Bacteriophage mv4 Site-Specific Recombination: the Central Role of the P2 mv4Int-Binding Site

The contributions of the five ^mv4Int- and two ^mv4Xis arm-binding sites to the spatial intasome organization of bacteriophage mv4 were found not to be equivalent. The 8-bp overlap region was mapped to the left extremity of the core region and is directly flanked by the P2 Int arm-binding site. These results and the absence of characteristic Int core-binding sites suggest that the P2 site is the determinant for integrase positioning and recognition of the core region.     

Site-Specific Recombination of Bacteriophage P22 Does Not Require Integration Host Factor

Site-specific recombination by phages lambda and P22 is carried out by multiprotein-DNA complexes. Integration host factor (IHF) facilitates lambda site-specific recombination by inducing DNA bends necessary to form an active recombinogenic complex. Mutants lacking IHF are over 1,000-fold less proficient in supporting lambda site-specific recombination than wild-type cells. Although the attP region of P22 contains strong IHF binding sites, in vivo measurements of integration and excision frequencies showed that infecting P22 phages can perform site-specific recombination to its maximum efficiency in the absence of IHF. In addition, a plasmid integration assay showed that integrative recombination occurs equally well in wild-type and ihfA mutant cells. P22 integrative recombination is also efficient in Escherichia coli in the absence of functional IHF. These results suggest that nucleoprotein structures proficient for recombination can form in the absence of IHF or that another factor(s) can substitute for IHF in the formation of complexes.     

Some Properties of Site-Specific and General Recombination Inferred from Int-Initiated Exchanges by Bacteriophage Lambda

The site-specific recombination at the attachment site for prophage integration might proceed by two general mechanisms: (1) a concerted reaction without a free intermediate; (2) a sequential mechanism differing from typical general recombination only by an inability of the cross-strand intermediate structure to migrate into the region of nonhomology adjacent to the attachment site. The blocked-migration model predicts frequent genetic exchange in the int xis region near the attachment site if Int-mediated recombination occurs between lambda phage with homologous attachment sites. We find such additional int xis exchanges, but only at very low frequency (1% of the Int-mediated recombination). We conclude that the resolution point only rarely moves away from the initial crossover point specified by Int and, therefore, that the Int reaction is mainly concerted. We interpret the rare additional int xis recombinants as indicative of occasional branch migration from an initial Int-mediated crossover. The frequency of the rare int xis recombinants is not simply related to distance from the attachment site to an int- or xis- mutation, suggesting that the heteroduplex distance is often at least a gene in length. The frequency of these additional exchanges is also not a strong function of distance between two mutations; from this we conclude that the resolution to the observed recombinant structure in the sequential cases occurs often by mismatch repair. We have found no marked effect of mutations in the bacterial recA, recB, recC, recF, or recL genes on the frequency of the int xis recombinants; this may indicate that none of these genes specifies a product uniquely required for resolution of a cross-strand intermediate.     

Control of Helicase Loading in the Coupled DNA Replication and Recombination Systems of Bacteriophage T4

The Gp59 protein of bacteriophage T4 promotes DNA replication by loading the replicative helicase, Gp41, onto replication forks and recombination intermediates. Gp59 also blocks DNA synthesis by Gp43 polymerase until Gp41 is loaded, ensuring that synthesis is tightly coupled to unwinding. The distinct polymerase blocking and helicase loading activities of Gp59 likely involve different binding interactions with DNA and protein partners. Here, we investigate how interactions of Gp59 with DNA and Gp32, the T4 single-stranded DNA (ssDNA)-binding protein, are related to these activities. A previously characterized mutant, Gp59-I87A, exhibits markedly reduced affinity for ssDNA and pseudo-fork DNA substrates. We demonstrate that on Gp32-covered ssDNA, the DNA binding defect of Gp59-I87A is not detrimental to helicase loading and translocation. In contrast, on pseudo-fork DNA the I87A mutation is detrimental to helicase loading and unwinding in the presence or absence of Gp32. Other results indicate that Gp32 binding to lagging strand ssDNA relieves the blockage of Gp43 polymerase activity by Gp59, whereas the inhibition of Gp43 exonuclease activity is maintained. Our findings suggest that Gp59-Gp32 and Gp59-DNA interactions perform separate but complementary roles in T4 DNA metabolism; Gp59-Gp32 interactions are needed to load Gp41 onto D-loops, and other nucleoprotein structures containing clusters of Gp32. Gp59-DNA interactions are needed to load Gp41 onto nascent or collapsed replication forks lacking clusters of Gp32 and to coordinate bidirectional replication from T4 origins. The dual functionalities of Gp59 allow it to promote the initiation or re-start of DNA replication from a wide variety of recombination and replication intermediates.     

