Escherichia coli MutY protein has a guanine-DNA glycosylase that acts on 7,8-dihydro-8-oxoguanine:guanine mispair to prevent spontaneous G:C-->C:G transversions.

Low rates of spontaneous G:C-->C:G transversions would be achieved not only by the correction of base mismatches during DNA replication but also by the prevention and removal of oxidative base damage in DNA. Escherichia coli must have several pathways to repair such mismatches and DNA modifications. In this study, we attempted to identify mutator loci leading to G:C-->C:G transversions in E.coli. The strain CC103 carrying a specific mutation in lacZ was mutagenized by random miniTn 10 insertion mutagenesis. In this strain, only the G:C-->C:G change can revert the glutamic acid at codon 461, which is essential for sufficient beta-galactosidase activity to allow growth on lactose. Mutator strains were detected as colonies with significantly increased rates of papillae formation on glucose minimal plates containing P-Gal and X-Gal. We screened approximately 40 000 colonies and selected several mutator strains. The strain GC39 showed the highest mutation rate to Lac+. The gene responsible for the mutator phenotypes, mut39 , was mapped at around 67 min on the E.coli chromosome. The sequencing of the miniTn 10 -flanking DNA region revealed that the mut39 was identical to the mutY gene of E.coli. The plasmid carrying the mutY + gene reduced spontaneous G:C-->T:A and G:C-->C:G mutations in both mutY and mut39 strains. Purified MutY protein bound to the oligonucleotides containing 7,8-dihydro-8-oxo-guanine (8-oxoG):G and 8-oxoG:A. Furthermore, we found that the MutY protein had a DNA glycosylase activity which removes unmodified guanine from the 8-oxoG:G mispair. These results demonstrate that the MutY protein prevents the generation of G:C-->C:G transversions by removing guanine from the 8-oxoG:G mispair in E.coli.     

Cross sensitivity of mutator strains to physical and chemical mutagens.

Ten different mutator strains of Saccharomyces cerevisiae were tested for cross sensitivity to two alkylaitng agents, ethylmethanesulfonate (EMS) and methylmethanesulfonate (MMS), to determine if any of them are defective in the repair systems which normally deal with damage caused by these agents. For one of the mutators, namely mut2-1, it was shown by genetic analysis that mutator activity and MMS sensitivity are both controlled by the same gene. Two mutants, mut2-1 and mut7-1, were found to be sensitive to MMS but normal to ultraviolet and gamma-rays. Another group is represented by mut1, mut6 and mut8 which are not sensitive to any of the mutagens tested so far. Mutator strain mut2-1 was also shown not to be significantly altered for levels of UV-induced forward and reverse mutations. These observations lend support to the idea of multiple repair systems that deal with DNA damage caused by different agents and also show that mutator activity can often result from the loss of normal cellular repair systems.     

Role of Streptococcus sanguis (strain Wicky) cell surface-located deoxyribonucleic acid-binding factor in transformation of a homologous strain

In a previous report we demonstrated the presence of a factor binding deoxyribonucleic acid (DNA) in vitro (BF) in cell leakage fluids from transformable Streptococcus sanguis strains Wicky, Challis, and Blackburn. BF originating from strain Wicky was purified to homogeneity, and its properties are described. In this work, it was found that BF occurs at the surface of Wicky cells in two forms, loosely bound (LB-BF) and strongly bound to the cell envelope. It was demonstrated that LB-BF formed fast-sedimenting complexes with exogenous DNA at the surface of Wicky cells. About 10-fold-more DNA became associated as a fast-sedimenting complex in competent than in incompetent cells. Thus, LB-BF is a cell receptor for exogenous DNA. However, the comparison of the effects of some agents on the transformation yield and the formation of LB-BF-DNA complexes, showed that the influence of these agents on both observed phenomena is not parallel and may be even opposite. These results are interpreted to mean that the LB-BF-DNA complexes do not take part in transformation. The problem of participation of BF strongly bound with the cell membrane fraction remains to be elucidated.     

Binding of Escherichia coli RNA polymerase to T7 DNA. Displacement of holoenzyme from promoter complexes by heparin.

