Photolyase-dimer-DNA complexes and exclusion stimulation in Escherichia coli: Depolarization of the plasma membrane

Using cells that overproduce DNA photolyase, we found that UV irradiation (3 J/m²) efficiently inactivates accumulation of methylthiogalactoside (TMG) when RexAB proteins of phage lambda are present. The effect requires both formation of photolyase-dimer-DNA (PDD) complexes and expression of the RexAB proteins. It is reversed completely by a flash of visible light if given immediately after UV and becomes irreversible after post-UV incubation for about 15 min. Inactivation is significant after only 5 min of post-UV incubation, is accompanied by a loss of previously accumulated TMG, and does not require de novo protein synthesis. Passive transport of O-nitrophenylgalactoside by inactivated cells is typical of energy-depleted membranes. We suggest that PDD complexes mimic a developmental intermediate of phage superinfection and stimulate formation of the RexB membrane channel recently proposed by others to explain classical exclusion. This suggestion is supported by additional data showing an inactivation of colony-forming ability by exclusion stimulation and an inability of PDD complexes to inactivate accumulation of TMG if RexB is present in larger relative amounts than RexA (a detail characteristic of exclusion stimulated by phage superinfection).     

On the lack of host-cell reactivation of UV-irradiated phage T5. I. Interference of T5 infection with the host-cell reactivation of phage T1

UV-irradiated phage T5, in contrast to T1, T3 and T7, fail to display hostcell reactivation (HCR) when infecting excision-repair proficient Escherichia coli cells. Possible causes of this lack of HCR (which T5 shares with the T-even phages) have been investigated by studying HCR of T1 under conditions of superinfection by T5. Repair-proficient B/r cells were infected at low multiplicity with UV-irradiated phage T1 in the presence of 1.8 mg/ml caffeine and were superinfected after 15 min with heavily UV-irradiated T5 amber mutants at high multiplicity. The caffeine, which is later diluted out, prevents any T1 repair prior to T5 superinfection, and UV (254 nm) irradiation of T5 with 144 J/m² reduces the ability of this phage to exclude T1, thus permitting a reasonable fraction of the mixedly infected complexes to produce T1 progeny.Under these conditions, T5 superinfection causes loss of HCR in about 90% of the T1-producing complexes. Superinfection with unirradiated T5 likewise inhibits HCR of T1, but superinfection with irradiated T3 (a host-cell-reactivable phage) does not. This indicates that the observed HCR inhibition of T1 results from T5 infection rather than from competition of irradiated foreign DNA for the excision-repair enzymes of the bacterial host. Employment of apropriate T5 amber mutants has shown that “first-step transfer” (FST) of T5 DNA (involving only 8% of the T5 genome) is sufficient for HCR inhibition, but that transfer of the remainder DNA in addition inhibits a previously described minor T1 recovery process. HCR inhibition of T1, and thus presumably lack of HCR in T5 itself, is ascribed to a substance which is produced either post infection by a gene located in the FST segment of the T5 genome, or which is transferred from extracellular T5 together with the FST DNA.     

In vivo evidence for two active nuclease motifs in the double-strand break repair enzyme RexAB of Lactococcus lactis

In bacteria, double-strand DNA break (DSB) repair involves an exonuclease/helicase (exo/hel) and a short regulatory DNA sequence (Chi) that attenuates exonuclease activity and stimulates DNA repair. Despite their key role in cell survival, these DSB repair components show surprisingly little conservation. The best-studied exo/hel, RecBCD of Escherichia coli, is composed of three subunits. In contrast, RexAB of Lactococcus lactis and exo/hel enzymes of other low-guanine-plus-cytosine branch gram-positive bacteria contain two subunits. We report that RexAB functions via a novel mechanism compared to that of the RecBCD model. Two potential nuclease motifs are present in RexAB compared with a single nuclease in RecBCD. Site-specific mutagenesis of the RexA nuclease motif abolished all nuclease activity. In contrast, the RexB nuclease motif mutants displayed strongly reduced nuclease activity but maintained Chi recognition and had a Chi-stimulated hyperrecombination phenotype. The distinct phenotypes resulting from RexA or RexB nuclease inactivation lead us to suggest that each of the identified active nuclease sites in RexAB is involved in the degradation of one DNA strand. In RecBCD, the single RecB nuclease degrades both DNA strands and is presumably positioned by RecD. The presence of two nucleases would suggest that this RecD function is dispensable in RexAB.     