Involvement of Gene 49 in Recombination of Bacteriophage T4

The role of T4 gene 49 in recombination was investigated using its conditional-lethal amber (am) and temperature-sensitive (ts) mutants. When measured in genetic tests, defects in gene 49 produced a recombination-deficient phenotype. However, DNA synthesized in cells infected with a ts mutant (tsC9) at a nonpermissive temperature appeared to be in a recombinogenic state: after restitution of gene function by shifting to a permissive temperature, the recombinant frequency among progeny increased rapidly even when DNA replication was blocked by an inhibitor. Growth of a gene 49-defective mutant was suppressed by an additional mutation in gene uvsX, but recombination between rII markers was not.     

Control of Early Gene Expression of Bacteriophage T4: Involvement of the Host rho Factor and the mot Gene of the Bacteriophage

Many early mRNA species of bacteriophage T4 are not synthesized after infection of Escherichia coli in the presence of chloramphenicol. This has been interpreted as a need for T4 protein(s) to be synthesized to allow expression of some early genes, e.g., those for deoxycytidinetriphosphatase, deoxynucleosidemonophosphate kinase and UDP-glucose-DNA beta-glucosyltransferase. In the experiments described here, early mRNA of bacteriophage T4 was allowed to accumulate during chloramphenicol treatment. After the addition of rifampin to inhibit further RNA synthesis, and subsequent removal of chloramphenicol, the accumulated mRNA was permitted to express itself into measured enzyme activities. It was shown that the early mRNA species coding for deoxycytidinetriphosphatase and UDP-glucose-DNA beta-glucosyltransferase could be formed in the presence of chloramphenicol if the E. coli host cell carried a mutation in the structural gene for the RNA chain termination factor rho. This was interpreted to mean that T4 protein(s) with anti-rho activity is normally required for the expression of these two early genes. An altered rho-factor could not, however, relieve the need of phage protein synthesis for the formation of another early mRNA, that coding for deoxynucleosidemonophosphate kinase. In this case the mot gene of T4 seemed to be involved, since the primary infection of E. coli cells with the mot gene mutant tsG1 did not allow subsequent deoxynucleoside monophosphate kinase mRNA synthesis after wild-type phage infection in the presence of chloramphenicol. In control experiments, deoxynucleoside monophosphate kinase mRNA synthesis induced by wild-type phage superinfecting in the presence of chloramphenicol was facilitated by the primary infection with T4 phage containing an unmutated mot gene.     

Replication and Recombination in Ligase-Deficient rII Bacteriophage T4D

Deoxyribonucleic acid replication and genetic recombination were investigated after infection of Escherichia coli with ligase-deficient rII bacteriophage T4D. The major observations are: (i) deoxyribonucleic acid synthesis is discontinuous, (ii) the discontinuities are more slowly repaired than in wild-type infection, (iii) host ligase is required for viability, and (iv) genetic recombination is increased.     

CTnDOT Integrase Interactions with Attachment Site DNA and Control of Directionality of the Recombination Reaction

