Escherichia coli recA protein protects single-stranded DNA or gapped duplex DNA from degradation by RecBC DNase

RecA- mutants of Escherichia coli extensively degrade their DNA following UV irradiation. Most of this degradation is due to the recBC DNase, which suggests that the recA gene is involved in the control of recBC DNase in vivo. We have shown that purified recA protein inhibits the endonuclease and exonuclease activities of recBC DNase on single-stranded DNA. The extent of inhibition is dependent on the relative concentration of recA protein, recBC DNase, and the DNA substrate; inhibition is greatest when the concentrations of DNA and recBC DNase are low and the concentrations of recA protein is high. At fixed concentrations of recA protein and recBC DNase, inhibition is eliminated at high concentrations of DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), an ATP analog which stabilizes the binding of recA protein to both single- and double-stranded DNA, recA protein is a more potent inhibitor of the nuclease activities on single-stranded DNA and is a weak inhibitor of the exonuclease activity on double-stranded DNA. Inhibition of the latter is enhanced by oligodeoxynucleotides, which stimulate the binding of recA protein to double-stranded DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), recA protein also inhibits the action of exonuclease I on single-stranded DNA and of lambda exonuclease on double-stranded DNA. These observations are most consistent with the idea that recA protein protects DNA from recBC DNase by binding to DNA. RecA protein also blocks the endonucleolytic cleavage of gapped circular DNA by recBC DNase. Since both recA protein and recBC DNase have the ability under certain conditions to unwind duplex DNA and to displace strands, we looked for evidence that their combined action would enlarge gaps but found no extensive enlargement. D-loops, a putative intermediate in genetic recombination, are effectively protected against the action of recBC DNase by the E. coli single strand binding protein and by recA protein in the presence of adenosine 5'-O-(3-thiotriphosphate).     

Partial purification and properties of an exonuclease inhibitor induced by bacteriophage Mu-1.

From an induced lysogen of bacteriophage Mu-1, we partially purified a substance of high molecular weight that blocks the action of several exonucleases on double-stranded DNA. The presence of the inhibitor in cell-free extracts is dependent on induction of a Mu prophage. The Mu-related inhibitor acts by binding to double-stranded DNA rather than by interacting with the DNase. The inhibitor protects linear duplex DNA of Mu, P22, and phi X174am3 from exonucleolytic degradation by recBC DNase and lambda exonuclease. Single-stranded DNA, however, is not protected by the inhibitor from degradation by either recBC DNase or exonuclease I. The inhibitor preparation contains a protein that binds to linear duplex DNA, but not to circular duplex DNA; ends are required for binding to occur. Single-stranded DNA is not a substrate for the binding protein. These and other results suggest that the binding protein and the inhibitor are the same activity.     

Transfection of Escherichia coli spheroplasts. V. Activity of recBC nuclease in rec+ and rec minus spheroplasts measured with different forms of bacteriophage DNA.

The in vivo activity of the recBC nuclease was assayed by transfection of isogenic rec+ and rec minus spheroplasts with bacteriophage DNA of various origin and structure. The results indicate that the recBC nuclease can limit transfection at several stages during the production of an infective center; such limitations depend primarily on whether the DNA is in, or assumes, a nuclease-sensitive structure. The first stage of limitation can occur when a nuclease-sensitive transfecting molecule enters the spheroplast. Other potential limitation points occur during replication and maturation of the bacteriophage DNA. The initial stage can be bypassed by using recBC nuclease-resistant molecules such as circular forms. Through analysis of results with other DNA structures, we found that in vivo the effects of the double-strand exonucleolytic activity of the recBC nuclease predominated. The effects of the single-strand nuclease activities seem to be modified from those observed for the purified enzyme in vitro (Karu et al., 1974). Inside the cell, the single-strand exonuclease activity is very weak and the single-strand endonuclease activity is abolished almost completely.     

