The deoxyribonucleic acid unwinding protein of Escherichia coli. Properties and functions in replication

Synthesis of bacteriophage phi X174 in vitro: mechanism of switch from DNA replication to DNA packaging

Replication of a replicative form DNA of bacteriophage phi X174 initiates by rolling-circle synthesis of the viral DNA followed by discontinuous synthesis of the complementary DNA. Gene C protein of phi X174, which is involved in DNA packaging, inhibits the rolling-circle DNA synthesis by binding to the initiation complex in vitro. The gene C protein-associated initiation complex can synthesize and package the viral DNA to produce infectious phage when supplemented with phi X174 gene J protein and the prohead. Multiple rounds of phage synthesis occur without dissociation of the gene C protein from the complex. These results indicate that gene C protein is central in the switch from replication of a replicative form DNA to synthesis and concomitant packaging of viral DNA into phage capsid, which occurs in the late stage of infection.

Continuous association of Escherichia coli single-stranded DNA binding protein with stable complexes of recA protein and single-stranded DNA

The single-stranded DNA binding protein of Escherichia coli (SSB) stimulates recA protein promoted DNA strand exchange reactions by promoting and stabilizing the interaction between recA protein and single-stranded DNA (ssDNA). Utilizing the intrinsic tryptophan fluorescence of SSB, an ATP-dependent interaction has been detected between SSB and recA-ssDNA complexes. This interaction is continuous for periods exceeding 1 h under conditions that are optimal for DNA strand exchange. Our data suggest that this interaction does not involve significant displacement of recA protein in the complex by SSB when ATP is present. The properties of this interaction are consistent with the properties of SSB-stabilized recA-ssDNA complexes determined by other methods. The data are incompatible with models in which SSB is displaced after functioning transiently in the formation of recA-ssDNA complexes. A continuous association of SSB with recA-ssDNA complexes may therefore be an important feature of the mechanism by which SSB stimulates recA protein promoted reactions.

Salt-dependent changes in the DNA binding co-operativity of Escherichia coli single strand binding protein

The co-operative nature of the binding of the Escherichia coli single strand binding protein (SSB) to single-stranded nucleic acids has been examined over a range of salt concentrations (NaCl and MgCl2) to determine if different degrees of binding co-operativity are associated with the two SSB binding modes that have been identified recently. Quantitative estimates of the binding properties, including the co-operativity parameter, omega, of SSB to single-stranded DNA and RNA homopolynucleotides have been obtained from equilibrium binding isotherms, at high salt (greater than or equal to 0.2 M-NaCl), by monitoring the fluorescence quenching of the SSB upon binding. Under these high salt conditions, where only the high site size SSB binding mode exists (65 +/- 5 nucleotides per tetramer), we find only moderate co-operativity for SSB binding to both DNA and RNA, (omega = 50 +/- 10), independent of the concentration of salt. This value for omega is much lower than most previous estimates. At lower concentrations of NaCl, where the low site size SSB binding mode (33 +/- 3 nucleotides/tetramer) exists, but where SSB affinity for single-stranded DNA is too high to estimate co-operativity from classical binding isotherms, we have used an agarose gel electrophoresis technique to qualitatively examine SSB co-operativity with single-stranded (ss) M13 phage DNA. The apparent binding co-operativity increases dramatically below 0.20 M-NaCl, as judged by the extremely non-random distribution of SSB among the ssM13 DNA population at low SSB to DNA ratios. However, the highly co-operative complexes are not at equilibrium at low SSB/DNA binding densities, but are formed only transiently when SSB and ssDNA are directly mixed at low concentrations of NaCl. The conversions of these metastable, highly co-operative SSB-ssDNA complexes to their equilibrium, low co-operativity form is very slow at low concentrations of NaCl. At equilibrium, the SSB-ssDNA complexes seem to possess the same low degree of co-operativity (omega = 50 +/- 10) under all conditions tested. However, the highly co-operative mode of SSB binding, although metastable, may be important during non-equilibrium processes such as DNA replication. The possible relation between the two SSB binding modes, which differ in site size by a factor of two, and the high and low co-operativity complexes, which we report here, is discussed.

Identification of the Escherichia coli recN gene product as a major SOS protein

The recA+ lexA+-dependent induction of four Escherichia coli SOS proteins was readily observed by two-dimensional gel analysis. In addition to the 38-kilodalton (kDa) RecA protein, which was induced in the greatest amounts and was readily identified, three other proteins of 115, 62, and 12 kDa were seen. The 115-kDa protein is the product of the uvrA gene, which is required for nucleotide excision repair and has previously been shown to be induced in the SOS response. The 62-kDa protein, which was induced to high intracellular levels, is the product of recN, a gene required for recBC-independent recombination. The recA and recN genes were partially derepressed in a recBC sbcB genetic background, a phenomenon which might account for the recombination proficiency of such strains. The 12-kDa protein has yet to be identified.

