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.     

Phage-exclusion enzymes: a bonanza of biochemical and cell biology reagents?

Many parasitic DNA elements including prophages and plasmids synthesize proteins that kill the cell after infection by other phages, thereby blocking the multiplication of the infecting phages and their spread to other nearby cells. The only known function of these proteins is to exclude the infecting phage, and therefore to protect their hosts, and thereby the DNA elements themselves, against phage contagion. Many of these exclusions have been studied extensively and some have long been used in molecular genetics, but their molecular basis was unknown. The most famous of the phage exclusions are those caused by the Rex proteins of λ prophage. The Rex exclusions are still not completely understood, but recent evidence has begun to lead to more specific models for their action. One of the Rex proteins, RexA, may be activated by a DNA-protein complex, perhaps a recombination or replication intermediate, produced after phage infection. In the activated state, RexA may activate RexB, which has been proposed to be a membrane ion channel that allows the passage of monovalent cations, destroying the cellular membrane potential, and killing the cell. We now understand two other phage exclusions at the molecular level which use strategies that are remarkably similar to each other. The parasitic DNA elements responsible for the exclusions both constitutively synthesize enzymes that are inactive as synthesized by the DNA element but are activated after phage infection by a short peptide determinant encoded by the infecting phage. In the activated state, the enzymes cleave evolutionarily conserved components of the translation apparatus, in one case EF-Tu, and in the other case tRNA^Lys. Translation is blocked and development of the phage is arrested. A myriad of different phage-exclusion systems are known to exist and many of these may also be specific for highly conserved cellular components, furnishing generally useful enzymes for biochemical and biomedical research.     

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).     

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).     

Recombinant expression and characterization of a reducing-end xylose-releasing exo-oligoxylanase from Bifidobacterium adolescentis

The family 8 glycoside hydrolase (RexA) from Bifidobacterium adolescentis was expressed in Escherichia coli. The recombinant enzyme was characterized as a reducing-end xylose-releasing exo-oligoxylanase. Apart from giving insights into this new class of enzymes, knowledge of the RexA enzyme helps to postulate a mechanism for the B. adolescentis breakdown of prebiotic xylooligosaccharides.     

Yet another way that phage λ manipulates its Escherichia coli host: λrexB is involved in the lysogenic–lytic switch

The life cycle of phage λ has been studied extensively. Of particular interest has been the process leading to the decision of the phage to switch from lysogenic to lytic cycle. The principal participant in this process is the λcI repressor, which is cleaved under conditions of DNA damage. Cleaved λcI no longer acts as a repressor, allowing phage λ to switch from its lysogenic to lytic cycle. The well‐known mechanism responsible for λcI cleavage is the SOS response. We have recently reported that the Escherichia coli toxin‐antitoxin mazEF pathway inhibits the SOS response; in fact, the SOS response is permitted only in E. coli strains deficient in the expression of the mazEF pathway. Moreover, in strains lysogenic for prophage λ, the SOS response is enabled by the presence of λrexB. λRexB had previously been found to inhibit the degradation of the antitoxin MazE, thereby preventing the toxic action of MazF. Thus, phage λ rexB gene not only safeguards the prophage state by preventing death of its E. coli host but is also indirectly involved in the lysogenic–lytic switch.     

Lambda excision revisited: testing a model for synapsis of prophage ends

Excision of lambda prophage was reexamined to test a model for prophage end synapsis. The model proposes that, during in situ prophage replication, following induction, the diverging replication forks are held together. Consequently, prophage DNA is spooled through the replication machinery, drawing the prophage ends together and facilitating synapsis. The model predicts that excision will be slowed if in situ lambda replication is inhibited, and the predicted low rate of excision of a nonreplicating prophage was observed after thermoinduction. However, excision was rapid if additional Int protein was supplied or if the temperature was reduced after induction, showing that (i) Int is partially thermosensitive for excision at 42 degrees C and (ii) in situ replication is not required for rapid excision, a finding that is inconsistent with the model.     

Restriction and modification in B. subtilis: the role of homology between donor and recipient DNA in transformation and transfection

Non-modified DNAs from phages SPO2 and phi 105, and prophage DNAs extracted from lysogens carrying these phages, were used to transfect isogenic r+m+ B. subtilis recipients which were either non-lysogenic, or had been lysogenized with a homologous or a non-homologous phage. Restriction of transfecting phage and prophage DNA occurred in non-lysogenic recipients and in recipients lysogenic for a non-homologous phage. No effect of restriction was observed when phage or prophage DNA was used to transfect recipients carrying a homologous prophage. This is analogous to the absence of restriction in transformation and indicates that in B. subtilis the distinction between transforming and transforming and transfecting DNA is not made at the initial stages of DNA uptake and processing, but rather at later stages, where recognition of homologous regions in donor and recipient DNA plays an important role.     

Ant-mediated inactivation of Salmonella phage L-specified repression at OR of prophage L.

