Quantitation of the inhibition of Hfr x F- recombination by the mutagenesis complex UmuD'C.

The UmuD'C complex and RecA protein are two essential components in mutagenic repair of gaps produced by the replication of damaged DNA. In this process, the UmuD'C complex might help DNA polymerase to synthesize DNA across a lesion. Besides, a RecA polymer wrapping around single-stranded DNA could function as a directional chaperone to target the UmuD'C complex at the lesion. It was shown in our laboratory that the UmuD'C complex prevents homologous recombination and recombinational repair when expressed at elevated levels. To find out whether the UmuD'C complex inhibits recombination by interfering directly with RecA, we measured the kinetics of inhibition of Hfr x F- recombination in F- recipients in which either RecA or UmuD'C were made to vary. The cell concentrations of RecA and UmuD'C proteins were adjusted by having the recA and the umuD'C genes regulated by the arabinose P(BAD) promoter. In the absence of the UmuD'C complex, recombination was a function of RecA concentration and then reached a plateau when the RecA concentration was above 9000 monomers/cell. At a fixed RecA concentration, the yield of Hfr x F- recombinants decreased as a function of the UmuD'C cell concentration. At a given UmuD'C/RecA ratio, recombination inhibition by UmuD'C was reversed by increasing the RecA cell concentration. RecA1730, a mutant protein impaired in the chaperone activity, was insensitive to UmuD'C inhibition. We propose a model accounting for the RecA chaperone function in SOS mutagenesis and for the UmuD'C inhibitory effect on homologous recombination. We suggest that the UmuD'C complex is placed at the tip of a RecA polymer as a result of a treadmilling process. This would position the UmuD'C complex right at a lesion while the capping by UmuD'C would destabilize a RecA polymer and thereby abort the recombination process.

Gratuitous induction.

We describe a novel mode of SOS induction, called gratuitous indirect induction, which is elicited when the maintenance of an intact lambda miniF introduced into a recipient was inhibited by a resident plasmid or by mutations in miniF that impaired partition or replication. Gratuitous induction required the presence of the lynA locus on miniF and was dependent on the host recA and lexA alleles. To account for gratuitous induction, we postulate that impairment of the normal co-regulation between partition and replication of miniF affects lynA functions whose disturbance leads to the production of an SOS signal.

Characterization of a mutant RecA protein that facilitates homologous genetic recombination but not recombinational DNA repair: RecA423.

A recA mutant (recA423; Arg169-->His), with properties that should help clarify the relationship between the biochemical properties of RecA protein and its two major functions, homologous genetic recombination and recombinational DNA repair, has been isolated. The mutant has been characterized in vivo and the purified RecA423 protein has been studied in vitro. The recA423 cells are nearly as proficient in conjugational recombination, transductional recombination, and recombination of lambda red- gam- phage as wild-type cells. At the same time, the mutant cells are deficient for intra-chromosomal recombination and nearly as sensitive to UV irradiation as a recA deletion strain. The cells are proficient in SOS induction, and results indicate the defect involves the capacity of RecA protein to participate directly in recombinational DNA repair. In vitro, the RecA423 protein binds to single-stranded DNA slowly, with an associated decline in the ATP hydrolytic activity. The RecA423 protein promoted a limited DNA strand exchange reaction when the DNA substrates were homologous, but no bypass of a short heterologous insert in the duplex DNA substrate was observed. These results indicate that poor binding to DNA and low ATP hydrolysis activity can selectively compromise certain functions of RecA protein. The RecA423 protein can promote recombination between homologous DNAs during Hfr crosses, indicating that the biochemical requirements for such genetic exchanges are minimal. However, the deficiencies in recombinational DNA repair suggest that the biochemical requirements for this function are more exacting.

Indirect SOS induction is promoted by ultraviolet light-damaged miniF and requires the miniF lynA locus.