Escherichia coli RNA polymerase holoenzyme bound to promoter sites on T7 DNA is attacked and inactivated by the polyanion heparin. The highly stable RNA polymerase-T7 DNA complex formed at the major T7 A1 promoter can be completely inactivated by treatment with heparin, as shown by monitoring the loss of activity of such complexes, and by gel electrophoresis of the RNA products transcribed. The rate of this inactivation is much faster than the rate of dissociation of RNA polymerase from promoter complexes, and thus represents a direct attack of heparin on the polymerase molecule bound at promoter A1. Experiments employing the nitrocellulose filter binding technique suggest that heparin inactivates E. coli RNA polymerase when bound to T7 DNA by directly displacing the enzyme from the DNA. RNA polymerase bound at a minor T7 promoter (promoter C) is much less sensitive to heparin attack than enzyme bound at promoter A1. Thus, the rate of inactivation of RNA polymerase-T7 DNA complexes by heparin is dependent upon the structure of the promoter involved even though the inhibitor binds to a site on the enzyme molecule.     

Translocation of the pre-synaptic complex formed upon DNA uptake by Streptococcus sanguis and its inhibition by ethidium bromide.

Summary Donor DNA in its initially bound, singlestranded form exists in a chromosomally-unassociated complex where it is resistant to exogenous DNase I but sensitive to micrococcal nuclease. Most of the complexes are readily recuperable from the supernatant of recipients converted into spheroplasts. Subsequent to formation of this superficially located complex, donor DNA progressively associates with the recipient chromosome into which it is eventually integrated. Treatment of recipients with ethidium bromide at various times after initial DNA binding almost immediately halts translocation of whatever donor material is not yet synapsed with the chromosome. On the other hand, donor DNA that has already synapsed experiences no difficulty in becoming genetically integrated. Some degradation occurs to DNA that fails to undergo translocation as a result of ethidium bromide treatment, the acid-soluble products appearing in the culture medium. DNA in untranslocated complexes surviving treatment is not appreciably different in single-strand length from that in untreated complexes. When these surviving complexes are isolated from a cell lysate, the contained DNA can be shown by spectrofluorometry to have bound the drug.     

Mutational specificity of the dnaE173 mutator associated with a defect in the catalytic subunit of DNA polymerase III of Escherichia coli.

We developed a system to examine forward mutations that occurred in the rpsL gene of Escherichia coli placed on a multicopy plasmid. Using this system we determined the mutational specificity for a dnaE173 mutator strain in which the editing function of DNA polymerase III is impeded. The frequency of rpsL- mutations increased 32,000-fold, due to the dnaE173 mutator, and 87 independent rpsL- mutations in the mutator strain were analyzed by DNA sequencing, together with 100 mutants recovered from dnaE+ strain, as the control. While half the number of mutations that occurred in the wild-type strain were caused by insertion elements, no such mutations were recovered from the mutator strain. A novel class of mutation, named "sequence substitution" was present in mutants raised in the dnaE173 strain; seven sequence substitutions induced in the mutator strain occurred at six sites, and all were located in quasipalindromic sequences, carrying the GTG or CAC sequence at one or both endpoints. While other types of mutation were found in both strains, single-base frameshifts were the most frequent events in the mutator strain. Thus, the mutator effect on this class of mutation was 175,000-fold. A total of 95% of the single-base frameshifts in the mutator strain were additions, most of which occurred at runs of A or C bases so as to increase the number of identical residues. Base substitutions, the frequency of which was enhanced 25,000-fold by the mutator effect, occurred primarily at several hotspots in the mutator strain, whereas those induced in the wild-type strain were more randomly distributed throughout the rpsL sequence. The dnaE173 mutator also increased the frequency of duplications 28,000-fold. Of the three duplications recovered from the mutator strain, one was a simple duplication, the region of which was flanked by direct repeats. The other duplications were complex, one half part of which was in the inverted orientation of a region containing two sets of inverted repeats. The same duplications were also recovered from the wild-type strain. The present data suggest that dnaE173 is a novel class of mutator that sharply induces sequence-directed mutagenesis, yielding high frequencies of single base frameshifts, duplications with inversions, sequence substitutions and base substitutions at hotspots.     

ATP hydrolysis-dependent formation of a dynamic ternary nucleoprotein complex with MutS and MutL.