Effect of cis-Platinum(II)Diamminodichloride on Wild Type and Deoxyribonucleic Acid Repair-Deficient Mutants of Escherichia coli

The anti-tumor drug cis-platinum(II)diamminodichloride (PDD) induced extensive filamentation in wild-type Escherichia coli and in mutants lacking certain deoxyribonucleic acid (DNA) repair functions (uvrA, recB, recC, and polA); viability of repair-deficient mutants treated with PDD was significantly less than that of wild-type cells. PDD was highly toxic to lex1, lex1 uvrA6 (where its effect was cummulative), and recA13 mutants, all of which were killed without formation of filaments. ³H-thymine incorporated into DNA of cells subsequently treated with PDD became trichloroacetic acid-soluble at rates similar to those observed after exposure to comparable doses of ultraviolet light (UV) or mitomycin C. PDD, like UV, induced extensive degradation of DNA in recA organisms. After a 30-min lag, PDD inhibited significantly the synthesis of DNA but not of ribonucleic acid or protein in E. coli. However, the relative differences between rates of DNA synthesis observed in PDD-treated and control cells decreased substantially when the duration of pulses (³H-thymine) was prolonged from 2 to 5 min. These observations suggest that PDD-induced damage to DNA is reversible, possibly by defined mechanisms of excision and recombination repair.     

Superinfection in Bacteriophage S13 and Determination of the Number of Bacteriophage Particles Which Can Function in an Infected Cell

Bacteriophage S13 shows exclusion of superinfecting homologous phage, but the exclusion is only partial. The superinfecting phage can form infectious replicative form deoxyribonucleic acid (RF), can direct protein synthesis, and can form progeny particles even at a superinfection time as late as 60 min after the first infection. Exclusion is also only partial for the closely related phage phiX174. Seven min after the first infection, the exclusion mechanism begins to operate, requiring continuous phage-specified protein synthesis. The gene A protein (required for synthesis of progeny RF) appears to be involved in the exclusion mechanism. In superinfection experiments, it was found that at least 40 phage particles per cell can replicate and can carry out protein synthesis, though the number of sites for binding of RF to the membrane is only about 15 per cell. The results suggest that attachment of RF to a binding site is not required for protein synthesis. Evidence is presented that non-attached parental RF can serve as a template for single-stranded deoxyribonucleic acid synthesis.     

Alkylation of T7 bacteriophage blocks superinfection exclusion

Alkylation of T7 bacteriophage by methyl methane sulfonate blocked superinfection exclusion. This blockage could be correlated with a delay in the synthesis of phage-specific proteins. Therefore we conclude that protein synthesis directed by the primary infecting phage is required for efficient exclusion of superinfecting phage particles.     

DNA damage-processing in E. coli: on-going protein synthesis is required for fixation of UV-induced lethality and mutation

UV irradiation of E. coli produces photoproducts in the DNA genome. In consequence, some bacteria lose viability (colony-forming ability) or remain viable as mutant cells. However, the end-points of viability inactivation (lethality) or mutation are determined by cellular processes that act on the UV-damaged DNA. We have investigated the in vivo time course for processes that deal with cyclobutane pyrimidine dimers (CPD) which can be specifically removed by photoreactivation (PR). At different times during post-UV incubation, samples were challenged with PR and assayed for viability or mutation. We used excision-defective E. coli B/r cells and worked under yellow light to avoid background PR. During post-UV incubation (0-100min) in fully supplemented defined medium, inactivation and mutation were initially significantly reversed by PR but the extent of this reversal decreased during continued incubation defining "fixation" of lethality or mutation, respectively. In contrast, if protein synthesis was restricted during the post-UV incubation, no fixation developed. When chloramphenicol was added to inhibit protein synthesis after 30min of supplemented post-UV incubation, at a time sufficient for expression of UV-induced protein(s), fixation of lethality or mutation was still annulled (no change in the effectiveness of PR developed). Lethality fixation did progress when protein synthesis was restricted and the cells were incubated in the presence of puromycin or were either clpP or clpX defective. We discuss these and related results to suggest (1) on-going protein synthesis is required in the fixation process for lethality and mutation to sustain an effective level of a hypothetical protein sensitive to ClpXP proteolysis and (2) this protein plays a critical role in the process leading to exchange between Pol III activity and alternative polymerase activities required as each cell deals with damage in template DNA.     