IntDOT is a tyrosine recombinase encoded by the conjugative transposon CTnDOT. The core binding (CB) and catalytic (CAT) domains of IntDOT interact with core-type sites adjacent to the regions of strand exchange, while the N-terminal arm binding (N) domain interacts with arm-type sites distal to the core. Previous footprinting experiments identified five arm-type sites, but how the arm-type sites participate in the integration and excision of CTnDOT was not known. In vitro integration assays with substrates containing arm-type site mutants demonstrated that attDOT sequences containing mutations in the L1 arm-type site or in the R1 and R2 or R1 and R2′ arm-type sites were dramatically defective in integration. Substrates containing mutations in the L1 and R1 arm-type sites showed a 10- to 20-fold decrease in detectable in vitro excision, but introduction of multiple arm-type site mutations in attR did not have an effect on the excision frequency. A sixth arm-type site, the R1′ site, was also identified and shown to be required for integration and important for efficient excision. These results suggest that intramolecular IntDOT interactions are required for integration, while the actions of accessory factors are more important for excision. Gel shift assays performed in the presence of core- and arm-type site DNAs showed that IntDOT affinity for the attDOT core was enhanced when IntDOT was simultaneously bound to arm-type site DNA.Conjugative transposons (CTns), also known as integrative and conjugative elements (ICEs), are mobile genetic elements that are widespread in Bacteroides spp. and are implicated in the spread of antibiotic resistance. These elements are normally integrated into the host chromosome but can excise, replicate, and transfer to a recipient cell by conjugation (34). Since CTns commonly carry antibiotic resistance genes, it is likely that the increase in antibiotic-resistant Bacteroides strains has been mediated through the lateral transfer of these elements (36). One of the best-studied ICEs in Bacteroides is the conjugative transposon CTnDOT. CTnDOT is 65 kb in size and carries genes encoding resistance to tetracycline and erythromycin. Over the past 30 years, the incidence of tetracycline resistance has increased to 80% of Bacteroides isolates due to the presence of CTnDOT-type elements (36).Integration and excision of CTnDOT results from site-specific recombination between regions of DNA known as attachment (att) sites. During integration, the joined ends of the closed circular intermediate (attDOT) recombine with the bacterial target sequence (attB) to form the recombinant sites (attL and attR). The integration reaction requires IntDOT, a CTnDOT-encoded protein that has been identified as a member of the tyrosine recombinase family, as well as a host factor encoded by Bacteroides (8, 21). Site-specific recombination between the attL and attR attachment sites results in excision of CTnDOT from the host chromosome. IntDOT is also required for excision, as are three element-encoded proteins: Orf2c, Orf2d, and Exc, as well a Bacteroides host factor (8, 38). The roles of these accessory proteins are not well understood, although Orf2c and Orf2d have been shown to bind DNA (unpublished results).One of the best-studied tyrosine recombinases is the integrase (Int) of the lambda system. The C terminus of Int includes the core binding (CB) and catalytic (CAT) domains that bind to core-type sites, which flank the sites of cleavage and strand exchange (2, 24). The N-terminal arm-binding (N) domain binds to arm-type sites that are distal to the core-type sites. In the presence of the appropriate host and accessory factors, Int binding to arm-type sites is required for the formation of higher-order protein/DNA complexes known as intasomes, which are required for integration and excision (15, 18, 22). Int is capable of making intramolecular interactions (interactions between Int monomers on the same attachment site) and intermolecular interactions (interactions between Int monomers on different attachment sites) during recombination (15, 16). In the lambda system, the directionality of the reaction is regulated by Int interactions with arm-type sites in conjunction with the integration host factor (IHF) during the formation of an integrative intasome, or IHF, Xis, and FIS during the formation of the two excisive intasomes (1, 4, 42).Presumably, IntDOT occupancy of specific arm-type sites in conjunction with interactions of accessory factors with att sites leads to the assembly of integrative or excisive intasomes and thus contributes to the directionality of IntDOT-mediated recombination. Previous DNase I footprinting experiments identified five arm-type binding sites on attDOT (11). In this study, mutations were constructed in the five sites to determine their roles in the integration and excision of CTnDOT. In addition, a sixth arm-type site was discovered that is important for both integrative and excisive recombination. The results of gel shift assays also show that the interaction of IntDOT with core-type sites and arm-type sites involves cooperative interactions.     

Region-Specific Recombination in Phage T4. III. the Effect of Host Mutations on Glucosylation-Dependent Recombination in Bacteriophage T4d

Mutations in the Escherichia coli genes recK, recL and (probably) uvrE and polA increase special (glucosylation-dependent), but not general recombination in bactriophage T4D.     

A Genetic Analysis of Primary Products of Bacteriophage Lambda Recombination

Primary products of bacteriophage lambda recombination that display heterozygosity as a consequence of the presence of regions of heteroduplex DNA are rare in standard lambda crosses. Phage manifesting heterozygosity at a given allele are evident when recombinants, emerging from a cross, are selected for an exchange in a neighboring interval. We show that the abundance of such heterozygotes can be increased 10- to 20-fold by selection on an E. coli indicator that is defective in methyl-directed mismatch repair (mutL). Thus, the activity of the methyl-directed mismatch repair system is, at least in part, responsible for the low frequency of detectably heterozygous phage emerging from a standard cross. In a mutL indicator, many primary products of recombination are replicated without the intervention of mismatch repair.--The products of a six-factor phage cross have been plated on a mutL indicator allowing visual detection of those phage products heterozygous for one of the allelic pairs, cI. By genetic analysis, we show that the heteroduplex regions of these primary products of recombination are on the average about 4 kb in length and can include as much as half of the lambda genome.     