Functional interactions of Escherichia coli MutS and MutL in mismatch repair are dependent on ATP. In this study, we show that MutS and MutL associate with immobilised DNA in a manner dependent on ATP hydrolysis and with an ATP concentration near the solution K m of the ATPase of MutS. After removal of MutS, MutL and ATP, much of the protein in this ternary complex is not stably associated, with MutL leaving the complex more rapidly than MutS. The rapid dissociation reveals a dynamic interaction with concurrent rapid association and dissociation of proteins from the DNA. Analysis by surface plasmon resonance showed that the DNA interacting with dynamically bound protein was more resistant to nuclease digestion than the DNA in MutS-DNA complexes. Non-hydrolysable analogs of ATP inhibit the formation of this dynamic complex, but permit formation of a second type of ternary complex with MutS and MutL stably bound to the immobilised DNA.     

Probing the structure of multi-stranded guanine-rich DNA complexes by Raman spectroscopy and enzymatic degradation.

The multi-stranded DNA complexes formed by the oligonucleotides d(T15G4T2G4), Tel, and d(T15G15), TG, were examined by nuclease digestion and Raman spectroscopy. Both Tel and TG can aggregate to form structures consisting of multiple, parallel-oriented DNA strands with two independent structural domains. Overall, the structures of the TG and Tel aggregates appear similar. According to the Raman data, the majority of bases are in C2'-endo/anti conformation. The interaction of guanines at the 3'-ends in both complexes stabilizes the complexes and protects them from degradation by exonuclease III. The 5'-extensions remain single-stranded and the thymines are accessible to single-strand-specific nuclease digestion. The extent of enzymatic cleavage at the junction at the 5' end of the 15 thymines implies a conformational change between this part of the molecule and the guanine-rich region. The differential enzymatic sensitivity of the complexes suggests there are variations in backbone conformations between TG and Tel aggregates. TG aggregates were more resistant to digestion by DNase I, Mung Bean nuclease, and S1 nuclease than Tel complexes. It is proposed that the lower DNase I sensitivity may be partly due to the more stable backbone exhibited by TG than Tel complexes. Structural uniformity along the guanine core of TG is suggested, as there is no indication of structural discontinuities or protected sites in the guanine-rich regions of TG aggregates. The lower extent of digestion by Mung Bean nuclease at the 3' end implies that these bases are inaccessible to the enzyme. This suggests that there is minimal fraying at the ends, which is consistent with the extreme thermal stability of the TG aggregates.     

Uptake of circular deoxyribonucleic acid and mechanism of deoxyribonucleic acid transport in genetic transformation of Streptococcus pneumoniae.

Deoxyribonucleic acid (DNA) from the covalently closed circular DNA molecules of Pseudomonas phage PM2 was found to enter normally transformable cells of Streptococcus pneumoniae as readily as linear bacterial DNA. In a mutant of S. pneumoniae that lacks a membrane nuclease and is defective in DNA entry, as many molecules of PM2 DNA as of linear DNA were bound on the outside of cells at equivalent DNA concentrations. Bound DNA suffered single-strand breaks, but circular DNA with preexisting breaks was bound no better than closed circles. In the presence of divalent cations, DNA bound to cells of a leaky nuclease mutant showed double-strand breaks. At least the majority of PM2 DNA that entered normal cells was single stranded. These results are consistent with a mechanism for DNA entry in which DNA is first nicked on binding, then a double-strand break is formed by cleavage of the complementary strand, and continued processive action of the membrane nuclease facilitates entry of the originally nicked strand. Although the bulk of circular donor DNA appeared to enter in this way, the results do not exclude entry of a small amount of donor DNA in an intact form.     

Specificity of binding to four-way junctions in DNA by bacteriophage T7 endonuclease I.

T7 endonuclease I binds specifically to four-way junctions in duplex DNA and promotes their resolution into linear duplexes. Under conditions in which the nuclease activity is blocked by the absence of divalent cations, the enzyme forms a distinct protein-DNA complex with the junction, as detected by gel retardation and filter binding assays. The formation of this complex is structure-specific and contrasts with the short-lived binding complexes formed on linear duplex DNA. The binding complex between T7 endonuclease I and a synthetic Holliday junction analog has been probed with hydroxyl radicals. The results indicate that the nuclease binds all four strands about the junction point.     

