavage. Surprisingly, when SV40 chromatin was digested with multiple-site restriction enzymes, less than 2% of the DNA was digested to limit digest fragment, whereas only a small fraction (9 to 15%) received two or more cuts. Instead, the principal digest fragment was full-length linear SV40 DNA III. The failure to generate limit digest fragments was not a consequence of reduced enzyme activity in the reaction mixtures or of histone exchange. When the position of the principal cleavage site was mapped after HpaI digestion, it was found that this site was not unique. Nevertheless, all sites wree not cleaved with equal probability. An additional finding was that SV40 chromatin containing nicked-circular DNA II produced by random nicking of DNA I was also resistant to digestion by restriction enzymes. These results suggest that the initial cut which causes relaxation of topological constraint in SV40 chromatin DNA imparts resistance to further digestion by restriction enzymes. We propose that this may be accomplished by either "winding" of the internucleosomal DNA into the body of the nucleosome, or as suggested by others, by successive right-hand rotation of nucleosomes.     

Xenopus Cdc45-dependent loading of DNA polymerase alpha onto chromatin under the control of S-phase Cdk.

At the onset of S phase, chromosomal replication is initiated by the loading of DNA polymerase alpha onto replication origins. However, the molecular mechanisms for controlling the initiation are poorly understood. Using Xenopus egg extract, we report here the identification of a Xenopus homolog of Cdc45, a yeast protein essential for the initiation of replication, which is shown to be an essential molecule for the initiation of replication via the loading of DNA polymerase alpha onto chromatin. XCdc45, by physically interacting with the polymerase in the extract, became associated with chromatin only after nuclear formation. During S phase, XCdc45 co-localized with the polymerase in the nuclei, and the loading of the polymerase, which depended on endogenous XCdc45, was facilitated by exogenously added recombinant XCdc45. These findings, together with the apparent requirement of S-phase-cdk activity for the loading of XCdc45, suggest that XCdc45, under the control of S-phase cdk, plays a pivotal role in the loading of DNA polymerase alpha onto chromatin.     

Structural transitions of chromatin at low salt concentrations: a flow linear dichroism study

We have studied the structure of nuclease-solubilized chromatin from Ehrlich ascites cells by flow linear dichroism (LD) using the anisotropic absorption of the DNA bases and of two intercalated dyes, ethidium bromide and methylene blue. It is confirmed that intercalation occurs preferentially in the linker part of the chromatin fiber, at binding ratios (dye/base) below 0.020. Using this information, we determined the orientation of the linker in relation to the average DNA organization in chromatin. The LD measurements indicate that the conformation of chromatin is considerably changed in the ionic strength interval 0.1-10 mM NaCl: with increasing salt concentration, the LD of the intrinsic DNA base absorption changes signs, from negative to positive, at approximately 2.5 mM NaCl. The LD of the intercalated dyes also changes signs, however, at a somewhat higher salt concentration. The results are analyzed in terms of possible allowed combinations of tilt angles of nucleosomes and pitch or tilt angles of linker DNA sections relative to the fiber axis, at different salt concentrations in the interval 0.1-10 mM NaCl. Two models for the salt-induced structural change of chromatin are discussed.     

Histone-histone interaction mediates chromatin unfolding at physiological ionic strength

High-resolution thermal denaturation data on chicken erythrocyte chromatin are reported over 4 orders of magnitude in NaCl concentration which includes the physiological region. A novel technique using critical-point polyacrylamide sols instead of ordinary solvents effectively stabilizes chromatin against precipitation at high salt concentrations. These sols are optically transparent from 260 to 320 nm and are thermally stable over the temperature ranges studied. At Na+ ion concentrations below 10 mM, the polyacrylamide slightly destabilizes chromatin at the nucleosome level, possibly through interactions of histones H1 and H5 with the carboxylic acid residues. At the same low salts, polyacrylamide stabilizes pure DNA against denaturation, presumably by mechanically stabilizing it against helix-distorting thermal fluctuations. In both cases, however, the polyacrylamide sols are entirely noninvasive at higher salts. Prominent low-temperature thermal transitions are observed in chromatin at and above 100 mM NaCl which evidently are associated with conformational changes in DNA. Our results are in accord with the idea that histone-histone interactions at physiological ionic strengths (approximately 100 mM Na+) may be comparable to histone-DNA interactions and hence may be sufficient to promote the destabilization of the DNA helix in chromatin under these conditions. The biological implications of this are discussed, and a possible model for the local decondensation of chromatin under physiological conditions is proposed.     