Involvement of a Replicative DNA Helicase of Bacteriophage T4 in DNA Recombination

Bacteriophage T4 gene 41 encodes a replicative DNA helicase that is a subunit of the primosome which is essential for lagging-strand DNA synthesis. A mutation, rrh, was generated and selected in the helicase gene on the basis of limited DNA replication that ceases early. The survival of ultraviolet-irradiated phage and the frequency of genetic recombination are reduced by rrh. In addition, rrh diminishes the production of concatemeric DNA. These results strongly suggest that the gene 41 replicative helicase participates in DNA recombination.     

The Evolution of Epistasis and the Advantage of Recombination in Populations of Bacteriophage T4

Experiments reported here test two hypotheses about the evolution of recombination: first, the Fisher-Muller concept that sexual organisms respond to selection more rapidly than do asexual ones, and second, that epistasis is more likely to evolve in the absence of recombination. Populations of bacteriophage T4 were selected by the drug proflavine in discrete generations and the change in mean population fitness was monitored. Three separate selection series yielded results supporting the Fisher-Muller hypothesis. The amount of epistasis evolved was measured by partitioning the T4 map into regions and comparing the sum of the proflavine resistances of each region with the resistance of the whole. Significantly more interactions were found in phage isolated from the populations with lower total recombination than in those from populations with higher recombination. The degree to which these experiments fit preconceived notions about natural selection suggests that microorganisms may be advantageously used in other population genetics experiments.     

Replication and Recombination of Gene 59 Mutant of Bacteriophage T4D

After infection of Escherichia coli B with phage T4D carrying an amber mutation in gene 59, recombination between two rII markers is reduced two- to three-fold. This level of recombination deficiency persists even when burst size similar to wild type is induced by the suppression of the mutant DNA-arrest phenotype. In the background of two other DNA-arrest mutants in genes 46 and 47, a 10- to 11-fold reduction in recombination is observed. The cumulative effect of gene 59 mutation on gene 46-47 mutant suggests that complicated interactions must occur in the production of genetic recombinants. The DNA-arrest phenotype of gene 59 mutant can be suppressed by inhibiting the synthesis of late phage proteins. Under these conditions, DNA replicative intermediates similar to those associated with wild-type infection are induced. Synthesis of late phage proteins, however, results in the degradation of mutant 200S replicative intermediate into 63S DNA molecules even in the absence of capsid assembly. Although these 63S molecules are associated with membrane, they do not replicate. These results suggest a role for gene 59 product, in addition to a possible requirement of concatemeric DNA in late replication of phage T4 DNA.     

Genetic Recombination in Bacteriophage T4: Single-Burst Analysis of Cosegregants and Evidence in Favor of a Splice/Patch Coupling Model

To reveal the structure of penultimate DNA intermediates in T4 bacteriophage recombination, resolution of which produces free recombinant molecules, a single-burst analysis of the recombinant progeny was made in multifactor crosses, enabling one to determine quantitatively the different recombinants generated by one or two exchanges within the same chromosome segment. It was found that double and single exchanges are highly correlated in T4 recombination. These results were interpreted as evidence for simultaneous formation of a splice/patch pair as the primary recombination products. A recombination model called here the "splice/patch coupling model" is presented according to which resolution of a single DNA intermediate results in two linear heterozygous molecules containing a patch and a splice, respectively, in homologous positions.     