Indirect prophage induction is produced by transfer to recipients of u.v.-damaged F plasmid (95 kb). We tested whether the SOS signal can be produced by miniF, a 9.3 kb restriction fragment, coding for the replication and segregation functions of plasmid F. We used lambda miniF, a hybrid phage-plasmid. u.v.-irradiated lambda miniF induced prophages phi 80 or lambda and sfiA, a chromosomal SOS gene, in more than 50% of the infected cells. The maximal inducing dose produced about 0.5 pyrimidine dimers per kb and left 1% of lambda miniF survivors. Thus, the SOS signal produced by u.v.-damaged lambda miniF was almost as potent as that resulting from direct u.v.-irradiation of the lysogens. The u.v.-damaged vector lambda, devoid of miniF, failed to promote SOS induction. In contrast, efficient induction was observed when u.v.-damaged lambda miniF infected a lambda immune host, in which replication and expression of the phage genome were repressed. When replication and expression of the miniF genome was repressed by Hfr incompatibility, SOS induction was largely prevented. All these facts indicate that, in the hybrid lambda-miniF, it is the u.v.-damaged miniF that generates an SOS signal. To locate on the miniF genome the loci that are involved in the production of the SOS signal, we isolated deletions spanning all the miniF restriction fragments. We characterized six mutant phenotypes (Par+, Rep-, Fid-, Par-2, Par-1 and SOS-) related to four functions; partition, copy number, replication and SOS induction. A locus, we call lynA, 800 bp long, located by deletion mapping between the two origins of replication oriP and oriS is required for the production of an inducing signal. We postulate that indirect SOS induction by u.v.-damaged miniF results from the disturbance of the lynA function that may be involved in the co-segregation of F plasmid with the host chromosome.

Damaged-site independent mutagenesis of phage lambda produced by inducible error-prone repair.

The existence of damaged-site independent mutagenesis is confirmed here by scoring the appearance of clear-plaque (c-) or virulent (vir) forward mutations on intact (non-irradiated) phage lambda grown on UV-irradiated E. coli K12 hosts. The mutation frequency was measured as a function of the incubation time between the occurrence of host DNA lesions and phage infection. The time course of mutagenesis of intact phage followed the induction pattern observed upon UV-reactivation of UV-damaged phage by Defais et al. (1976). Intact phage did not mutate in UV-irradiated hosts carrying the uvm-25 mutation known to prevent the occurrence of UV-reactivation. These findings suggest that damaged-site independent mutagenesis results from inducible error-prone repair. Clear-plaque mutations arising on intact phage were mostly found in phage bursts consisting of clear and turbid plaque formers whereas UV-damaged phage gave rise to mostly clear-plaque formers. Contrarily to damaged-site dependent mutagenesis, damaged-site independent mutagenesis can arise even at late times during the phage replication cycle. Our data indicate that about half of the phage mutations that arise upon UV-reactivation are damaged-site independent mutations. Replication of intact phage DNA in a host during induction of SOS functions provides a sensitive assay for the detection of damaged-site independent mutagenesis.

Induction of prophage lambda does not require full induction of RecA protein synthesis.

In mitomycin C-treated lambda lysogens, even though the rate of synthesis of RecA protein was greatly reduced by a low concentration of rifampicin (4 microgram/ml), induction of prophage lambda occurred readily as assessed by (i) cell lysis of the lysogens, (ii) production of progeny phage, and (iii) extensive cleavage of lambda repressor. The extent and the rate of cleavage of lambda repressor were not significantly affected by the low rate of synthesis of RecA protein resulting from rifampicin action. However, the yield of phage progeny was reduced and lysis of the cells was slightly delayed. We conclude that in RecA+ bacteria, induction of prophage lambda does not require full induction of RecA protein synthesis.

Substitution of UmuD' for UmuD does not affect SOS mutagenesis.

In order to study the role of UmuDC proteins in SOS mutagenesis, we have constructed new Escherichia coli K-12 strains to avoid i) over-production of Umu proteins, ii) the formation of unwanted mixed plasmid and chromosomal Umu proteins upon complementation. We inserted a mini-kan transposon into the umuD gene carried on a plasmid. The insertion at codon 24 ends protein translation and has a polar effect on the expression of the downstream umuC gene. We transferred umuD24 mutation to the E coli chromosome. In parallel, we subcloned umuD+ umuC+ or umuD' umuC+ genes into pSC101, a low copy number plasmid. In a host with the chromosomal umuD24 mutation, plasmids umuD+ umuC+ or umuD' umuC+ produced elevated resistance to UV light and increased SOS mutagenesis related to a gene dosage of about 3. UV mutagenesis was as high in umuD' umuC+ hosts devoid of UmuD+ protein as in umuD+ umuC+ hosts. UmuD' protein, the maturated form of UmuD, can substitute for UmuD in SOS mutagenesis.