Summary Ant product of phage P22 inactivates repression of prophage L at the right-hand operator o_R and allows for transactivation of prophage gene 12. The transactivation efficiency observed with a series of phage and prophage recombinants, using single superinfection of a lysogenic bacterium, is about the same as that recently observed at o_L of prophage L. This finding is in contrast to the failure to demonstrate derepression at o_R of prophage L in an experimental system employing double superinfection (Prell, 1978a). The reasons for the differing results are discussed and it is shown that derepression by the ant product in trans at o_R of the prophage is not modified to any significant degree by the immunity specificity (L or P22) of the prophage or of the superinfecting phage.     

High-frequency elimination of SP02 prophage from Bacillus subtilis by plasmid transformation

Transformation of competent Bacillus subtilis lysogenic for SP02 with any of three plasmids (pCM194, pUB110, pAM77) generates drug-resistant transformants of which 5 to 20% have lost the infectivity and immunity associated with the SP02 prophage. Such cured derivatives can be again lysogenized with SP02 and again cured by introduction of a different plasmid. Elimination of the SP02 prophage was not detected when plasmids were introduced by PBS1 transduction or by transformation of protoplasts. Similarly, transformants of B. subtilis selected for chromosome markers retained the prophage. The phi 105 prophage was not eliminated from competent B. subtilis transformed with plasmids.     

Effect of the Prophage and Penicillinase Plasmid of the Recipient Strain Upon the Transduction and the Stability of Methicillin Resistance in Staphylococcus aureus

Transduction of a methicillin-resistance determinant (mec) in Staphylococcus aureus RN450 was dependent on its prior lysogenization with an appropriate temperate phage. In addition, an appropriate transduced penicillinase plasmid was usually required. Some phage 80-resistant variants of RN450 or of its parental lysogenic strain, NCTC 8325, were also effective recipients for transduction of mec. Elimination of prophage from RN450 abrogated its effectiveness as a transductional recipient of mec. Elimination of prophage from a methicillin-resistant transductant of RN450 reduced resistance to undetectable levels in six of seven phage-eliminated strains. In four of these a variable number of clones again became phenotypically resistant after lysogenization alone or lysogenization combined with reintroduction of a penicillinase plasmid. In two prophage-eliminated strains, no evidence of residual mec could be adduced. The establishment, expression, or stability of the transduced mec in strain RN450 appeared to depend on some function determined by a prophage or a prophage and a penicillinase plasmid.     

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.     

Mechanism of Haemophilus influenzae transfection by single and double prophage deoxyribonucleic acid.

Whole phages HP1 and HP3, vegetative-phage deoxyribonucleic acid (DNA), and single and tandem double prophage DNA were exposed to ultraviolet radiation and then assayed on a wild-type (DNA repair-proficient) Haemophilus influenzae Rd strain and on a repair-deficient uvr-1 strain. Host cell reactivation (DNA repair) was observed for whole-phage and vegetative-phage DNA but not for single and double prophage DNA. Competent (phage-resistant) Haemophilus parainfluenzae cells were normally transfected with H. influenzae-grown phage DNA and with tandem double prophage DNA but not at all with single prophage DNA. CaCl2-treated H. influenzae suspensions could be transfected with vegetative phage DNA and with double prophage DNA but not with single prophage DNA. These observations support the hypothesis that transfection with single prophage DNA occurs through prophage DNA single-strand insertion into the recipient chromosome (at the bacterial att site) followed by DNA replication and then prophage induction.     

Inheritance of nocardiophage phi EC in matings of nocardial lysogens.

Lysogens of Nocardia erythropolis were mated with nonlysogenic strains to study the inheritance of the phi EC prophage. Crosses between lysogenic strains of the Mat-Ce mating type and nonlysogenic Mat-cE strains produced Mat-cE lysogens at a recovery rate of 17%, whereas recombination frequencies between chromosomal traits were about 2.3 x 10(-5). Crosses of lysogenic Mat-cE mating types with nonlysogenic Mat-Ce produced Mat-Ce lysogens at a recovery rate of 19%, whereas recombinants for chromosomal traits were recovered at only 1.8 x 10(-5). Crosses of homologous mating types, lysogenic Mat-Ce with nonlysogenic Mat-Ce or lysogenic Mat-cE with nonlysogenic Mat-cE, failed to transfer the prophage. It was concluded that the phi EC prophage exists as a plasmid and can be transferred at high frequencies with patterns of transfer controlled like typical nocardial fertility. Evidence that the prophage may also exist as an integrated element was observed from recombination analyses.     

Isolation and characterization of nondefective transducing lambda bacteriophages carrying fla genes of Escherichia coli K-12.