A simple and rapid method for evaluating the survival of xeroderma pigmentosum lymphoid lines after irradiation with ultraviolet light

A simple, rapid, and reproducible test has been developed to measure the viability of cells after irradiation with ultraviolet light (UV). Epstein-Barr virus-transformed lymphoid lines, derived from patients with xeroderma pigmentosum (XP), were irradiated with UV, and the post-UV viability of the lymphoid lines was determined by the trypan blue dye exclusion method. The relative post-UV survival of the patients' lymphoid lines was similar to the relative post-UV survival of the patients' fibroblast strains.     

A simple and rapid method for evaluating the survival of xeroderma pigmentosum lymphoid lines after irradiation with ultraviolet light

Summary A simple, rapid and reproducible test has been developed to measure the viability of cells after irradiation with ultraviolet light (UV). Epstein-Barr virus-transformed lymphoid lines, derived from patients with xeroderma pigmentosum (XP), were irradiated with UV, and the post-UV viability of the lymphoid lines was determined by the trypan blue dye exclusion method. The relative post-UV survival of the patients' lymphoid lines was similar to the relative post-UV survival of the patients' fibroblast strains.     

Recovery of the accumulation ability of thiomethyl-beta-galactoside in Escherichia coli after bacteriophage T4 infection.

Effects of UV-irridiated and unirradiated T4 phage infection on the beta-galactoside accumulation ability in Eschericia coli have been examined by the use of 14C-labeled thiomethyl-beta-galactoside (TMG). Under conditions where a synchronous adsorption of phage takes place, the cellular ability for TMG accumulation is found to be largely inhibited immediately after phage adsorption, but it recovers with time to a new level, which is dependent on the multiplicity of infection. When cells are infected with UV-irradiated T4 at the same multiplicity as that of unirradiated phage, the cellular accumulation ability is more severely inhibited and there is no recovery from the inhibition. The recovery process in T4-infected cells is mostly sensitive to puromycin. These results suggest that the initial inhibition of the TMG accumulation ability is probably caused by the adsorption of phage coats, and the subsequent restoration occurs through the action of a phage-directed protein(s). In the recovery process, no new transport system appears to be involved. The restored ability of TMG accumulation is resistant to the action of superinfecting UV phage. However, different mechanisms appear to be operating in T4-infected cells for the establishment of resistance to ghosts and for the recovery from the phage coat-induced inhibition.     

Comparative studies of host-cell reactivation, colony forming ability and excision repair after UV irradiation of xeroderma pigmentosum, normal human and some other mammalian cells

Host-cell reactivation, that is, the degree of survival of Herpes simplex virus after UV irradiation, was high in African green monkey BSC-1 cells, intermediate in normal human fibroblasts and human FL cells, and low in both xeroderma pigmentosum (XP) cells and mouse L cells. However, colony-forming ability after UV was high for FL, normal human fibroblasts and L cells, slightly low for BSC-1 cells and extremely low for XP cells. During the 24-h post-UV incubation period, up to about 50% of the thymine-containing dimers in the acid-insoluble DNA fraction disappeared at an almost equal rate for BSC-1, FL and normal human cells but remained unaltered for the XP cells. Alkaline sucrose gradient centrifugation of DNA after UV irradiation revealed only a slight difference between FL and BSC-1 cells in the kinetics of formation of single-strand breaks and their apparent repair. From these and the previously known characters of L cells possessing reduced excision-repair ability, if any, we may conclude that, if the survival of UV-irradiated Herpes simplex virus on a test line of human or other mammalian cells is as low as that on excisionless XP cells, then it is very probable that the test cell line is defective in excision repair. This reasoning leads to the presumptive conclusion that mouse L cells have an enhanced post-replication repair other than excision repair to deal with UV damage responsible for inactivation of colony-forming ability.     

The effect of UV irradiation on proliferation and life span of human diploid fibroblast-like cells

Summary The effect of low dose UV irradiation on the reinitiation of proliferative activity and on the life span of human diploid fibroblast-like cells is described. Cells were exposed to UV at confluence or after maintenance in an arrested state. Cell division was stimulated immediately after UV irradiation or after an additional post-UV incubation period. Arrested populations of all in vitro ages exhibited a greater sensitivity to UV and the reinitiation of proliferation was enhanced by post-UV incubation before stimulation. Ultraviolet light had no effect on life span regardless of in vitro cell age, culture state at the time of exposure, or the presence of a postirradiation period of arrest.     