Degradation of linear and circular DNA with gaps by the recBC enzyme of Escherichia coli. Effects of gap length and the presence of cell-free extracts

It is shown that circular PM2 DNA with two gaps of 13 nucleotides per molecule is degraded by purified recBC enzyme from Escherichia coli to acid-soluble material at a rate which is less than one tenth of the rate of solubilization of linear duplex DNA. Increasing the gap length in the circular DNA to 40-650 nucleotides does not affect the breakdown of the molecules by the recBC enzyme, nor does it change the proportions of the products formed (acid-soluble material, acid-insoluble fragments and non-degraded molecules). On the other hand, terminal gaps in linear duplex DNA produced by limited digestion with either exonuclease III or lambda exonuclease significantly reduce the rate of the degradation by the recBC enzyme, particularly when the gaps exceed 100 nucleotides. The results suggest that the recBC enzyme does not cleave gaps in circular DNA at random positions, but possibly at the junction between single-stranded and duplex DNA or close to it. The degradation of gapped circular DNA by purified recBC enzyme was used to search for an inhibitor of the recBC enzyme in extracts from ultraviolet-irradiated cells. No such inhibitor has been observed but rather a weak stimulatory factor for the solubilization of gapped circular DNA by the recBC enzyme. Thus, the experimental system appears not to be suited as a test in vitro for an ultraviolet-induced inhibitor of the recBC enzyme which has been postulated to be produced in recA+ lexA+ cells of E. coli after ultraviolet irradiation.     

The gamma protein specified by bacteriophage gamma. Structure and inhibitory activity for the recBC enzyme of Escherichia coli.

The protein encoded by the gam gene of bacteriophage lambda ("gamma protein") is a specific inhibitor of the recBC enzyme of Escherichia coli. The lambda protein has been purified approximately 2,000-fold, and its structure and inhibitory activity have been characterized. It appears to be composed of two identical subunits of 16,500 daltons, inhibits all of the catalytic activities of the recBC enzyme with apparently equal efficiency, but has no effect upon any other E. coli or lambda-DNase tested. Inhibition does not occur unless recBC enzyme is exposed to gamma protein prior to reaction of the enzyme with DNA. The inhibitory activity is independent of temperature, and no catalytic activity has been detected that might fulfill the inhibitory function. It appears instead that the inhibition involves a stoichiometric, rather than a catalytic interaction between gamma protein and the enzyme. Reaction kinetics for the recBC enzyme inhibited by gamma protein show no anomalous protein--only a depressed rate. Inhibition is not competitive and does not appear to affect the enzyme's affinity for DNA. The enzyme remains inhibited after it is separated from "excess" gamma protein by gel filtration or sedimentation in a glycerol gradient, and inhibited enzyme has a reduced electrophoretic mobility compared to that of uninhibited enzyme. Gamma Protein inhibits recBC enzyme which has been reconstituted from cell-free extracts by complementation in vitro, but at least one of the complementing factors present in extracts from recB- cells does not by itself form a complex with gamma protein. The mechanism of inhibition and the implications of these results from gamma replication and recombination are discussed.     

Purification and some properties of deoxyribonuclease whose synthesis is controlled by gene 49 of bacteriophage T4.

An enzyme which specifically cleaves very-fast-sedimenting DNA of bacteriophage T4 is synthesized after infection of T4, and its synthesis is controlled by gene 49 [1,2]. This enzyme has been proved to be a DNase [2]. We have purified this DNase 3000-fold from extracts of E. coli infected with T4. The purified preparation was practically free from other DNases, and the DNase activity was not detectable in cells infected with a mutant defective in gene 49. The enzyme activity from cells infected with a temperature-sensitive mutant of gene 49 was also temperature-sensitive, suggesting strongly that gene 49 is a structural gene of the DNase. The molecular weight of the wild-type enzyme was estimated to be 50 x 10(3) by gel filtration chromatography. The purified DNase did not cleave native and denatured DNAs of T3 and T4, but cleaved renatured T3 DNA with enzymatically fragmented T3 DNA, indicating that gaps in the DNA duplex are structures susceptible to the DNase. Cleavage of the hybridized T3 DNA occurred when the fragmented DNA was phosphorylated at either the 3' or 5'-strand termini.     

A comparative study of the functions of recBCD-nuclease from Escherichia coli and "recombinase", encoded by plasmid R1drd-19]

The RecBCD nuclease of Escherichia coli and "recombinase" determined by R1drd-19 plasmid (the latter is able to replace at least partially the indicated cellular enzyme) were shown to differ from each other in some essential features. The product encoded by the plasmid as distinct from RecBCD nuclease practically is not sensitive to inhibition by GamS protein of the lambda phage. Earlier, it was found that the presence of R1drd-19 plasmid in the recBC cells restores the level of the total ATP-dependent exonuclease activity because of appearance in such cells of a new exonuclease activity also ATP-dependent. The exonuclease activity determined by R1drd-19 plasmid was found to differ from the corresponding activity of the RecBCD enzyme. The plasmid enzyme was able to prevent reproduction of T4g2- mutant on recBC cells. The ability of the plasmid "recombinase" to some stimulation of intrachromosomal recombination in recA mutant witness to incomplete RecA-dependence of its function. No significant homology was registered between Escherichia coli DNA fragment containing the recB, recC, recD genes and the EcoRI-C-fragment of R1drd-19 carrying the sequences responsible for recombination and repair functions of the plasmid.     