Initiation of eukaryotic DNA replication: origin unwinding and sequential chromatin association of Cdc45, RPA, and DNA polymerase alpha

We report that a plasmid replicating in Xenopus egg extracts becomes negatively supercoiled during replication initiation. Supercoiling requires the initiation factor Cdc45, as well as the single-stranded DNA-binding protein RPA, and therefore likely represents origin unwinding. When unwinding is prevented, Cdc45 binds to chromatin whereas DNA polymerase alpha does not, indicating that Cdc45, RPA, and DNA polymerase alpha bind chromatin sequentially at the G1/S transition. Whereas the extent of origin unwinding is normally limited, it increases dramatically when DNA polymerase alpha is inhibited, indicating that the helicase that unwinds DNA during initiation can become uncoupled from the replication fork. We discuss the implications of these results for the location of replication start sites relative to the prereplication complex.     

Replicative activity of isolated chromatin from proliferating and quiescent early passage and aging cultured mouse cells

Replicative activity of isolated chromatin from late passage cultured mouse cells has been compared to the activities of chromatin preparaions from dividing and quiescent early passage cells. Rates of endogenous DNA synthesis are similar for chromatin from growing or resting cells but this activity is stimulated 2.5-fold in senescent cell chromatin. Chromatin from growing young cells copies exogenously added single stranded DNA at the highest efficiency. Chromatin of senescent cells copies this template at a lower rate and resting young cell chromatin replicates single stranded DNA at the lowest efficiency. Similar relative rates are obtained when activated DNA is copied by the various chromatin preparations. Total activity of DNA polymerase extracted by salt from chromatin is similar for dividing and quiescent young cells but the proportion of DNA polymerase beta is higher in the latter. Elevated activities of DNA polymerases are extracted from chromatin of old cells. It is concluded, therefore, that chromatin-directed replication is differently arrested in non-dividing senescent cells and in quiescent early passage cells. The possible regulatory mechanisms of DNA replication in quiescence and aging are discussed.     

Influence of histone H1 on chromatin structure

Removal of histone H1 produces a transition in the structure of chromatin fibers as observed by electron microscopy. Chromatin containing all histone proteins appears as fibers with a diameter of about 250 A. The nucleosomes within these fibers are closely packed. If histone H1 is selectively removed with 50-100 mM NaCl in 50 mM sodium phosphate buffer (pH 7.0) in the presence of the ion-exchange resin AG 50 W - X2, chromatin appears as "beads-on-a-string" with the nucleosomes separated from each other by distances of about 150-200 A. If chromatin is treated in the presence of the resin with NaCl at concentrations of 650 mM or more, the structural organization of the chromatin is decreased, yielding fibers of irregular appearance.     

Properties of chromatin subunits from developing trout testis.

When a sample of trout testis nuclei is digested with micrococcal nuclease, the DNA is cleaved almost entirely to discrete fragments approximately 200 base pairs long and multiples thereof. The same DNA fragments can be obtained when isolated chromatin, as opposed to intact nuclei, is nuclease digested. These DNA fragments can also be found in discrete chromatin "subunits" isolated from nuclease-digested nuclei. Sedimentation through sucrose gradients or velocity sedimentation in an analytical ultracentrifuge separates these chromatin subunits into 11 S (monomer), 16 S (dimer), and 22 S (trimer) etc. species. Subunits can also be fractionated on a Sepharose 2B column equilibrated and run in low salt. High salt (greater than 40 mM NaCl) or divalent cations (congruent to 5 mM) cause subunit precipitation. Chromatin subunits have a protein to DNA ratio of approximately 1.2 and contain all the histones, including the trout-specific histone T. There are, however, no detectable nonhistone chromosomal proteins. Mg-2+ precipitates of the 11 S chromatin monomers, when pelleted, are thin and clear, while oligomer Mg-2+ pellets are thick and white. This could reflect a more symmetrical or ordered packing of 11 S monomers, which are deficient in histone I. This histone may cross-link the larger oligomers, resulting in a disordered Mg-2+ complex. These results are consistent with the subunit model of chromatin structure, based on 200 base pair long regions of DNA associated with histones. These subunits would be separated by nuclease-sensitive DNA spacer regions and cross-linked by histone I.     

