Role of exonucleases V and VIII in adenosine 5''-triphosphate- and deoxynucleotide triphosphate-dependent strand break repair in toluenized Escherichia coli cells treated with X-rays.

The repair of X-ray-induced strand breaks was studied in permeabilized Escherichia coli recBC cells deficient for the adenosine 5'-triphosphate (ATP)-dependent exonuclease V and in recBC sbcA cells that possess the ATP-independent exonuclease VIII. It is shown that repair induced by additon of ATP does not take place in recBC and recBC sbcB cells and is limited in recBC sbcA cells. ATP-dependent repair is nevertheless observable if together with ATP a mixture of deoxynucleotide monophosphates is supplied to the cells. These data fit with the assumption that in wild-type cells ATP-dependent repair involves exonuclease V-induced deoxyribonucleic acid degradation and rephosphorylation of the degradation products which are reused for deoxyribonucleic acid polymerase I-dependent break closure. Repair in the presence of deoxynucleotide triphosphates rejoins a similar fraction of breaks in all strains tested irrespective of the amount of postirradiation degradation resulting from exonuclease V and exonuclease VIII activities. Thus, exonuclease V is dispensable for deoxynucleotide triphosphate-dependent repair, i.e., does not "clean" the ends of breaks produced by X-irradiation. ATP- and deoxynucleotide triphosphate-dependent repair are not additive and seem to repair the same population of deoxyribonucleic acid molecules damaged by X-irradiation.     

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.     

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.     

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).     

Alterations in cloned Xenopus ribosomal spacers generated by high-frequency plasmid recombination

In an attempt to understand the mechanisms that have led to the complex intraspecific heterogeneity in spacer organisation found in Xenopus r.DNA, we have transformed Escherichia coli strains that exhibit high levels of plasmid recombination with Xenopus laevis r.DNA sequences inserted in pBR322. We have found that in these recBC sbcA strains, plasmid recombination results in the generation of many types of altered r.DNA spacer at a high frequency. The altered spacers result from two types of deletion/duplication events that occur in the promoter-derived sequences making up much of the spacer. The alterations caused by these events mimic in several ways the different types of organisation found among spacers in the genome. The sbcA-dependent plasmid recombination apparently provides a test system for reconstructing some of the recombinational events that operate during the evolution and maintenance of spacer DNA sequences in vivo.     

(AT)n is an interspersed repeat in the Xenopus genome.

We have observed (AT)34 and (AT)23 tracts close to the coding sequences of the Xenopus laevis tadpole alpha T1 and adult beta 1 globin genes, respectively. We show that (AT)n sequences are found as interspersed repeats within the Xenopus globin and histone gene loci. Using (AT)n co-polymer in filter hybridisation experiments we estimate that there are 10(4) (AT)n tracts per haploid Xenopus genome. Hybridisation to genomic blots of DNA from yeast, slime mold, trypanosome, fruit fly, salmon, chicken, rat, human, crab and Xenopus species shows that strictly alternating AT of sufficient length to hybridise appears to be most abundant in Xenopus and crab genomes. We show that the specificity of the co-polymer probe for strictly alternating AT is, however, dependent on the length of the probe. Hybridisation experiments using (TG)n copolymer suggest that this highly conserved repeat is found as clustered repeats in the Xenopus genome in contrast to other eukaryotic genomes so far studied.     

sbcB15 And DeltasbcB mutations activate two types of recf recombination pathways in Escherichia coli