Repair and plasmid R46 mediated mutation requires inducible functions in Proteus mirabilis

Summary In Proteus mirabilis nalidixic acid or a predose of UV induce Rec protein formation, a portion of post-UV replication repair and post-UV replication enhancement. These inducible functions are not significantly affected by the plasmid R46, which renders P. mirabilis efficiently UV-mutable. The R46-mediated UV induction of rif ^r mutations requires additional inducible functions, as existing after malidixic acid treatment in rec ⁺ strains. After a nalidixic acid pretreatment UV efficient induction of rif ^r mutations occurs without an otherwise obligatory period of post-UV incubation prior to plating on rifampicin agar. The inducible character of this qualification of plasmid R46-mediated UV mutagenesis in P. mirabilis is evident from the inhibitory effects of chloramphenicol and starvation. Constitutive high-level synthesis of Rec protein in cells harboring the recombinant (multi-copy) rec ⁺ plasmid pPM1 reduced plasmid R46-mediated UV mutagenesis, probably by preventing (inducible?) functions required by the plasmid R46 repair-mutator.     

Inhibition of Replication of Ribonucleic Acid Bacteriophage f2 by Superinfection with Bacteriophage T4

Superinfection by phage T4 of cells infected by the ribonucleic acid (RNA) phage f2 results in inhibition of further f2 production. Experiments using rifampin show that the exclusion of f2 requires T4 gene function soon after T4 infection. By using a sensitive new peptide-mapping procedure to identify f2 coat protein in infected cells, we show that synthesis of the f2 coat occurs at a reduced level until 4 min after T4 superinfection and then ceases abruptly. Within 4 min after T4 superinfection, there are also several changes in f2 RNA metabolism, all of which require T4 gene function: preexisting f2 replicative intermediate RNA and f2 single-stranded RNA are degraded to small but still acid-precipitable fragments, and most f2-specific RNA is released from polyribosomes. We favor the hypothesis that T4 induces the synthesis of a specific endoribonuclease which degrades f2 RNA and that the inhibition of f2 protein synthesis may be a consequence of this degradation, rather than a direct effect of T4 upon translation.     

Superinfection exclusion and changes in cellular transport processes in phage infected Salmonella typhimurium.

Summary The changes induced by bacteriophage P22 in the cellular transport process(es) of the host Salmonella typhimurium (Taneja et al., 1975; Khandekar et al., 1975; Bandyopadhyay and Chakravorty, 1976) involve interactions between the superinfection exclusion system of the resident prophage and the C immunity region of the superinfecting phage. The sieA gene of the prophage interferes with the changes in the cellular transport process induced by the superinfecting phage. However, if the superinfecting phage carries active C ₁ and C ₂ genes of the superinfecting phage seem to be expressed in the sie A⁺ lysogen.     

On the lack of host-cell reactivation of UV-irradiated phage T5 II. Further characterization of the repair inhibition exerted by T5 infection

Experiments reported in the preceding paper [4] had shown that host-cell reactivation (HCR) of UV-irradiated phage T1 in excision-repair proficient Escherichia coli cells is inhibited by superinfection with phage T5. Theoretical considerations have led to predictions concerning the dependence of repair inhibition on the multiplicity of superinfecting T5 phage and on the UV fluence to which they were exposed. These predictions have been supported by experimental results described in this paper. The fluence dependence permitted calculation of the relative UV sensitivity of the gene function responsible for repair inhibition; it was found to be about 2.3% that of the plaque-forming ability of phage T5.The T5-inhibitable step in excision repair occurs early in the infective cycle of T1. Furthermore, experiments involving the presence of 400 μg/ml chloramphenicol showed that HCR inhibition of T1 is caused by a protein produced after the FST segment of T5 (i.e. the first 8% of the T5 genome) has entered the host cell. A previously described minor T1 recovery process, occuring in both excision-repair-proficient and -deficient host cells, is inhibited by T5 infection due to a different substance, which is most likely associated with the “second-step-transfer” region of T5 DNA (involving the remainder of the genome). Superinfection with T4ν₁ phage resulted in HCR inhibition of T1, resembling that observed after T5 superinfection. The discussion of these results suggests that inhibition of the bacterial excision repair system by T5 or T4 infection occurs at the level of UV-endonucleolytic incision, and that lack of HCR both in T-even phages and in T5 can be explained in the same manner.     