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.     

Chromatin aggregation depends on the anion species of the salts

The effects of anions on chromatin aggregation may be classified into three categories. First, monovalent anions, glutamate, acetate, chloride, and thiocyante, follow the lyotropic series in their effects on both H1 histone displacement and chromatin aggregation. Second, alkyl carboxylates and dicarboxylates differ in their ability to induce chromatin aggregation depending on charge density, suggesting possible interference by bulky alkyl chains with neutralization (screening) of closely spaced positive protein charges. Third, the multivalent anions, citrate3- and SO4(2-), bind tightly to histone and disrupt nucleosomes and thus interfere with chromatin aggregation. Substantial differences in chromatin aggregation were observed with different species of anions. At salt concentrations of 0-500 mN and pH 7.0, as much as 70% of the chromatin could be induced to aggregate by monosodium glutamate and sodium acetate, whereas only 10% or less was precipitated by NaSCN, Na2SO4, and Na3citrate. The physiological anion composition of the nucleus is not known; however, the anion effects discussed in the present work suggest a potential for regulation of chromatin condensation in higher eukaryotes.     

Yeast RNA polymerase III. Chromatographic, catalytic and DNA-binding properties are highly dependent on the type of anion

The chromatographic, catalytic and DNA-binding properties of yeast RNA polymerase III are highly affected by both concentration and type of salt. The type of anion is an especially important modulating factor for the enzymological properties of the enzyme. When acetate or sulfate anions are substituted for chloride anions, RNA polymerase III exhibits a higher affinity for DEAE-Sephadex A25, becomes able to transcribe DNA at relatively high ionic strength and shows a significant increase in the binding strength to DNA. A quantitative analysis of the binding of the enzyme to single-stranded DNA shows that the number of ionic contacts in the complex is not affected by the type of anion, but the nonionic contribution to the binding constant is significantly increased when acetate is substituted for chloride.     

Hydrogen peroxide induces rapid digestion of oligodendrocyte chromatin into high molecular weight fragments

High molecular weight (HMW) fragmentation of nuclear chromatin was studied in cultured rat oligodendrocytes (OL) exposed to hydrogen peroxide (H2O2). Intact genomic DNA was isolated by agarose embedding, and analyzed by field inversion gel electrophoresis, with and without S1 endonuclease digestion to detect and discriminate between single and double stranded fragmentations, respectively. The exposure of OL to H2O2 resulted in a very rapid degradation of chromosomal DNA into HMW fragments that reflect native chromatin structure. Hence, within 10 min after the addition of 1 mM H2O2, a discrete pool representing approximately 45% of the nuclear chromatin underwent single strand digestion into >400 kb fragments likely at AT-rich matrix attachment regions. Subsequent accumulation of single stand breaks at these regions led to bifilar scission. Ultimately, chromatin within this susceptible pool was cleaved at remaining matrix attachment regions into 50-200 kb fragments. Chromatin digestion could be elicited with H2O2 concentrations as low as 50 microM. After the removal of H2O2, most >400 kb fragments were religated within 2 h; however, digestion into 50-200 kb fragments was irreversible. The DNA digestion was not accompanied by the degradation of nuclear proteins, i.e., lamins A/C and poly (ADP-ribose) polymerase indicating that chromatin fragmentation is unlikely to be mediated by proteolysis. In conclusion, H2O2 at pathologically relevant concentrations induces a very rapid and extensive digestion of OL chromatin into HMW fragments. Because the chromatin fragmentation is only partly reversible, it may be a decisive factor in committing oxidatively stressed OL to degeneration and/or death.     

