traY and traI are required for oriT-dependent enhanced recombination between lac-containing plasmids and lambda plac5.

Recombination between F42lac and lambda plac5 is typically 20- to 50-fold more efficient than recombination between chromosomal lac and lambda plac5. This enhancement of recombination requires trans-acting factors located in the promoter-distal and promoter-proximal regions of the main traY-to-traI (traZ) operon. By testing the ability of deletion mutants of tra to support enhanced recombination, we have identified traY as the only product has been ruled out. We also report that traI is the only gene from the promoter-distal end of the traY to traI operon that is required for recombination enhancement. Of the two proposed domains of traI, we conclude that the oriT-nicking activity is essential, whereas the helicase activity is largely dispensable. The possibility of a third traI activity is also discussed.     

Structure of a recombination site in the transducing bacteriophage lambda plac5 DNA

A recombination site in the transducing bacteriophage lambda plac5 DNA has been structurally elucidated. Comparison of primary structures of E. coli lac-operon (distal end of lacZ gene, Z-Y spacer, and proximal end of lacY gene) described earlier with corresponding segments of bacteriophages lambda CI857 and lambda plac 5-2 DNAs sequenced in this paper showed that the bacterial DNA insert ends immediately after Z-Y spacer, just before the initiating triplet ATG of lacY gene. It thus follows that in contrast to the earlier conception, the insert does not seem to include any part of lacY gene. The recombination sites in both phage and bacterial DNA contain structurally homological segments about 20 b. p. long (crossover region), with two extra basepairs in the bacterial DNA (AT in the sense-strand). We suppose that the very dinucleotide plays a substantial role in initiation of recombinational event: causing formation of a nonperfect heteroduplex structure, it determines the T-A internucleotide bond to be endonucleolytically cut (crossover point) followed by exonucleolytic elimination of the extra links (AT) and reciprocal strand exchange. The second recombination site in lambda plac5 DNA has been localized by us within lacI gene as being close to the HindII site (nucleotides 854 to 859 of the gene). The structures of the two regions of site-specific recombination may shed light upon mechanisms of the phage abnormal excision leading to formation of transducing phages.     

Specialized transduction with lambda plac5: dependence on recB.

Genetically disabled lambda plac5 transducing phage derivatives were used to study the recB dependence of recombination during specialized transduction. The frequency of transduction was normalized to colony-forming units, and the end product of recombination was monitored by scoring for addition and substitution transductants. When a chromosomal lac gene was the recipient DNA substrate molecule, both the normalized transduction frequency and the proportion of addition and substitution transductants showed essentially no recB dependence. There was a pronounced recB dependence for both normalized transduction frequency and recombination end product formation when F42 lac was the recipient DNA substrate. recB appears to have no significant role in the recombination that occurs between the two lac regions in an addition transductant. UV irradiation of the transducing phages increased the absolute level of both addition and substitution transductants obtained with a chromosomal lac gene but resulted in a considerable change in the relative frequency of addition versus substitution transductants.     

Specialized transduction with lambda plac5: dependence on recA and on configuration of lac and att lambda.

The construction of lambda plac5 transducing phages carrying various lacZ alleles is described. Genetically disabled (N- N- P-) lambda plac transducing the phages were used to study the dependence of specialized transduction on host RecA function and on the location of the lacZ gene in the recipient strain. In the absence of site-specific recombination at att lambda, transduction was completely dependent on host RecA function. Regardless of the configuration of att lambda, lambda plac transducing phages recombined at a 20- to 50-fold higher frequency with F42 lac than with a lac gene located in the cellular chromosome. Deletion mutants of lacZ in the recipient strain were used to show that the probability of lac recombination resulting from lambda plac infection is apparently proportional to the amount of homology between the parental lacZ genes.     

Structure of the recombination zone during abnormal excision of the transducing bacteriophage lambda plac9

Investigating molecular mechanism of illegitimate recombinations in prokaryote we study transducing bacteriophages of the lambda lac series. We have carried out physical mapping of bacteriophage lambda plac9 DNA and, by comparing the obtained results with the data on the structure of lambda DNA and lac operon of E. coli, located the phage-bacterial junction corresponding to the lambda-lac9 abnormal excision and elucidated the nucleotide sequence around the junction. It led to the primary structure of phage and bacterial segments in the lysogenic bacterium which took part in the recombinational act leading to the abnormal excision and lambda lac9 formation. Structural homology of the partners in the lambda plac9 excision proved to be lower than in case of the earlier studied lambda plac5 and lambda plac10 whose excision proceeded regioselectively. Various aspects of the crossover area, including the crossover point's probable position and enzymic systems participating in the abnormal excision, are discussed.     

The separation of phage promoter from bacterial lac promoter for beta-galactosidase expression in transducing phage lambda plac5.