Kinetic studies of the hydrolysis of platinum-DNA complexes by nuclease S1

The antitumor agent cis-diamminedichloroplatinum(II) (cis-DDP) reacts covalently with DNA and disrupts its secondary structure. Damaged DNA, but not native DNA, is readily digested by S1 nuclease, an endonuclease specific for single stranded polynucleotides. We have measured S1 nuclease digestion of platinated DNA by the release of platinum-DNA adducts and compared it with digestion of unplatinated DNA. The rate of hydrolysis of damaged substrate from platinum-DNA complexes was less than the overall rate of digestion of nucleotides. Similar results were observed for platinum-DNA complexes in native, denatured or renatured conformations. The hydrolysis of denatured platinum-DNA complexes, rb = 0.075 platinum per nucleotide, obeyed Michaelis-Menten kinetics. Taking into account the level of DNA damage, Vm, for the release of platinated adducts was 0.6 times smaller than for digestion of unplatinated DNA. Km values and competition experiments indicated that the enzyme bound equally well to platinated and unplatinated substrates. Similar results were obtained for denatured DNA complexes with trans-DDP while [PtCl(diethylenetriamine)]Cl had no influence on nuclease digestion. These results suggest that bifunctional platinum-DNA lesions have contradictory effects on the hydrolysis of double stranded DNA by S1 nuclease. On one hand they create nuclease sensitive substrate by disrupting DNA secondary structure. On the other, they inhibit digestion of the damaged strand by increasing the activation energy for hydrolysis.     

Plasmid pRQ7 from the hyperthermophilic bacterium Thermotoga species strain RQ7 replicates by the rolling-circle mechanism.

The hyperthermophilic bacterium Thermotoga species strain RQ7 harbors an 846-bp plasmid, pRQ7, with a single open reading frame. Previously published analyses of the DNA sequence of pRQ7 suggested that it may replicate by a rolling-circle (RC) replication mechanism, and this report provides experimental evidence supporting this hypothesis. Single-stranded pRQ7 DNA accumulates in strain RQ7, as evidenced by the facts that this DNA bound to nitrocellulose membranes under nondenaturing conditions, was sensitive to S1 nuclease digestion, and hybridized to only one of two homologous DNA probes specific for each strand of the plasmid. The DNA encoding the open reading frame was cloned and expressed in Escherichia coli and gave a protein with a molecular mass of 26 kDa, similar to that deduced by sequence analysis. This protein bound to a fragment of pRQ7 that contains a putative double-stranded replication region in a magnesium-dependent reaction and made this fragment sensitive to S1 nuclease activity. It did not cause this same S1 nuclease sensitivity in the remainder of pRQ7. This activity on pRQ7 DNA suggests that this protein plays a role in plasmid replication.     

Inhibition of the catalytic properties of Staphylococcus aureus nuclease by monoclonal antibodies

Monoclonal antibodies (Mab) specific for Staphylococcus aureus nuclease (nuclease) were examined for their capacity to inhibit the enzyme-mediated cleavage of DNA. Within a panel of 22 anti-nuclease Mab produced by hybridoma cell lines derived from SJL/J, A/J or BALB/c mice, only five were capable of modifying nuclease activity. Of the five, only one protected DNA from enzymatic degradation whereas the others reduced the rate of the enzymatic reaction. When mixed together, partially inactivating Mabs were frequently more efficient inhibitors than when used individually. It was shown by competitive binding assay that nuclease could be bound simultaneously to more than one Mab. Mixtures of five inactivating Mabs were able to completely block the nuclease activity. Although the actual mechanism for Mab nuclease inactivation is not known, the present data are consistent with simple steric hindrance for the formation of the DNA-nuclease complex by bulky Mab molecules bound to epitopes close to, but distinct from, nuclease catalytic sites. A mathematical model for Mab binding and inactivation of nuclease, taking into account multiple binding events for one or two Mabs interacting with nuclease, was used to derive affinities and maximum reductions of the enzymatic rate (details on the derivation of the equations and on the hypotheses of the model are given in an appendix). This analysis showed that the observed cooperative effects were dependent on the formation of multi-molecular complexes in which nuclease is bound simultaneously to two (or more) different Mabs. It also shows that the formation of cyclic complexes, if allowed, might result in very high apparent affinities. Since in screening of hybridoma fusions, the probability of finding such pairs of monoclonal antibodies would be low, this phenomenon may explain the fact that no Mab, or mixture of Mabs, matched the polyclonal antisera in capacity to block nuclease enzymatic activity.Abbreviations Nuclease Staphylococcus aureus, Foggi Strain, nuclease - Ig immunoglobulin, Mab(s)monoclonal antibody(ies) - ELISA enzyme linked immunosorbent assay - RIA radioimmunoassay     