Marker-Dependent Recombination in T4 Bacteriophage. III. Structural Prerequisites for Marker Discrimination

Distance- as well as marker-dependence of genetic recombination of bacteriophage T4 was studied in crosses between rIIB mutants with known base sequences. The notion of a "basic recombination," which is the recombination within distances shorter than hybrid DNA length in the absence of mismatch repair and any marker effects, was substantiated. The basic recombination frequency per base pair can serve as an objective parameter (natural constant) of general recombination reflecting its intensity. Comparative studies of the recombination properties of rIIB mutants with various sequence changes in the mutated sites showed that the main factor determining the probability of mismatch repair in recombination heteroduplexes is the length of a continuous heterologous region. A run of A:T pairs immediately adjoining the mismatch appears to stimulate its repair. In the case of mismatches with DNA strands of unequal length, formed by frameshift mutations, the repair is asymmetric, the longer strand (bulge) being preferentially removed. A pathway for mismatch repair including sequential action of endonuclease VII (gp49)----3'----5' exonuclease (gp43)----DNA polymerase (gp43)----DNA ligase (gp30) was proposed. A possible identity of the recombinational mismatch repair mechanism to that operating to produce mutations via sequence conversion is discussed.     

Marker-Dependent Recombination in T4 Bacteriophage. IV. Recombinational Effects of Antimutator T4 DNA Polymerase

Recombinational effects of the antimutator allele tsL42 of gene 43 of phage T4, encoding DNA polymerase, were studied in crosses between rIIB mutants. Recombination under tsL42-restricted conditions differed from the normal one in several respects: (1) basic recombination was enhanced, especially within very short distances; (2) mismatch repair tracts were shortened, while the contribution of mismatch repair to recombination was not changed; (3) marker interference at very short distances was augmented. We infer that the T4 DNA polymerase is directly involved in mismatch repair, performing both excision of a nonmatched single strand (by its 3' -> 5' exonuclease) and filling the resulting gap. A pathway for the mismatch repair was substantiated; it includes sequential action of endo VII (gp49) -> 3'->5' exonuclease (gp43) -> DNA polymerase (gp43) -> DNA ligase (gp30). It is argued that the marker interference at very short distances may result from the same sequence of events during the final processing of recombinational intermediates.     

Functional Analysis of the Bacteriophage T4 Rad50 Homolog (gp46) Coiled-coil Domain

Rad50 and Mre11 form a complex involved in the detection and processing of DNA double strand breaks. Rad50 contains an anti-parallel coiled-coil with two absolutely conserved cysteine residues at its apex. These cysteine residues serve as a dimerization domain and bind a Zn²⁺ cation in a tetrathiolate coordination complex known as the zinc-hook. Mutation of the zinc-hook in bacteriophage T4 is lethal, indicating the ability to bind Zn²⁺ is critical for the functioning of the MR complex. In vitro, we found that complex formation between Rad50 and a peptide corresponding to the C-terminal domain of Mre11 enhances the ATPase activity of Rad50, supporting the hypothesis that the coiled-coil is a major conduit for communication between Mre11 and Rad50. We constructed mutations to perturb this domain in the bacteriophage T4 Rad50 homolog. Deletion of the Rad50 coiled-coil and zinc-hook eliminates Mre11 binding and ATPase activation but does not affect its basal activity. Mutation of the zinc-hook or disruption of the coiled-coil does not affect Mre11 or DNA binding, but their activation of Rad50 ATPase activity is abolished. Although these mutants excise a single nucleotide at a normal rate, they lack processivity and have reduced repetitive exonuclease rates. Restricting the mobility of the coiled-coil eliminates ATPase activation and repetitive exonuclease activity, but the ability to support single nucleotide excision is retained. These results suggest that the coiled-coiled domain adopts at least two conformations throughout the ATPase/nuclease cycle, with one conformation supporting enhanced ATPase activity and processivity and the other supporting nucleotide excision.     

Integration of hup Genes into the Genome of Chickpea-Rhizobium Through Site-Specific Recombination

The hup gene fragment of cosmid pHU52 was integrated into the genome of chickpea-Rhizobium Rcd301 via site-specific homologous recombination. Two small fragments of genomic DNA of strain Rcd301 itself were provided to flank cloned hup genes to facilitate the integration. The hup insert DNA of cosmid pHU52 was Isolated as an Intact 30.2 kb fragment using EcoRI, and cloned on partially restricted cosmid clone pSPSm3, which carries a DNA fragment of strain Rcd301 imparting streptomycin resistance. One of the recombinant cosmid clones, pBSL 12 thus obtained was conjugally transferred to the strain Rcd30₁. The integration of hup gene fragment into the genomic DNA through site-specific homologous recombination, was ensured by introducing an incompatible plasmid, pPH1 JI. The integration was confirmed by Southern hybridization. The integrated hup genes were found to express ex plants in two such constructs BSL 12–1 and BSL 12–3.