The replication defective transducing phage λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 carries a portion of the $\text{E.}\text{coli}\text{lac}$ operon in the $\text{b}$2 region of the lambda phage. This $\text{lac}$ operon segment contains the $\text{lac}$ promoter, the $\text{lac}$ operator, and the β-galactosidase $\text{z}$ gene, but does not contain the $\text{lac}$ repressor $\text{i}$ gene. The $\text{z}$ gene can be expressed from both the inserted $\text{lac}$ promoter and the phage promoter. When $\text{E.}\text{coli}$ strain 594 ($\text{z}$^?, $\text{i}$⁺) or JC6256 (Δ$\text{lac}$) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the absence of additional cyclic AMP, β-galactosidase synthesis is shown to be expressed from the phage promoter. When 594 (λ⁺) or JC6256 (λ⁺) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the presence of additional cyclic AMP and IPTG, β-galactosidase synthesis is shown to be expressed from the inserted $\text{lac}$ promoter.The ability to separate the phage promoter from the inserted $\text{lac}$ promoter for β-galactosidase expression will simplify the interpretation whenever λp$\text{lac}$5 is used.     

Structural bases of a long-stretched deletion: completing the lambda plac5 DNA primary structure.

In studying molecular mechanisms of specialised transduction, the lacI (E. coli)-Ea47 (lambda) DNA junction in transducing bacteriophage lambda plac 5 has been structurally elucidated, thus yielding the complete sequence of lambda plac 5 DNA including the lac5 substitution, a well-known segment of lambdoid vectors. The lambda plac5 DNA is shown to consist of 19368 bp (lambda left arm) + 3924 bp (lac5 substitution) + 25353 bp (lambda right arm), totally amounting to 48645 bp. The presence of the phage rho bL promoter near to the right end of the lac5 insert is shown. The lacI gene distal end in lambda plac5 proved to be much longer than it was postulated earlier, coding for 224 C-terminal amino acid residues of lac repressor. Both the recombination studied in this paper and the earlier studied abnormal prophage excision (2, 3) occur near to Chi-like structures (chi*lacI and chi*lom, respectively). On the basis of the data obtained, a key role of the E. coli RecBCD system and Chi-like sequences in the formation of deletions in bacterial cells is suggested.     

Site-specificity of abnormal excision: the mechanism of formation of a specialized transducing bacteriophage lambda plac5.

Molecular mechanism of the specialized transducing bacteriophage lambda plac5 formation has been studied. Phage-bacterial DNA junctions in lambda plac5 DNA are localized and primary structure of regions of the abnormal excisional recombination leading to the phage formation is elucidated; the crossover region proved to be comparable with the central part of attP and attB sites (the core and the adjacent tetranucleotide) in length and degree of homology. Bacterial insert in lambda plac5 DNA is shown to end immediately after Z-Y spacer, the DNA not containing lacY gene segments. The data obtained led to the conclusion of site-specific (homologous) character of abnormal excision upon formation of lambda transducing bacteriophages. Possible mechanisms of the excision are discussed.     

The role of supercoiling in mycobacteriophage L5 integrative recombination.

The genome of temperate mycobacteriophage L5 integrates into the chromosomes of its hosts, including Mycobacterium smegmatis , Mycobacterium tuberculosis and bacille Calmette-Guérin. This integrase-mediated site-specific recombination reaction occurs between the phage attP site and the mycobacterial attB site and requires the mycobacterial integration host factor. Here we examine the role of supercoiling in this reaction and show that integration is stimulated by DNA supercoiling but that supercoiling of either the attP or the attB substrate enhances recombination. Supercoiling thus facilitates a post-synaptic recombination event. We also show that, while supercoiling is not required for the production of a recombinagenic intasome, a mutant attP DNA deficient in binding of the host factor acquires a dependence on supercoiling for intasome formation and recombination.     

The interaction of recombination proteins with supercoiled DNA: defining the role of supercoiling in lambda integrative recombination

Lambda integrative recombination depends on supercoiling of the phage attachment site, attP. Using dimethylsulfate protection and indirect end-labeling, the interaction of the recombination proteins Int and IHF with supercoiled and linear attP has been studied. Supercoiling enhances the binding of Int to attP, but not if a truncated attP site is employed or if IHF is omitted. We reason that the altered affinity reflects the formation of a higher-order nucleoprotein structure, an "attP intasome," that involves Int and IHF assembly of both arms of attP into a wrapped configuration. The good correlation between the degree and sign of supercoiling needed to promote recombination and that needed for the "attP intasome" indicates that the primary role of supercoiling is to drive the formation of the wrapped structure.     

The role of recombination in the formation of circular oligomers of the lambda plasmid