A RecA protein mutant deficient in its interaction with the UmuDC complex.

recA1730 is a dominant point mutation preventing SOS mutagenesis. We demonstrate here that: i) RecA1730 fails to produce mutagenesis even though UmuD' is formed, ii) recA1730, when complemented by recA+, can cleave LexA protein and it displays a UmuDC- phenotype in spite of adequate concentrations of matured UmuD' and UmuC proteins, iii) the Mut- phenotype caused by RecA1730 is partially alleviated by MucAB proteins, functional analogs of UmuDC. To explain the mutant phenotype, we postulate that recA1730 impairs a RecA function required for the positioning of the UmuD'C complex within the replisome at the site of lesions.

Identification of a mouse cDNA fragment whose expressed polypeptide reacts with anti-recA antibodies.

We have previously reported the in vivo detection of a mouse nuclear protein that cross-reacts with antibodies raised against E coli recA protein. Here, we characterize monospecific anti-recA antibodies, their use for the immunological screening of a cDNA expression library and the isolation of a mouse cDNA fragment which codes for a polypeptide recognized by anti-recA antibodies. The cDNA fragment is 601 nucleotide long and was called KIN17(601). It contains an open reading frame coding for a 200 amino acid polypeptide. In kin17(200) polypeptide, there are amino acids identical to those that form one of the major antigenic determinants of recA protein. Kin17(200) polypeptide also displays a significant similarity with the helix 1 motif of several homeoproteins.

At the birth of molecular radiation biology.

Rational thinking builds on feelings, too. This article starts with a tribute to Richard Setlow, an eminent scientist; it retraces as well some studies in molecular genetics that helped to understand basic questions of radiation biology. In the mid-1950s, the induction of a dormant virus (prophage) by irradiation of its host was an intriguing phenomenon. Soon, it was found that prophage induction results from the inactivation of the prophage repressor. Similarly, a score of induced cellular SOS functions were found to be induced when the LexA repressor is inactivated. Repressor inactivation involves the formation of a newly formed distinctive structure: a RecA-polymer wrapped around single-stranded DNA left by the arrest of replication at damaged sites. By touching this RecA nucleofilament, the LexA repressor is inactivated, triggering the sequential expression of SOS functions. The RecA nucleofilament acts as a chaperone, allowing recombinational repair to occur after nucleotide excision repair is over. The UmuD'C complex, synthesized slowly and parsimoniously, peaks at the end of recombinational repair, ready to be positioned at the tip of a RecA nucleofilament, placing the UmuD'C complex right at a lesion. At this location, UmuD'C prevents recombinational repair, and now acts as an error-prone paucimerase that fills the discontinuity opposite the damaged DNA. Finally, the elimination of lesions from the path of DNA polymerase, allows the resumption of DNA replication, and the SOS repair cycle switches to a normal cell cycle.

Repair promoted by plasmid pKM101 is different from SOS repair.

In E. coli K12 bacteria carrying plasmid pKM101, prophage lambda was induced at UV doses higher than in plasmid-less parental bacteria. UV-induced reactivation per se was less effective. Bacteria with pKM101 showed no alteration in their division cycle. Plasmid pKM101 coded for a constitutive error-prone repair different from the inducible error-prone repair called SOS repair. Plasmid pKM101 protected E. coli bacteria from UV damage but slightly sensitized them to X-ray lesions. Protection against UV damage was effective in mutant bacteria deficient in DNA excision-repair provided that the recA, lexA and uvrE genes were functional. Survival of phages lambda and S13 after UV irradiation was enhanced in bacteria carrying plasmid pKM101; phage lambda mutagenesis was also increased. Plasmid pKM101 repaired potentially lethal DNA lesions, although wild-type DNA sequences may not necessarily be restored; hence the mutations observed are the traces of the original DNA lesions.

Induction and mutagenesis of prophage lambda in Escherichia coli K12 by metabolites of aflatoxin B1.

Like most carcinogens, aflatoxin B1 must be activated by mammalian microsomal enzymes to give rise to coupounds active on bacteria. These compounds act as inducers of E. coli K12 (lambda) at a high efficiency, whereas unmodified aflatoxin B1 has no effect. Moreover, metabolites of aflatoxin B1 have a mutagenic action on phage lambda, as shown by the appearance of clear plaque mutants. We propose the hypothesis that the same derivative is responsible for carcinogenesis of liver cells by aflatoxin B1. Therefore, our system provides a simple way of measuring in vitro, in the same assay, the mutagenic and inducing activities of compounds to which the cells are permeable, thereby detecting potentially carcinogenic agents.