Intermediates in homologous pairing promoted by recA protein. Isolation and characterization of active presynaptic complexes

recA protein promotes homologous pairing and strand exchange by an ordered reaction in which the protein first polymerizes on single-stranded DNA. This presynaptic intermediate, which can be formed either in the presence or absence of Escherichia coli single-stranded binding protein (SSB), has been isolated by gel filtration and characterized. At saturation, purified complexes contained one molecule of recA protein per 3.6 nucleotide residues of single-stranded DNA. Complexes that had been formed in the presence of SSB contained up to one molecule of SSB per 15 nucleotide residues, but the content of SSB in different preparations of isolated complexes appeared to be inversely related to the content of recA protein. Even when they have lost as much as a third of their recA protein, presynaptic complexes can retain activity, because the formation of stable joint molecules depends principally on the binding of recA protein to the single-stranded DNA in the localized region that corresponds to the end of the duplex substrate.

Identification and characterization of the mutL and mutS gene products of Salmonella typhimurium LT2

The gene products of the mutL and mutS loci play essential roles in the dam-directed mismatch repair in both Salmonella typhimurium LT2 and Escherichia coli K-12. Mutations in these genes result in a spontaneous mutator phenotype. We have cloned the mutL and mutS genes from S. typhimurium by generating mutL- and mutS-specific probes from an S. typhimurium mutL::Tn10 and an mutS::Tn10 strain and using these to screen an S. typhimurium library. Both the mutL and mutS genes from S. typhimurium were able to complement E. coli mutL and mutS strains, respectively. By a combination of Tn1000 insertion mutagenesis and the maxicell technique, the products of the mutL and mutS genes were shown to have molecular weights of 70,000 and 98,000 respectively. A phi (mutL'-lacZ+) gene fusion was constructed; no change in the expression of the fusion could be detected by treatment with DNA-damaging agents. In crude extracts, the MutS protein binds single-stranded DNA, but not double-stranded DNA, with high affinity.

Variability in the nucleic acid binding site size and the amount of single-stranded DNA-binding protein in Escherichia coli

The Escherichia coli single-stranded DNA binding protein (SSB), essential for DNA replication, recombination and repair, can undergo a thermally induced irreversible conformational change which does not eliminate its biological activity, but changes the number of nucleotides it covers (binding site size) when binding to a single-stranded nucleic acid lattice. The binding site size of native and conformationally changed SSB was also found to be a function of the molecular mass of the polynucleotide, an observation which is unusual for single-stranded DNA binding proteins and will greatly affect the affinity relationship of this protein for nucleic acids. A radioimmunoassay used to quantitate in SSB level in cells revealed the number of SSB tetramers to be larger than initial estimates by a factor of as much as six. All these data suggest that the biological role of SSB and its mechanism of action is by far more complex than originally assumed.

A role for DNA polymerase in the specificity of nucleotide incorporation opposite N-acetyl-2-aminofluorene adducts

Escherichia coli DNA polymerase I (Klenow fragment), DNA polymerase alpha from both calf thymus and human lymphoma cells and DNA polymerase beta from calf thymus and Novikoff hepatoma cells can incorporate nucleotides opposite N-guanin-8-yl-acetyl-2-aminofluorene in DNA. The polymerases incorporate dCTP opposite some AAF-dG lesions when Mg2+ is the divalent cation. Substitution of Mn2+ for Mg2+ broadens the specificity of insertion: E. coli DNA polymerase I (Klenow fragment) also inserts A, and at specific sites G or T; DNA polymerase alpha inserts any of the four dNTPs with A and C incorporated preferentially to G and T. Polymerase beta is specific, inserting mainly C even in the presence of Mn2+. The Km for addition of dATP opposite a lesion by E. coli polymerase I (Klenow fragment) in the presence of Mn2+ is about 0.5 mM. dNMPs increase the insertion of nucleotides opposite AAF-dG in the presence of Mg2+ and increase both the rate and number of sites at which incorporation occurs in the presence of Mn2+. dNTP alpha S and recA protein increase only the insertion of C. We suppose that the incorporation of dCTP reflects normal base-pairing with the AAF-deoxyguanine in the anti conformation, whereas insertion of the other nucleotides (including some of the C) reflects insertion opposite the AAF adduct in its preferred syn conformation. The fact that the DNA polymerase plays a role in determining the specificity of insertion opposite a lesion terminating DNA synthesis suggests that the spectrum of base substitution mutagenesis seen in vivo may reflect the properties of the protein components, including the polymerase, involved in bypass synthesis.