Partial purification and properties of a bacteriophage T7 inhibitor of the host exonuclease V activity.

Infection of Escherichia coli with bacteriophage T7 results in an inhibition of the host exonuclease V (recB, C DNase) activity. This inhibition is not observed when cells are infected in the presence of chloramphenicol or with a gene 1 mutant. The protein responsible for the inhibition of exonuclease V has been partially purified from T7-infected cells. The protein which does not possess nuclease or ATPase activity can inhibit all nucleolytic activities associated with exonuclease V. The protein does not, however, inhibit the DNA-dependent ATPase activity associated with exonuclease V. The inhibitory protein has a molecular weight of about 12,000, as determined from sedimentation analysis in glycerol gradients.     

Purification and subunit structure of recBC DNase from Escherichia coli harboring a recB and recC genes-inserted plasmid

recBC DNase of Escherichia coli has been purified from the transformant, HB101/pFS11-04 (recB+ recC+), by successive ammonium sulfate fractionation, DEAE-cellulose chromatography, Sephadex G-150 gel filtration, hydroxyapatite chromatography, DNA cellulose affinity chromatography, and second DEAE-cellulose chromatography. The purified enzyme was obtained in an overall yield of 3%. The enzyme protein appeared as a single pure component on native polyacrylamide gel electrophoresis. The purified enzyme was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional electrophoresis. The results show that recBC DNase consists of two nonidentical subunits with molecular weights of 125,000 and 135,000, and isoelectric points of 5.6 and 5.7, respectively.     

Ca2+, calmodulin-dependent phosphorylation of glycogen synthase by a brain protein kinase

The inactivation of rec BC nuclease activity and simultaneously the separation of 3 DNA-dependent ATPases and an ATP-independent DNases specific for single-stranded DNA have been observed after DEAE-cellulose chromatography of cell extracts from Escherichia coli. Two of the ATPases catalyze the strand separation of duplex DNA. Reconstitution of ATP-dependent DNase activity has been carried out by the combination of the separated enzymes.     

A defect in the acetyl coenzyme A<-->acetate pathway poisons recombinational repair-deficient mutants of Escherichia coli

Recombinational repair-dependent mutants identify ways to avoid chromosomal lesions. Starting with a recBC(Ts) strain of Escherichia coli, we looked for mutants unable to grow at 42 degrees C in conditions that inactivate the RecBCD(Ts) enzyme. We isolated insertions in ackA and pta, which comprise a two-gene operon responsible for the acetate<-->acetyl coenzyme A interconversion. Using precise deletions of either ackA or pta, we showed that either mutation makes E. coli cells dependent on RecA or RecBCD enzymes at high temperature, suggesting dependence on recombinational repair rather than on the RecBCD-catalyzed linear DNA degradation. Complete inhibition of growth of pta/ackA rec mutants was observed only in the presence of nearby growing cells, indicating cross-inhibition. pta rec mutants were sensitive to products of the mixed-acid fermentation of pyruvate, yet none of these substances inhibited growth of the double mutants in low-millimolar concentrations. pta, but not ackA, mutants also depend on late recombinational repair functions RuvABC or RecG. pta/ackA recF mutants are viable, suggesting, together with the inviability of pta/ackA recBC mutants, that chromosomal lesions due to the pta/ackA defect are of the double-strand-break type. We have isolated three insertional suppressors that allow slow growth of pta recBC(Ts) cells under nonpermissive conditions; all three are in or near genes with unknown functions. Although they do not form colonies, ackA rec and pta rec mutants are not killed under the nonpermissive conditions, exemplifying a case of synthetic inhibition rather than synthetic lethality.     

On the role of ATP in phosphodiester bond hydrolysis catalyzed by the recBC deoxyribonuclease of Escherichia coli.