The λdv1 plasmid forms an extensive oligomeric series of circular DNA molecules in recombination-proficient (recsu⁺) Escherichia coli. These rec⁺ [λdv1]⁺ strains can be typed into the following four classes according to which member of the oligomeric series is most frequent: monomer, dimer, trimer, and tetramer strains. Each of these strains forms a set of circular λdv1 DNA molecules in which most members belong to the series l, 2l, 3l, 4l, where l is the length of the most frequent circular DNA that characterizes the strain—i.e. l equals the length of the most frequent oligomer in the respective strain. In a given strain, the frequency of a molecular species decreases as its length becomes a larger multiple of l. For example, the dimer strains produce dimers, tetramers, hexamers, octomers, etc., in decreasing frequencies, which reach the limits of detection at about the hexadecamer.When recA^? mutations that are absolutely defective for host recombination are introduced into each of these four strains, l retains the same values as in the parent rec⁺ strain, but oligomers larger than 2l are not formed, and the frequency of the 2l oligomer is much reduced. The introduction of recB^? or recC^? mutations, which are only partially defective for host recombination, produces a much smaller perturbation of the rec⁺ distributions, and $\text{rec}{}^{\mathrm{+}}\text{recA}{}^{\mathrm{?}}$ merodiploids exhibit the rec⁺ phenotype with respect to both oligomerization and host recombination.The effects of rec^? mutations on the distribution of λdv1 oligomers and the nature of the oligomeric series produced in rec⁺ cells all indicate that an intermolecular reciprocal recombination between two circular λdv1 DNAs is the principal reaction responsible for oligomerization. It is suggested that the small residual oligomerization that yields 2l oligomers in recA^?cells results from aberrant segregation of the DNA strands at the termination of the replication of l-sized molecules.The inactivation of recA, but not of recB or C, also results in a marked reduction in the frequency of spontaneous curing which in recA⁺ [λdv1⁺]hosts leads to the segregation of [λdv^?]cells. However, spontaneous curing does not appear to be dependent upon the recombination reactions that yield the [λdv 1⁺]oligomers, since the frequency of oligomerization in recA⁺ hosts decreases with increasing l, whereas the frequency of curing increases with increasing l.     

Orientation-dependent recombination hotspot activity in bacteriophage lambda.

Promoters of genetic exchange by the Escherichia coli Rec system, Chi elements, have been analyzed in λ phages carrying bacterial EcoRI restriction fragments. Some fragments confer Chi⁺ phenotype in one orientation and Chi^? in the opposite orientation. The inactivity of Chi in one orientation explains why all active Chi elements in λ manifest a certain recombinational bias of the same sense.When these studies were undertaken, we rather expected to find two classes of Chi, one class which stimulated recombinant formation stronger to its left and one class stimulating recombinant formation more strongly to its right. The failure to find the second class is now understandable by supposing that the orientation of Chi which would have permitted it to act rightward is the orientation in which Chi has no activity at all. Several models are proposed for the orientation dependence of Chi activity.     

Site-specific photo-cross-linking between lambda integrase and its DNA recombination target

The site-specific recombinase (Int) of bacteriophage lambda is a heterobivalent DNA-binding protein and is composed of three domains as follows: an amino-terminal domain that binds with high affinity to "arm-type" sequences within the recombination target DNA (att sites), a carboxyl-terminal domain that contains all of the catalytic functions, and a central domain that contributes significantly to DNA binding at the "core-type" sequences where DNA cleavage and ligation are executed. We constructed a family of core-type DNA oligonucleotides, each of which contained the photoreactive analog 4-thiodeoxythymidine (4-thioT) at a different position. When tested for their respective abilities to promote covalent cross-links with Int after irradiation with UV light at 366 nm, one oligonucleotide stood out dramatically. The 4-thioT substitution on the DNA strand opposite the site of Int cleavage led to photo-induced cross-linking efficiencies of approximately 20%. The efficiency and specificity of Int binding and cleavage at this 4-thioT-substituted core site was shown to be largely uncompromised, and its ability to participate in a full site-specific recombination reaction was reduced only slightly. Identification of the photo-cross-linked residue as Lys-141 in the central domain provides, along with other results, several insights about the nature of core-type DNA recognition by the bivalent recombinases of the lambda Int family.     

A coliphage lambda vector with enhanced biological containment: lambda gtALO.lambda B.

The biological containment of the lambda gt family of cloning vectors has been enhanced by conditionally blocking DNA replication as well as head and tail morphogenesis. The vector, lambda gtALO.lambda B, was constructed by crossing the Oam29, Aama1 and Lam439 mutations into lambda gt.lambda B. The mutation blocking phage DNA replication, Oam29, is suppressed by suII+ or suIII+. The head gene mutation, Aama1, is suppressed by suIII+ but not by suII+ and the tail gene mutation, Lam439, is suppressed by suII+ but not by suIII+. This allows the option of increasing the biological containment by producing heads when a large amount of cloned DNA is being prepared from an individual isolate. A model recombinant, lambda gt Aama1 Lam439 Oam29.KmR' (lambda gtALO.KmR') was constructed and the containment of the vector was evaluated by the series of standardized experiments required for EK2 certification.     

A critical role of lambda 5 protein in B cell development.

The lambda 5 gene is a homolog of immunoglobulin J lambda-C lambda genes, expressed specifically in immature B-lineage cells. Lambda 5-encoded molecules form membrane complexes with mu or D mu proteins in association with an additional protein specifically expressed in immature B cells that is encoded by the Vpre-B gene. We have generated mice in which the lambda 5 gene is inactivated by targeted gene disruption in embryonic stem cells. In these mice, B cell development in the bone marrow is blocked at the pre-B cell stage. However, the blockade is leaky, allowing B cells to populate the peripheral immune system at a low rate. These cells are allelically excluded and able to respond to antigen.