Optical anisotropy of chromatin. Flow linear dichroism and electric dichroism studies

The optical anisotropy of chromatin with different length of the linker DNA isolated from a variety of sources (Frend erythroleukemia cells, calf thymus, hen erythrocytes and sea urchin sperm) has been studied in a large range of mono- and bivalent cations concentrations by the use of flow linear dichroism (LD) and electric dichroism. We have found that all chromatins studied displayed negative LD values in the range of 0.25 mM EDTA - 2 mM NaCl and close positive values in the range of 2-100 mM NaCl. Mg2+ cations, in contrast to Na+ cations, induce optically isotropic chromatin fibers. All chromatin samples exhibit positive form effect amounting to 5-10% of LD amplitude observed at 260 nm. This form effect is determined by the anisotropic scattering of polarized light by single chromatin fibers. The conformational transition at 2 mM NaCl leads to the distortion of chromatin filament structure. The reversibility of this distortion depends on the length of the linker DNA - for chromatins with the linker DNA of 10-30 b.p. it is parially reversible, while for preparations with longer linker DNA it is irreversible. Relatively low electric field does not affect chromatin structure, while higher electric field (more than 7 kV/cm) distorts the structure of chromatin. Presented results explain the contradictory data obtained by electrooptical and hydrooptical methods.     

Alterations of DNA and chromatin structures at telomeres and genetic instability in mouse cells defective in DNA polymerase alpha

Telomere length is controlled by a homeostatic mechanism that involves telomerase, telomere-associated proteins, and conventional replication machinery. Specifically, the coordinated actions of the lagging strand synthesis and telomerase have been argued. Although DNA polymerase alpha, an enzyme important for the lagging strand synthesis, has been indicated to function in telomere metabolism in yeasts and ciliates, it has not been characterized in higher eukaryotes. Here, we investigated the impact of compromised polymerase alpha activity on telomeres, using tsFT20 mouse mutant cells harboring a temperature-sensitive polymerase alpha mutant allele. When polymerase alpha was temperature-inducibly inactivated, we observed sequential events that included an initial extension of the G-tail followed by a marked increase in the overall telomere length occurring in telomerase-independent and -dependent manners, respectively. These alterations of telomeric DNA were accompanied by alterations of telomeric chromatin structures as revealed by quantitative chromatin immunoprecipitation and immunofluorescence analyses of TRF1 and POT1. Unexpectedly, polymerase alpha inhibition resulted in a significantly high incidence of Robertsonian chromosome fusions without noticeable increases in other types of chromosomal aberrations. These results indicate that although DNA polymerase alpha is essential for genome-wide DNA replication, hypomorphic activity leads to a rather specific spectrum of chromosomal abnormality.     

Histone H1 compacts DNA under force and during chromatin assembly

Histone H1 binds to linker DNA between nucleosomes, but the dynamics and biological ramifications of this interaction remain poorly understood. We performed single-molecule experiments using magnetic tweezers to determine the effects of H1 on naked DNA in buffer or during chromatin assembly in Xenopus egg extracts. In buffer, nanomolar concentrations of H1 induce bending and looping of naked DNA at stretching forces below 0.6 pN, effects that can be reversed with 2.7-pN force or in 200 mM monovalent salt concentrations. Consecutive tens-of-nanometer bending events suggest that H1 binds to naked DNA in buffer at high stoichiometries. In egg extracts, single DNA molecules assemble into nucleosomes and undergo rapid compaction. Histone H1 at endogenous physiological concentrations increases the DNA compaction rate during chromatin assembly under 2-pN force and decreases it during disassembly under 5-pN force. In egg cytoplasm, histone H1 protects sperm nuclei undergoing genome-wide decondensation and chromatin assembly from becoming abnormally stretched or fragmented due to astral microtubule pulling forces. These results reveal functional ramifications of H1 binding to DNA at the single-molecule level and suggest an important physiological role for H1 in compacting DNA under force and during chromatin assembly.     

The effect of low ionic strength on the circular dichroic spectrum of chromatin and nucleosomal subunits

Circular dichroism has been used to measure the conformation changes in the DNA of chromatin and chromatin subunits as a function of ionic strength. Transfer of chromatin from 0.15 M to 0.25 mM salt led to an enhancement of the circular dichroic bands at 275 and 285 nm. Removal of histone H1 did not appreciably affect the circular dichroic spectrum when measured in 0.15 M salt, but in 0.25 mM salt H1 depletion led to a marked increase in the ellipticity. Conformation changes due to low ionic strength were also observed with a 145- and a 172-bp chromatin subunit. A linear combination of the ellipticities of the DNA of the two domains in chromatin, namely core and linker, was successful for measurements at 0.15 M salt, but large unexplained discrepancies appeared with the data from measurements in 0.25 mM salt.