Escherichia coli cells with mutations in recBC genes are defective for the main RecBCD pathway of recombination and have severe reductions in conjugational and transductional recombination, as well as in recombinational repair of double-stranded DNA breaks. This phenotype can be corrected by suppressor mutations in sbcB and sbcC(D) genes, which activate an alternative RecF pathway of recombination. It was previously suggested that sbcB15 and DeltasbcB mutations, both of which inactivate exonuclease I, are equally efficient in suppressing the recBC phenotype. In the present work we reexamined the effects of sbcB15 and DeltasbcB mutations on DNA repair after UV and gamma irradiation, on conjugational recombination, and on the viability of recBC (sbcC) cells. We found that the sbcB15 mutation is a stronger recBC suppressor than DeltasbcB, suggesting that some unspecified activity of the mutant SbcB15 protein may be favorable for recombination in the RecF pathway. We also showed that the xonA2 mutation, a member of another class of ExoI mutations, had the same effect on recombination as DeltasbcB, suggesting that it is an sbcB null mutation. In addition, we demonstrated that recombination in a recBC sbcB15 sbcC mutant is less affected by recF and recQ mutations than recombination in recBC DeltasbcB sbcC and recBC xonA2 sbcC strains is, indicating that SbcB15 alleviates the requirement for the RecFOR complex and RecQ helicase in recombination processes. Our results suggest that two types of sbcB-sensitive RecF pathways can be distinguished in E. coli, one that is activated by the sbcB15 mutation and one that is activated by sbcB null mutations. Possible roles of SbcB15 in recombination reactions in the RecF pathway are discussed.     

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.     

5-Azacytidine: survival and induction of the SOS response in Escherichia coli K-12

Survival and induction of the SOS system by 5-azacytidine, an analog of cytidine, were studied in Escherichia coli K-12. This compound did not produce any effect on the viability of dcm and dam dcm mutants. Furthermore, recA430 and lexA1 strains (both mutations interfere with LexA repressor cleavage but not recombination proficiency) were more resistant than the wild-type strain of E. coli K-12. In contrast, recBC and recA13 mutants were more sensitive to 5-azacytidine than the wild type. Transient exposure of E. coli to 5-azacytidine for 60 min induced both recA-dependent inhibition of cell division and induction of lambda prophage in Dcm+ strains but not in Dcm- mutants. Expression of both functions was dependent on recBC exonuclease. On the other hand, 5-azacytidine was unable to trigger the induction of umuCD and mucB genes and no amplification of RecA protein synthesis in either Dcm+ or Dcm- strains was observed. These last results are in agreement with previously reported data suggesting that there is a discrimination in the expression of the several SOS functions and that some SOS genes may be induced without amplification of RecA protein synthesis.     

Postinfection control by bacteriophage T4 of Escherichia coli recBC nuclease activity.

Infection by bacteriophage T4 has previously been shown to cause a rapid inhibition of the host recBC DNase, an ATP-dependent DNase that is required for genetic recombination in Escherichia coli. We report here the partial purification of a protein ("T4 rec inhibitor") from extracts of T4-infected cells and some characteristics of the in vitro inhibition reaction with purified inhibitor and recBC nuclease. This inhibitory activity could not be purified from extracts of uninfected E. coli. Both the ATP-dependent exonuclease and DNA-dependent ATPase activities of recBC DNase are inhibited by T4 rec inhibitor. Experiments suggest that the inhibitor interacts with the nuclease in a stoichiometric manner. The biological significance of this inhibition is discussed with respect to control reactions in phage-infected cells.     

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.     

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.     

Double helicase II (uvrD)-helicase IV (helD) deletion mutants are defective in the recombination pathways of Escherichia coli.

The Escherichia coli helD (encoding helicase IV) and uvrD (encoding helicase II) genes have been deleted, independently and in combination, from the chromosome and replaced with genes encoding antibiotic resistance. Each deletion was verified by Southern blots, and the location of each deletion was confirmed by P1-mediated transduction. Cell strains containing the single and double deletions were viable, indicating that helicases II and IV are not essential for viability. Cell strains lacking helicase IV (delta helD) exhibited no increase in sensitivity to UV irradiation but were slightly more resistant to methyl methanesulfonate (MMS) than the isogenic wild-type cell strain. As expected, cell strains containing the helicase II deletion (delta uvrD) were sensitive to both UV irradiation and MMS. The introduction of the helicase IV deletion into a delta uvrD background had essentially no effect on the UV and MMS sensitivity of the cell strains analyzed. The double deletions, however, conferred a Rec- mutant phenotype for conjugational and transductional recombination in both recBC sbcB(C) and recBC sbcA backgrounds. The Rec- mutant phenotype was more profound in the recBC sbcB(C) background than in the recBC sbcA background. The recombination-deficient phenotype indicates the direct involvement of helicase II and/or helicase IV in the RecF pathway [recBC sbcB(C) background] and RecE pathway (recBC sbcA background) of recombination. The modest decrease in the recombination frequency observed in single-deletion mutants in the recBC sbcB(C) background suggests that either helicase is sufficient. In addition, helicase IV has been overexpressed in a tightly regulated system. The data suggest that even modest overexpression of helicase IV is lethal to the cell.     