The deoxyribonuclease specified by the recB and recC genes of Escherichia coli (recBC DNase; exonuclease V) has been purified to near homogeneity by a new procedure. Although hydrolysis of even a single nucleotide from a duplex DNA molecule by the pure enzyme is absolutely dependent upon ATP, the extent of phosphodiester hydrolysis is strongly inhibited by ATP concentrations of 0.2 mm or greater, and the initial rate is unaffected. Under these conditions, the extent of DNA hydrolysis is proportional to enzyme concentration. In contrast, neither the rate nor the extent of hydrolysis of single-stranded DNA nor ATP is affected by high concentrations of ATP. The amount of large single-stranded polynucleotide generated by the action of the recBC DNase increases as the ATP concentration increases and, at 0.5 mM ATP, becomes equivalent to the amount of acid-soluble nucleotide formed. These findings suggest that high intracellular concentrations of ATP affect the mechanism of the recBC DNase so as to limit the extent of hydrolysis of duplex DNA, while at the same time favoring the formation of single-stranded regions within the duplex. Such regions may be essential intermediates in the recombination process.     

Constitutive inhibition of DNA degradation due to the enzyme RecBCD in the radiation-resistant Escherichia coli K-12 mutant Gam(r)444]

Exonucleolytic degradation of [3]H-labeled DNA was examined in partially purified fractions of lysates obtained from nonirradiated RecBCD enzyme-containing cells of Escherichia coli and in the radiation-resistant mutant Gamr444. The degradative activity was shown to be lowered in these cells to the same extent as in the recBC mutant. The efficiency of plating of the mutant phage T4 2-, DNA of which can be degraded by exonuclease V, was 400-fold higher on the strain Gamr444 than on the wild-type strain AB1157. This value was shown to be only twice as low as that on the recB mutant or on the strain AB1157 carrying plasmid pGam26 with a radiation-resistance allele gam26 cloned from mutant Gamr444. The data obtained confirmed the hypothesis that the Gamr444 mutant contains a constitutive inhibitor of exonucleolytic activity of the RecBCD enzyme in nonirradiated cells. This inhibitor was shown to be encoded by the gam26 allele that had previously been mapped at 56.8 min of the E. coli chromosome. A possible mechanism of the involvement of this inhibitor in enhanced radiation resistance of the mutant Gamr444 is considered.     

In vivo effects of recBC DNase, exonuclease I, and DNA polymerases of Escherichia coli on the infectivity of native and single-stranded DNA of bacteriophage T7.

The effect of several enzymes of the DNA metabolism of Escherichia coli on the biological activity of native and single-stranded T7 DNA was studied by transfection of lysozyme-EDTA spheroplasts prepared from various E. coli mutants. It is shown that the presence of the recBC DNase in the recipient cells decreases the infectivity of native and denatured DNA by about 100- and 10-fold, respectively. Lack of exonuclease I did not stimulate transfection by single-stranded DNA. Separated light (l) and heavy (r) strands of T7 DNA are fully infective, with a linear dependence on DNA concentrations, whereas heat-denatured DNA shows a two-hit kinetics. Single-stranded DNA was observed to depend on a functional DNA polymerase III for infectivity in polAB cells, whereas transfection with native T7 DNA was independent of the host DNA polymerases. The results are discussed with respect to the mode of T7 DNA replication.     

Differential Thermolability of Exonuclease and Endonuclease Activities of the recBC Nuclease Isolated from Thermosensitive recB and recC Mutants

The recBC nuclease (also called exonuclease V) has been partially purified from Escherichia coli K-12 strains carrying the thermosensitive recB270, recC271, and recB270 recC271 mutations. Of the multiple activities associated with the enzyme, only the adenosine 5'-triphosphate-dependent exonucleolytic hydrolysis of duplex deoxyribonucleic acid (DNA) is abnormally thermolabile. The exo- and endonucleolytic degradation of single-stranded DNA is no more thermosensitive than that catalyzed by the wild-type enzyme. These results suggest that the defects in genetic recombination, DNA repair, and the maintenance of cell viability observed in recBC mutants in vivo result primarily from the specific loss of adenosine 5'-triphosphate-dependent exonuclease active on duplex DNA.     

Role of recBC nuclease in Escherichia coli transformation.

In Escherichia coli transformation with linear donor deoxyribonucleic acid, the recBC pathway is functional, but genetic analysis shows that the recBC nuclease is deleterious to linear deoxyribonucleic acid.     