In Escherichia coli K-12, 11 fla genes and a hag gene are located between his and uvrC, making two clusters at map positions 42.5 and 43.0 min. Nondefective transducing lambda phages for these genes were isolated. Low-frequency-transducing donors were constructed starting from lysogens of lambda cI857 in which the prophage is integrated at a secondary attachment site at 44 min on the E. coli map. Two strategies were used to delete the region between the prophage and the fla genes. Deletion mutants of the supD locus between fla and the prophage were isolated by selecting for loss of Su1+, an allele of supD. A strain with a deletion starting within the prophage and ending at a position close to the fla genes was isolated from heat-resistant derivatives of the lysogen. A lysogen of lambda b2 was then constructed in which the prophage had integrated at the site of the defective prophage by means of recombination with residual lambda deoxyribonucleic acid. From low-frequency-transducing lysate of the donor strains thus constructed, either directly or in combination with a procedure that extends the loci transduced, various lambda pfla's were isolated. lambda pflaL1 carries all nine fla genes at 43 min, and lambda pflaH14 carries hag and two fla genes at 42.5 min.     

Genome-Based Identification of Active Prophage Regions by Next Generation Sequencing in Bacillus licheniformis DSM13

Prophages are viruses, which have integrated their genomes into the genome of a bacterial host. The status of the prophage genome can vary from fully intact with the potential to form infective particles to a remnant state where only a few phage genes persist. Prophages have impact on the properties of their host and are therefore of great interest for genomic research and strain design. Here we present a genome- and next generation sequencing (NGS)-based approach for identification and activity evaluation of prophage regions. Seven prophage or prophage-like regions were identified in the genome of Bacillus licheniformis DSM13. Six of these regions show similarity to members of the Siphoviridae phage family. The remaining region encodes the B. licheniformis orthologue of the PBSX prophage from Bacillus subtilis. Analysis of isolated phage particles (induced by mitomycin C) from the wild-type strain and prophage deletion mutant strains revealed activity of the prophage regions BLi_Pp2 (PBSX-like), BLi_Pp3 and BLi_Pp6. In contrast to BLi_Pp2 and BLi_Pp3, neither phage DNA nor phage particles of BLi_Pp6 could be visualized. However, the ability of prophage BLi_Pp6 to generate particles could be confirmed by sequencing of particle-protected DNA mapping to prophage locus BLi_Pp6. The introduced NGS-based approach allows the investigation of prophage regions and their ability to form particles. Our results show that this approach increases the sensitivity of prophage activity analysis and can complement more conventional approaches such as transmission electron microscopy (TEM).     

Prophage induction by DNA topoisomerase II poisons and reactive-oxygen species: role of DNA breaks.

Various compounds were evaluated for their ability to induce prophage lambda in the Escherichia coli WP2s(lambda) microscreen assay. The inability of a DNA gyrase subunit B inhibitor (novobiocin) to induce prophage indicated that inhibition of the gyrase's ATPase was insufficient to elicit the SOS response. In contrast, poisons of DNA gyrase subunit A (nalidixic acid and oxolinic acid) were the most potent inducers of prophage among the agents examined here. This suggested that inhibition of the ligation function of subunit A, which also has a DNA nicking activity, likely resulted in DNA breaks that were available (as single-stranded DNA) to act as strong SOS-inducing signals, leading to prophage induction. Agents that both intercalated and produced reactive-oxygen species (the mammalian DNA topoisomerase II poisons, adriamycin, ellipticine, and m-AMSA) were the next most potent inducers of prophage. Agents that produced reactive-oxygen species only (hydrogen peroxide and paraquat) were less potent than adriamycin and ellipticine but more potent than m-AMSA. Agents that intercalated but did not generate reactive-oxygen species (actinomycin D) or that did neither (teniposide) were unable to induce prophage, suggesting that intercalation alone may be insufficient to induce prophage. These results illustrate the variety of mechanisms (and the relative effectiveness of these mechanisms) by which agents can induce prophage. Nonetheless, these agents may induce prophage by producing essentially the same type of DNA damage, i.e., DNA strand breaks. The potent genotoxicity of the DNA gyrase subunit A poisons illustrates the genotoxic consequences of perturbing an important DNA-protein complex such as that formed by DNA and DNA topoisomerase.     

Prophage type of recombinants produced by cell fusion between various combinations of lysogenic or non-lysogenic substrains from two Staphylococcus aureus L-forms

Streptomycin (SM)- or erythromycin (EM)-resistant lysogenic and non-lysogenic substrains were produced from two Staphylococcus aureus L-form strains lysogenic for different prophages, namely, EMT-L (prophage alpha) and 209P (prophage beta). Cells of these L-form substrains were fused in various combinations using polyethylene glycol (PEG), and the frequency of recombinants selected as double resistance to both SM and EM and the prophage types of these recombinants were examined. In all the combinations, the frequency of recombinants was greater when the cells were treated with PEG than when they were not, and the difference was statistically significant (p less than 0.01) in 13 combinations. Combination between the lysogenic SM-resistant EMT-L substrain [EMT(Smr-alpha)] and lysogenic EM-resistant 209P-L substrain [209P(Emr-beta)] and the reverse combination, between 209P(Smr-beta) and EMT(Emr-alpha), resulted in a majority of recombinants harboring prophage beta. The former combination yielded recombinants that all held both prophage alpha and beta.