Induced reactivity of UV-damaged phage gamma in E. coli K12 host cells treated with aflatoxin B1 metabolites.

The metabolites of aflatoxin B1, the most potent hepatocarcinogen so far known, promote in E. coli K12 cells the reactivation of phage lambda damaged by ultraviolet (UV) radiation. This reactivation process is error prone; 25% of the phage DNA lesions are repaired, but mutagenesis, scored as clear plaque formation, is increased as much as 10-fold. Such reactivation of UV-damaged phage lambda, which occurs in wild-type and in uvrA but not in recA bacteria, is inducible: phage reactivation is obtained even after a long delay following treatment of the host by the short-lived metabolites. This induced reactivation of UV-damaged phage in hosts treated with metabolites of aflatoxin B1 is similar to direct of indirect UV reactivation. Metabolites of aflatoxin B1 produce induced phage reactivation as well as prophage lambda induction in lysogens and cell filamentation in non-lysogens. These cellular events are also triggered by DNA lesions caused by UV radiation and result from the induction of a metabolic pathway (SOS functions). We postulate that, in eucaryotes, carcinogens may induce cellular SOS functions similar to those in E. coli. Induction of such functions might be responsible for the transformation of mammalian cells.

Expression of a bacterial gene turned on by a potent carcinogen.

Contrary to mutagenesis, lysogenic induction produced by chemical carcinogens occurs in the majority of a population of lysogenic cells. Such a mass effect can therefore be measured at the biochemical level using an E. coli tester strain in which the galactose operon has been put under the negative control of the lambda repressor. In this publication we show that galactokinase synthesis is turned on by aflatoxin B1 metabolites within an hour after treatment of the tester bacteria. Such a biochemical assay provides a useful means for identifying potential chemical carcinogens.

Introduction of a UV-damaged replicon into a recipient cell is not a sufficient condition to produce an SOS-inducing signal.

Three models have been proposed for the nature of the SOS-inducing signal in E. coli. One model postulates that degradation products of damaged DNA generate an SOS-inducing signal; another model surmises that the very lesions produced by UV damage constitute the SOS-inducing signal in vivo; a third model proposes that DNA damage is processed upon DNA replication to form single-stranded DNA (the SOS signal) that activates RecA protein. We tested the models by measuring SOS induction produced by introducing into recipient cells the UV-damaged DNA of 2 constructed phagemids. We used phagemids since they transferred DNA to the recipients with 100% efficiency. The origin of replication of the phagemids was either oriC from the E. coli chromosome, or oriF from F plasmid. Replication of the oriC phagemid was dependent on methylation. A UV-damaged oriC phagemid failed to induce SOS functions in a recipient cell whereas an oriF phagemid did induce them. Our results disprove the first and the second model proposed for the nature of the SOS-inducing signal. The failure of a UV-damaged oriC replicon to induce SOS can be explained by the third model if one assumes that replication of a UV-damaged oriC plasmid does not generate single-stranded DNA as does the E. coli chromosome after UV damage.

Induction of prophage lambda by daunorubicin and derivatives correlation with antineoplastic activity.

The antineoplastic drug daunorubicin and 15 other anthracyclines were tested for their ability to induce prophage lambda in Escherichia coli K12. Prophage lambda induction by daunorubicin was obtained in excision-repair deficient uvr- bacteria at doses about 3-fold lower than in excision-repair proficient uvr+ cells; this suggests that some of the lesions produced in DNA by daunorubicin are subject to excision repair and may be adducts. Daunorubicin seems to be converted to active species capable of causing prophage inducing lesions in DNA by bacterial enzymes. The antineoplastic and prophage inducing potencies of the anthracyclines were compared in a blind test. These two parameters were correlated for two thirds of the compounds. Such a correlation supports the idea that the antineoplastic activity of the anthracyclines is a consequence of their capacity to damage DNA.

KIN, a mammalian nuclear protein immunologically related to E. coli RecA protein.

A polypeptide of about 120 kDa, called KIN, has been identified in rat FR 3T3 cells by immunoblotting using affinity-purified antibodies against the RecA protein of Escherichia coli (38 kDa). The KIN protein as shown by fluorescent light microscopy and electron microscopy is essentially concentrated in the nucleus. Its level is higher in proliferating than in quiescent cells. Cell treatment with mitomycin C increases the level of the KIN protein. We sought similar proteins in other mammalian cells. Proteins with the same electrophoretic mobility were detected in mouse, monkey and human cell lines as well as in rat and mouse embryos.