Replication initiated at the origin (oriC) of the E. coli chromosome reconstituted with purified enzymes

A crude soluble enzyme system capable of authentic replication of a variety of oriC plasmids has been replaced by purified proteins constituting three functional classes: initiation proteins (RNA polymerase, dnaA protein, gyrase) that recognize the oriC sequence and presumably prime the leading strand of the replication fork; replication proteins (DNA polymerase III holoenzyme, single-strand binding protein, primosomal proteins) that sustain progress of the replication fork; and specificity proteins (topoisomerase I, RNAase H, protein HU) that suppress initiation of replication at sequences other than oriC, coated with dnaA protein. Protein HU and unidentified factors in crude enzyme fractions stimulate replication at one or more stages. Replication has been separated temporally and physically into successive stages of RNA synthesis and DNA synthesis.

Quantification of SSB protein in E. coli and its variation during RECA protein induction

Using a two-site immunometric assay (IRMA) we quantified the concentration of single-stranded DNA binding protein (SSB) in several E. coli strains. We found approximately 7,000 monomers of SSB present per bacterium, and this number remained constant throughout the exponential phase of growth. Two ssb- mutants (ssb-1 and ssb-113) are defective in the induction of the S.O.S. pathway. One of the first functions expressed upon induction of the S.O.S. pathway is the amplification of recA protein (RECA), which we monitored by an IRMA assay similar to the one used for SSB quantification. By combining the two assays we determined the level of SSB and RECA in ssb- mutants or in SSB and RECA overproducer strains. We found: a) a normal induction of RECA following UV irradiation of E. coli bacteria overproducing SSB, b) a normal level of SSB in wild type and ssb-1 and ssb-113 mutants either in the absence or in the presence of S.O.S. inducing agents. We confirmed a severe impairment in the induction of RECA in these two mutants after nalidixic acid treatment. Our results suggest that the concentrations of RECA and SSB protein in E. coli are regulated by independent biochemical pathways.

High mobility group proteins HMG1 and HMG2 do not decrease the melting temperature of DNA

High mobility group proteins 1 and 2 isolated in non-denaturing conditions cannot decrease the temperature of denaturation of DNA. When they are isolated or treated with tricloroacetic acid a hyperchromic peak below the melting temperature of free DNA appears in agreement with previous data ( Javaherian et al. (1979) Nucl . Acids Res. 6, 3569-3580). We show that this is due to light scattering of aggregated protein at submelting temperatures and not to melting of DNA.

The major herpes simplex virus DNA-binding protein holds single-stranded DNA in an extended configuration

Properties of the major DNA-binding protein found in herpes simplex virus-infected cells were investigated by using a filter binding assay and electron microscopy. Filter binding indicated that the stoichiometry of binding of the protein with single-stranded DNA is approximately 40 nucleotides per protein molecule at saturation. Strong clustering of the protein in DNA-protein complexes, indicative of cooperative binding, was seen with the electron microscope. Measurements of single-stranded fd DNA molecules saturated with protein and spread for electron microscopy by using both the aqueous and formamide spreading techniques indicated that the DNA is held in an extended configuration with a base spacing of approximately 0.13 nm per base.

DNA replication by novel macromolecular complexes involving DNA polymerase III holoenzyme activity

A fraction (P1) which showed DNA polymerase III holoenzyme activity was obtained by partial purification including Polymin P fractionation from extracts of E. coli K-12 wild type (pol A+, pol B+) cells. The P1 fraction was composed of three macromolecular complexes, 11 S, 18 S and 24 S, all of which possessed holoenzyme activity. The activity of the P1 fraction was maximal at about 70 mM NaCl. The synthesis of long-chain poly(dT) with a poly(dA) oligo(dT)10 primer was dependent on the presence of ATP, but not on the presence of spermidine, suggesting that the single-stranded DNA binding protein (SSB) was present in the fraction. The intermediate lengths of the products in the absence of ATP and NaCl also suggest the functioning of DNA polymerase III'.