Membrane-associated DNase activity controlled by genes 46 and 47 of bacteriophage T4D and elevated DNase activity associated with the T4 das mutation.

Lethal, amber mutations in T4 genes 46 and 47 cause incomplete degradation of host DNA, premature arrest of phage DNA synthesis, accumulation of abnormal DNA replication intermediates, and defective recombination. These phenotypes can be explained by the hypothesis that genes 46 and 47 control a DNA exonuclease, but in vitro demonstration of such a nuclease has not yet been reported. Membrane and supernatant fractions from 46- and 47- mutant-infected and 46+ 47+ control-infected cells were assayed for the presence of the protein products of these genes (i.e., gp46 and gp47) and for the ability to degrade various DNA substrates to acid-soluble products in vitro. The two proteins were found only on membranes. The membrane fraction from 46- 47- mutant-infected cells digested native or heavily nicked Escherichia coli DNA to acid-soluble products three to four times slower that the membrane fraction from control-infected cells. No such effect was found in the cytoplasmic fractions. The effect on nuclease activity in membranes was the same whether 46- and 47- mutations were present singly or together. NaClO4, a chaotropic agent, released both gp46 and gp47 from 46+ 47+ membranes, as well as the DNase activity controlled by genes 46 and 47. DNA cellulose chromatography of proteins released from membranes by NaClO4 showed that gp46 and gp47 bound to the native DNAs of both E. coli and T4. Thus, the overall enrichment of gp46 and gp47 relative to total T4 protein was 600-fold (10-fold in membranes, 2-fold more upon release from membranes by NaClO4, and 30-fold more upon elution from DNA cellulose). T4 das mutations, which partially suppress the defective phenotype of 46- and 47- mutants, caused a considerable increase in vitro DNase activity in both membrane and cytoplasmic fractions, We obtained evidence that the das+ gene does not function to inhibit E. coli exonuclease I or V, endonuclease I, or the UV endonuclease of gene uvrA or to decrease the activity of T4 exonuclease A or the T4 gene 43 exonuclease.     

Identification of a nuclease and host restriction-modification in the unicellular, aerobic nitrogen-fixing cyanobacterium Cyanothece sp.

In the process of developing a gene transfer system for the marine, unicellular, nitrogen-fixing cyanobacterium Cyanothece sp. strain BH68K, two major restriction barriers have been identified. A cell wall-associated nuclease exhibited non-site-specific degradation of covalently closed circular and linear double-stranded DNA molecules, including Cyanothece sp. strain BH68K chromosomal DNA. The nuclease is easily released from intact cells by using water or buffer containing Triton X-100. Nuclease activity was undetectable in cell extracts prepared from water-washed cells. Comparison of the restriction endonuclease susceptibility of Cyanothece sp. strain BH68K DNA to that of Anabaena sp. strain PCC 7120 revealed that these organisms have a nearly identical pattern of restriction and therefore may contain similar systems for DNA methylation. Restriction by DpnI, MboI, and Sau3AI indicated the presence of adenine methylation. Cyanothece sp. strain BH68K cell extracts contain a type II restriction endonuclease, Csp68KI. The activity of Csp68KI was easily detected in cell extracts without extensive purification. Csp68KI is an isoschizomer of AvaII and recognizes the nucleotide sequence 5'-GG(A/T)CC-3'. Cleavage occurs between the guanosine nucleotides producing 3-bp 5' overhang ends.     

Comparison of nuclease digestion of polyoma virus nucleoprotein complex and mouse chromatin.