Escherichia coli recBC deletion mutants.

Mutants of Escherichia coli with deletions of the recB and recC genes were obtained by two methods using transposable DNA elements. The phenotypes of these mutants are similar to those of mutants with recBC point mutations. These results indicate that the RecBC gene products, exonuclease V, is not essential for the growth of E. coli but is important for DNA repair and recombination.     

Orientation Dependence in Homologous Recombination

Homologous recombination was investigated in Escherichia coli with two plasmids, each carrying the homologous region (two defective neo genes, one with an amino-end deletion and the other with a carboxyl-end deletion) in either direct or inverted orientation. Recombination efficiency was measured in recBC sbcBC and recBC sbcA strains in three ways. First, we measured the frequency of cells carrying neo(+) recombinant plasmids in stationary phase. Recombination between direct repeats was much more frequent than between inverted repeats in the recBC sbcBC strain but was equally frequent in the two substrates in the recBC sbcA strain. Second, the fluctuation test was used to exclude bias by a rate difference between the recombinant and parental plasmids and led to the same conclusion. Third, direct selection for recombinants just after transformation with or without substrate double-strand breaks yielded essentially the same results. Double-strand breaks elevated recombination in both the strains and in both substrates. These results are consistant with our previous findings that the major route of recombination in recBC sbcBC strains generates only one recombinant DNA from two DNAs and in recBC sbcA strains generates two recombinant DNAs from two DNAs.     

mRNA- and DNA-directed synthesis of herpes simplex virus-coded exonuclease in Xenopus laevis oocytes

Microinjection of herpes simplex virus (HSV)-infected cell mRNA into Xenopus laevis oocytes resulted in the production of a new exonuclease activity. This enzyme strongly resembled the HSV alkaline exonuclease in many biochemical properties, and hybrid-arrested translation studies showed that it was virus coded, mapping at 0.080 to 0.185 genome map units. Exonuclease mRNA had a size and genome location equivalent to the mRNA encoding V185 in reticulocyte lysates, suggesting that V185 is the exonuclease. The enzyme synthesized in oocytes was found to act as an exonuclease in vivo. Two plasmids containing HSV DNA fragments directed the synthesis of exonuclease when microinjected into oocyte nuclei, and this finding enabled the coding and control sequences for this gene to be localized to 0.155 to 0.185 genome map units.     

Anatomy of herpes simplex virus DNA. V. Terminally repetitive sequences.

Native DNA from four strains of herpes simplex virus 1 (HSV-1) circularized after digestion with the lambda exonuclease, indicating that the molecules were terminally repetitious. In two strains, the terminal repetition was evident in nearly 50% of the DNA molecules. Maximal circularization was observed when only 0.25 to 0.5% of the DNA was depolymerized by the exonuclease, suggesting that the minimal size of the terminally repetitious regions is in the range of 400 to 800 bases pairs. More extensive exonuclease treatment resulted in a reduction in the frequency of circularization. To determine whether the terminally repetitive regions themselves contained self-annealing sequences that were precluding circularization of more extensively digested DNA, the terminal fragments from HinIII restriction endonuclease digests were isolated, denatured, and tested for their ability to self-anneal. The results of hydroxyapatite column chromatography and electron microscope examination of the terminal regions are consistent with this hypothesis.     

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.     

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.     

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.