Amplification of ssb-1 mutant single-stranded DNA-binding protein in Escherichia coli

The ssb-1 gene encoding a mutant Escherichia coli single-stranded DNA-binding protein has been cloned into plasmid pACYC184. The amount of overproduction of the cloned ssb-1 gene is dependent upon its orientation in the plasmid. In the less efficient orientation, 25-fold more mutant protein is produced than in strains carrying only one (chromosomal) copy of the gene; the other orientation results in more than 60-fold overproduction of this protein. Analysis of the effects of overproduction of the ssb-1 encoded protein has shown that most of the deficiencies associated with the ssb-1 mutation when present in single gene copy, including temperature-sensitive conditional lethality and deficiencies in amplified synthesis of RecA protein and ultraviolet light-promoted induction of prophage lambda +, are reversed by increased production of ssb-1 mutant protein. These results provide evidence in vivo that SSB protein plays an active role in recA-dependent processes. Homogenotization of a nearby genetic locus (uvrA) was identified in the cloning of the ssb-1 mutant gene. This observation has implications in the analysis of uvrA- mutant strains and will provide a means of transferring ssb- mutations from plasmids to the chromosome. On a broader scale, the observation may provide the basis of a general strategy to transfer mutations between plasmids and chromosomes.

Lack of single-strand DNA-binding protein amplification under conditions of SOS induction in E. coli

A two site immunoradiometric assay (IRMA) for quantification of the recA protein has been recently described (Paoletti et al. 1982). We have used a similar technique to monitor the possible amplification of the ssb protein in E. coli after induction of the SOS repair process by various DNA damaging agents. Under these conditions, while we have been able to detect a full amplification of recA protein, we failed to observed any amplification of the ssb protein.

Preferential transfection with M13mp2 RF DNA synthesized in vitro

Single-strand DNA binding protein (SSB) from Escherichia coli abolishes transfection of E.coli by viral M13mp2 DNA at levels that inhibit transfection by M13mp2 replicative form (RF) DNA by approx. 25%. Synthesis of M13mp2 RF DNA (SS leads to DS) has been carried out using DNA polymerase I (Klenow fragment) and a unique 15-nucleotide primer. A time course for in vitro synthesis showed that the increase in transfection in the presence of SSB paralleled DNA synthesis after an initial lag period for transfection. Digestion of replication products with restriction endonucleases and S1 endonuclease indicates that only those molecules that are fully or almost fully duplex transfect competent cells in the presence of SSB.

Suppression of the ssb-1 and ssb-113 mutations of Escherichia coli by a wild-type rep gene, NaCl, and glucose

The ssb-1 mutation confers severe temperature sensitivity and UV sensitivity on many strains of Escherichia coli K-12 and C, including strain C1412. However, ssb-1 confers only slight temperature sensitivity and slight UV sensitivity on strain C1a, suggesting that strain C1a contains extragenic suppressors of ssb-1. We found that introduction of the wild-type rep gene from C1a into strain C1412 ssb-1 gave strong suppression of temperature sensitivity and moderate suppression of UV sensitivity. Also, the C1a rep+ gene mildly suppressed the temperature sensitivity conferred by the ssb-113 mutation, formerly called lexC113. Suppression of the C1412 ssb-1 growth defect by C1a rep+ rendered the cells Gro- for phi X174. In contrast to the positive suppression of ssb-1 and ssb-113 by a wild-type rep gene, mutant rep alleles enhanced the severity of the ssb-1 defect, with several C1a ssb-1 double mutants being either more temperature sensitive or more UV sensitive than C1a ssb-1, depending on which mutant rep allele was used. As a control, the same rep alleles in combination with a dnaB mutation gave an allele-independent increase in temperature sensitivity. Our results on suppression of ssb-1 by rep and on the role of the genetic background in this suppression suggested that the rep and ssb proteins interact to form a subcomplex of the total DNA replication complex and that this subcomplex has some function in repair. The effects of NaCl and glucose on suppression of both the temperature sensitivity and the UV sensitivity conferred by ssb-1 and ssb-113 are described. The degree of suppression of temperature sensitivity by salt or glucose was dependent on the source of the wild-type rep allele, as well as on the genetic background.

Postreplication repair in E. coli: strand exchange reactions of gapped DNA by RecA protein

We have used a sensitive gel electrophoresis assay to detect the products of Escherichia coli RecA protein catalysed strand exchange reactions between gapped and duplex DNA molecules. We identify structures that correspond to joint molecules formed by homologous pairing, and show that joint molecules are converted by RecA protein into heteroduplex monomers by reciprocal strand exchanges. However, strand exchanges only occur when there is a 3'-terminus complementary to the single stranded DNA in the gap. In the absence of a complementary free end, the two DNA molecules pair and short heteroduplex regions are formed by localised interwinding.