Spackle and Immunity Functions of Bacteriophage T4

Cells of Escherichia coli B infected with the immunity-negative (imm2) mutant of bacteriophage T4 are able to develop a substantial level of immunity to superinfecting phage ghosts if the ghost challenge is made late in infection. This background immunity is not seen in infections with phage carrying the spackle (s) mutation in addition to the imm2 lesion. The level of immunity in s⁻ infections is intermediate between that of imm⁻ and wild-type infections under standard assay conditions. With respect to genetic exclusion of superinfecting phage, cells infected with imm⁻ phage are completely deficient, whereas infections with the s⁻ phage are only partially deficient compared to wild-type infections. Whereas s⁻-infected cells are unable to resist lysis from without by a high multiplicity of infection (MOI) of superinfecting phage, cells infected with imm⁻ phage show less than wild-type levels of resistance and the majority of cells remaining intact are unable to incorporate leucine or form infective centers. Under conditions of superinfection by low MOI of homologous phage, imm⁻-infected cells are lysis inhibited, whereas s⁻-infected cells do not show this property. Superinfecting phage inject their DNA into imm⁻-infected cells with the same efficiency as seen in wild-type infections, but this efficiency is reduced when the cells are first infected with s⁻ phage. The s function of T4 appears not only to affect the host cell wall as previously postulated by Emrich, but may also affect the junctures of cell wall and membrane with consequences similar to those of the imm function.     

Repair mechanisms involved in prophage reactivation and UV reactivation of UV-irradiated phage lambda

Survival of UV-irradiated phage λ is increased when the host is lysogenic for a homologous heteroimmune prophage such as λimm434 (prophage reactivation). Survival can also be increased by UV-irradiating slightly the non-lysogenic host (UV reactivation).Experiments on prophage reactivation were aimed at evaluating, in this recombination process, the respective roles of phage and bacterial genes as well as that of the extent of homology between phage and prophage.To test whether UV reactivation was dependent upon recombination between the UV-damaged phage and cellular DNAs, lysogenic host cells were employed. Such hosts had thus as much DNA homologous to the infecting phage as can be attained. Therefore, if recombination between phage and host DNAs was involved in this repair process, it could clearly be evidenced.By using unexposed or UV-exposed host cells of the same type, prophage reactivation and UV reactivation could be compared in the same genetic background.The following results were obtained: (1) Prophage reactivation is strongly decreased in a host carrying recA mutations but quite unaffected by mutation lex-I known to prevent UV reactivation; (2) In the absence of the recA⁺ function, the red⁺ but not the int⁺ function can substitute for recA⁺ to produce prophage reactivation, although less efficiently; (3) Prophage reactivation is dependent upon the number of prophages in the cell and upon their degree of homology to the infecting phage. The presence in a recA host of two prophages either in cis (on the chromosome) or in trans (on the chromosome and on an episome) increases the efficiency of prophage reactivation; (4) Upon prophage reactivation there is a high rate of recombination between phage and prophage but no phage mutagenesis; (5) The rate of recombination between phage and prophage decreases if the host has been UV-irradiated whereas the overall efficiency of repair is increased. Under these conditions UV reactivation of the phage occurs as in a non-lysogen, as attested by the high rate of mutagenesis of the restored phage.These results demonstrate that UV reactivation is certainty not dependent upon recombination between two pre-existing DNA duplexes. The hypothesis is offered that UV reactivation involves a repair mechanism different from excision and recombination repair processes.     

The steroid ligands of estrogen binding proteins in Xenopus laevis liver cytosol are primarily metabolites of 17β-estradiol

The interactions in vitro between [³H]estradiol and liver proteins from Xenopus laevis have been examined to determine if the binding reaction meets criteria of steroid-receptors which may function in the induction of vitellogenesis. Estrogenic hormones associated with proteins in serum and liver cytosol from Xenopus laevis. However, the interactions between soluble liver proteins and estrogens apparently do not result from serum contamination of liver as specific binding was distinguishable by ligand affinity and by differential mobility on polyacrylamide gels. Steroid ligands bound by liver proteins during incubation in vitro were examined by solubility and by thin-layer chromatography. Only a small percentage (13%) of the bound radioactive ligand was recovered as the original tritium-labeled steroid, 17β-estradiol. The major ligand was recovered as a water-soluble metabolite of estradiol which was identified tentatively as an estradiol-glucoside. To investigate whether the protein-bound estradiol metabolite(s) merely masks a small amount of authentic estradiol-receptor complexes or if the metabolite could be an intermediate in estrogen function, isolated liver nuclei were incubated with liver cytosol containing ³H-labeled steroid-protein complexes or with serum protein-bound [³H]estradiol. Nuclei preferentially accumulated ³H-labelea steroids from liver cytosol protein-steroid complexes relative to [³H]estradiol from serum proteins. However, analysis of the steroids recovered in the nuclei after incubation with liver cytosol revealed that both 17β-[³H]estradiol and the ³H-labeled water-soluble metabolite were retained in vitro by nuclei.