Recombination-Dependent Growth in Exonuclease-Depleted Recbc Sbcbc Strains of Escherichia Coli K-12

Analysis of the aroLM-sbcCD interval of the Escherichia coli K-12 chromosome revealed a new gene (rdgC) encoding a function required for growth in recombination-deficient recBC sbcBC strains. Deletion of rdgC does not reduce viability, conjugational recombination, or DNA repair in rec(+), recA, recB, recF, or recJ mutants. However, it makes the growth of recBC sbcBC strains reliant on the RecA, RecF, and RuvC proteins and, to a large extent, on RuvAB. The recBC sbcBC ΔrdgC ruvAB construct forms colonies, but cell viability is reduced to <5%. A recBC sbcBC ΔrdgC derivative carrying the temperature-sensitive recA200 allele grows at 32° but not 42°. Multicopy rdgC(+) plasmids reduce the growth rate of recBC sbcBC strains, while multicopy sbcC(+) plasmids that reactivate SbcCD nuclease cannot be maintained without RdgC protein. The data presented are interpreted to suggest that exonuclease-depleted recBC sbcBC strains have difficulty removing the displaced arm of a collapsed replication fork and that this problem is compounded in the absence of RdgC. Recombination then becomes necessary to repair the fork and allow chromosome duplication to be completed. The possibility that RdgC is an exonuclease is discussed.     

Identification of two conserved aspartic acid residues required for DNA digestion by a novel thermophilic Exonuclease VII in Thermotoga maritima

Exonuclease VII was first identified in 1974 as a DNA exonuclease that did not require any divalent cations for activity. Indeed, Escherichia coli ExoVII was identified in partially purified extracts in the presence of EDTA. ExoVII is comprised of two subunits (XseA and XseB) that are highly conserved and present in most sequenced prokaryotic genomes, but are not seen in eukaryotes. To better understand this exonuclease family, we have characterized an ExoVII homolog from Thermotoga maritima. Thermotoga maritima XseA/B homologs TM1768 and TM1769 were co-expressed and purified, and show robust nuclease activity at 80 degrees C. This activity is magnesium dependent and is inhibited by phosphate ions, which distinguish it from E. coli ExoVII. Nevertheless, both E. coli and T. maritima ExoVII share a similar putative active site motif with two conserved aspartate residues in the large (XseA/TM1768) subunit. We show that these residues, Asp235 and Asp240, are essential for the nuclease activity of T. maritima ExoVII. We hypothesize that the ExoVII family of nucleases can be sub-divided into two sub-families based on EDTA resistance and that T. maritima ExoVII is the first member of the branch that is characterized by EDTA sensitivity and inhibition by phosphate.     

Identification and developmental expression of inhibitor of caspase-activated DNase (ICAD) in Drosophila melanogaster

DNA fragmentation, a hallmark of apoptosis, is regulated by a specific nuclease called caspase-activated DNase (CAD) and its inhibitor (ICAD). When cell lysates from Drosophila S2 cells were chemically denatured and the denatured proteins were removed after dialysis, the supernatant inhibited Drosophila CAD (dCAD). To identify the inhibitor, we tested recombinant DREP-1, which was previously identified using the Drosophila EST data base and found it also inhibited dCAD DNase. An antibody against DREP-1 inhibited the ICAD activity in the S2 cell extracts, confirming the identification of DREP-1 as a Drosophila homolog of ICAD (dICAD). The recombinant DREP-1/dICAD was cleaved at a specific site by human caspase 3 as well as by extracts prepared from S2 cells undergoing apoptosis. Biochemical fractionation and immunoprecipitation of dICAD from S2 cell extracts indicated that dICAD is complexed with dCAD in proliferating cells. The expression of the caspase-resistant form of dICAD/DREP-1 in a Drosophila neuronal cell line prevented the apoptotic DNA fragmentation. Northern hybridization and the immunohistochemical analyses revealed that the expression of the dICAD gene is developmentally regulated.     

Nuclear translocation of a leukocyte elastase Inhibitor/Elastase complex during staurosporine-induced apoptosis: role in the generation of nuclear L-DNase II activity

Using L1210 murine leukemia cells, we have previously shown that in response to treatment with drugs having different targets, apoptotic cell death occurs through at least two different signaling pathways. Here, we present evidence that nuclear extracts from staurosporine-treated cells elicit DNase II activity that is not detected in nuclear extracts from cisplatin-treated cells. This activity correlates with the accumulation of two nuclear proteins (70 and 30 kDa) which are detected by an anti-L-DNase II antibody. Partial purification of this DNase II activity suggests that the 30-kDa protein could be the nuclease responsible for staurosporine-induced DNA fragmentation. The 70-kDa protein is also recognized by an anti-elastase antibody, suggesting that it carries residues belonging to both L-DNase II and elastase. Since previous findings showed that L-DNase II was generated from the leukocyte inhibitor of elastase, we propose that the 70-kDa protein results from an SDS-stable association between these two proteins and is translocated from the cytoplasm to the nucleus during staurosporine-induced apoptosis.