Role of SSB protein in RecA promoted branch migration reactions

The RecA protein of Escherichia coli is essential for genetic recombination and postreplicational repair of DNA. In vitro, RecA protein promotes strand transfer reactions between full length linear duplex and single stranded circular DNA of phi X174 to form heteroduplex replicative form II-like structures (Cox and Lehman 1981 a0. In a similar way, it transfers one strand of a short duplex restriction fragment to a single stranded circle. Both reactions require RecA and single strand binding protein (SSB) in amounts sufficient to saturate the ssDNA. The rate and extent of strand transfer is enhanced considerably when SSB is added after preincubation of the DNA with RecA protein. In contrast, SSB protein is not required for RecA protein catalysed reciprocal strand exchanges between regions of duplex DNA. These results indicate that while SSB is necessary for efficient transfer between linear duplex and ssDNA to form a single heteroduplex, it is not required for branch migration reactions between duplex molecules that form two heteroduplexes.

Effects of the ssb-1 and ssb-113 mutations on survival and DNA repair in UV-irradiated delta uvrB strains of Escherichia coli K-12

The molecular defect in DNA repair caused by ssb mutations (single-strand binding protein) was studied by analyzing DNA synthesis and DNA double-strand break production in UV-irradiated Escherichia coli delta uvrB strains. The presence of the ssb-113 mutation produced a large inhibition of DNA synthesis and led to the formation of double-strand breaks, whereas the ssb-1 mutation produced much less inhibition of DNA synthesis and fewer double-strand breaks. We suggest that the single-strand binding protein plays an important role in the replication of damaged DNA, and that it functions by protecting single-stranded parental DNa opposite daughter-strand gaps from nuclease attack.

Influence of single-stranded DNA-binding protein on recA induction in Escherichia coli

Two ssb mutants of Escherichia coli, which carry a lesion in the single-strand DNA-binding protein (SSB), are sensitive to UV-irradiation. We have investigated the influence of SSB on the "SOS" repair pathway by examining the levels of recA protein synthesis. These strains fail to induce normal levels of recA protein after treatment with nalidixic acid or ultraviolet light. The level of recA protein synthesis in wild-type cells is about three times greater than ssb cells. This deficiency in ssb mutants occurs in all strains and at all temperatures tested (30-41.5 degrees). In contrast, the ssb-1 mutation has no effect on temperature-induced recA induction in a recA441 (tif-1) strain. Cells carrying ssb+ plasmids and overproducing normal DNA-binding protein surprisingly are moderately UV-sensitive and have reduced levels of recA protein synthesis. Together these results establish that single-strand DNA-binding protein is involved in the induction of recA, and accounts, at least in part, for the UV sensitivity of ssb mutants. Three possible mechanisms to explain the role of SSB are discussed.

Suppression of the lexC (ssbA) mutation of Escherichia coli by a mutant of bacteriophage P1

A new mutant of bacteriophage P1 designated lxc that suppresses the phenotype of lexC and ssbA mutants of Escherichia coli was isolated and characterized. The properties of lexC mutants suppressed by the lxc mutation include temperature sensitive growth at 42 degrees C, sensitivity to ultraviolet light and alkylating agents, and a nonmutagenic response following exposure to ultraviolet irradiation. A bac mutant of bacteriophage P1 that suppresses the temperature sensitivity of dnaB mutants does not affect the phenotype of lexC or ssbA mutants. Neither the lxc or bac mutations affect the ultraviolet light sensitivity of strains with the mutations uvrA155, lexA102, or recA56.

Biological activity and a partial amino-acid sequence of Escherichia coli DNA-binding protein I isolated from overproducing cells

DNA-binding protein I from Escherichia coli was purified from cells carrying the ssb gene on a multicopy plasmid. In comparison to the strain without the recombinant plasmid the DNA-binding protein was over-produced more than 20-fold. The amount of the protein was measured after the purification steps by gel electrophoresis and radial immunodiffusion. The protein was purified to homogeneity and was active in replication assays like the wild-type DNA-binding protein. The assays were enzymatic replication of single-stranded and double-stranded fd DNA. E. coli DNA-binding protein I was further subjected to amino acid sequence analysis. A monomer of the protein consists of 187 residues which correspond to a molecular weight of 19715 with 5% error in analysis. The sequence of the amino-terminal 40 residues was determined and includes several basic residues of the protein. Sequence comparison between the DNA-binding protein I from E. coli and that coded by bacteriophage fd reveals similarities suggesting that DNA-binding protein I may use amino-terminal residues for binding to DNA like the phage protein.