We digested polyoma virus nucleoprotein complex, isolated from disrupted virions, with micrococcal nuclease and DNase I. The results were compared with digestions of chromatin from mouse nuclei. The nucleosome "core" structures were similar, but the spacing of the nucleosomes in the isolated polymoma nucleoprotein complexes was irregular, whereas in mouse chromatin it was regular. The average nucleosome repeat length in each case was 190 to 200 base pairs. This figure suggests that, unless there are substantial stretches of free DNA, the polyoma nucleoprotein complex contains about 26 nucleosomes. The commonly used method of preparing the nucleoprotein complex by disruption of virions at pH 10.2 may lead to significant damage to the structure. Such damage may be more clearly revealed by the susceptibility of the DNA to nuclease digestion than by the usual criteria of sedimentation velocity and buoyant density.     

Function of gene 49 of bacteriophage T4. I. Isolation and biochemical characterization of very fast-sedimenting DNA.

Very fast-sedimenting DNA was isolated from cells after infection with gene 49 defective phage T4. This DNA appeared membrane bound throughout the time after infection and could be isolated either in the membrane-bound form (M-DNA) or free of membrane (released DNA) depending on the lysis procedure. Released DNA formed complexes of marked stability with sedimentation velocities between 1,400S and 2,100S. These complexes did not seem to contain material other than DNA. This was concluded from the results of RNA, protein, and membrane labeling experiments and density analysis. In addition, these complexes were resistant against treatment with n-butanol, phenol. chloroform-methanol, sodium dodecyl sulfate, Sarkosyl, Pronase, RNase, or lysozyme. The observation that more then 90% of the purified very fast-sedimenting DNA is retrapped by magnesium-Sarkosyl crystals (M-band) suggests that the M-band technique may not be sufficient as a test for DNA-membrane attachment.     

Stabilization of triple-stranded oligonucleotide complexes: use of probes containing alternating phosphodiester and stereo-uniform cationic phosphoramidate linkages.

Pyrimidine oligonucleotides containing alternating anionic and stereo-uniform cationic N-(dimethylamino-propyl)phosphoramidate linkages [e.g. d(T+T-)7T, d(T+T-)2(T+C-)5T and (U'+U'-)7dT, where U' is 2'-O-methyluridine)] are shown to bind to complementary double-stranded DNA segments in 0.1 M NaCl at pH 7 to form triple-stranded complexes with the pyrimidine.purine.pyrimidine motif. For each of the sequences investigated, one stereoisomer bound with higher affinity, and the other stereoisomer with lower affinity, than the corresponding all-phosphodiester oligonucleotide. The stereoisomer of d(T+T-)7T that interacted weakly with a dT.dA target in 0.1 M NaCl formed a novel dA.dA.dT triple-stranded complex with poly(dA) or d(Al5C4A15) in 1 M NaCl; in contrast, the stereoisomer that bound strongly to the dT.dA target failed to form a dA.dA.dT triple-stranded complex.     

The structure of the complexes of DNA with chromosomal protein HMGB1 and histone H1 in the presence of manganese ions. I. Circular dicroism spectroscopy

The mechanisms of interaction of the non-histone chromosomal protein HMGB1 and linker histone H1 with DNA have been studied using circular dichroism and absorption spectroscopy. Both of the proteins are located in the inter-nucleosomal regions of chromatin. It was demonstrated that properties of the DNA-protein complexes depend on the protein content and can not be considered as a simple summing up of the effects of individual protein components. Interaction of HMGB1 and H1 proteins is shown to be co-operative rather than competitive. Lysine-rich histone H1 facilitates the binding of the HMGB1 with DNA by screening the negatively charged groups of the sugar-phosphate backbone of DNA and dicarboxylic amino-acid residues in the C-terminal domain of the HMGB1 protein. The observed joint action of the and H1 proteins stimulates DNA condensation with formation of the anisotropic DNA-protein complexes with typical psi-type CD spectra. Structural organization of the complexes depends not only on the DNA-protein interactions, but also on the interaction between HMGB1 and H1 protein molecules bound to DNA. Manganese ions significantly modify the character of interactions between the components in the triple DNA-HMGB1-H1 complex. Binding of Mn2+ ions causes the weakening of the DNA-protein interactions and strengthening the protein-protein interactions, which promote DNA condensation and formation of large DNA-protein particles in solution.