Initiation of synthesis of the structural proteins of Semliki Forest virus.

Insertion of phage λ DNA into the normal attachment site of the DNA of the host Escherichia coli has been studied by ultracentrifugation analysis of the conversion of covalent circles of F′450 (F′gal att^λ bio) to F′450(λ) circles. We have found that integration proceeds at the normal rate if, in addition to the int gene product and a proper combination of phage and bacterial attachment sites, a large pool of λ DNA and some activity of the excision gene xis are present. In addition, turnoff of both phage DNA synthesis and xis gene activity are required.     

On the role of the bacteriophage lambda int gene product in site specific recombination

Integrative recombination of phage λ DNA occurs in extracts made from cells synthesizing int protein. In this paper we show that extracts of cells containing temperature-sensitive int protein are inactivated more rapidly by incubation at 38 °C than are wild-type extracts. This indicates that the int protein is directly involved in the recombination reaction.     

Intracellular events during infection by Haemophilus influenzae phage and transfection by its DNA

Intracellular events following infection of competent Haemophilus influenzae by HPlcl phage, or transfection by DNA from the phage, were examined. Physical separation of a large fraction of the intracellular phage DNA from the bulk of the host DNA was achieved by lysis of infected or transfected cells with digitonin, followed by low-speed centrifugation. The small amount of bacterial DNA remaining with the phage DNA in the supernatants could be distinguished from phage DNA by its ability to yield transformants. After infection by whole phage, three forms of intracellular phage DNA were observable by sedimentation velocity analysis: form III, the slowest-sedimenting one; form II, which sedimented 1.1 times faster than III, and form I, which sedimented 1.6 times faster than III. It was shown by electron microscopy, velocity sedimentation in alkali, and equilibrium sedimentation with ethidium bromide, that forms I, II and III are twisted circles, open circles, and linear duplexes, respectively.After the entry of phage DNA into wild-type cells in transfection, the DNA is degraded at early times, but later some of the fragments are reassembled, resulting in molecules that sediment faster than the monomer length of phage DNA. Some of the fast-sedimenting molecules are presumably concatemers and are generated by recombination. In strain rec₁^? the fast-sedimenting molecules do not appear and degradation of phage DNA is even more pronounced than in wild-type cells. In strain rec₂^? there is little degradation of phage DNA, and the proportion of fast-sedimenting molecules is much smaller than in wild-type cells. Since rec₁^? and rec₂^? are transfected with much lower efficiency than wild type, our hypothesis is that both fragmentation and generation of fast-sedimenting phage DNA by recombination are required for more efficient transfection.     

The cyclization of Xenopus laevis 5 S DNA

DNA from Xenopus laevis containing the sequences complementary to 5 S RNA has been studied by the formation of folded rings. Maximal cyclization for fragments 1 to 2 μm in length is 45 to 55%. Thus the efficiency of folded ring formation from this tandemly-repeating DNA is about 50%, assuming that all fragments are 5 S DNA. From the ring frequency as a function of the number of nucleotides removed from the 3′ terminals of the shear-broken fragments, one may calculate that the repeating sequence is approximately 750 nucleotides long, a number that agrees with earlier partial denaturation mapping. The circumference of the folded rings confirms this repeating length since most rings correspond to modular size classes of 0.25-μm increments. Fragments 12 μm long cyclize almost as readily as 1 to 2-μm fragments do. Therefore, the length of the regions (g-regions) containing the tandemly-repeating 5 S DNA is more than 12 μm. The folded rings are about as stable to linearization by increasing concentrations of formamide as the duplex DNA is to denaturation. This indicates that the local, non-transcribed, spacer portions which represent the majority (83%) of the nucleotides in the tandemly-repeating unit, are probably homogeneous in sequence. The exonuclease-treated 5 S DNA fragments cyclize more rapidly than phage T7 DNA, and the kinetics are in accord with theoretical expectation.     

Structural features of lambda site-specific recombination at a secondary att site in galT.

Integration of bacteriophage λ DNA into the chromosome of its E. coli host proceeds via a site-specific recombination between specific loci (att sites) on the phage and bacterial chromosomes. Infection of an E. coli host deleted for the primary bacterial att site results in λ integration with reduced efficiency at a number of different “secondary att sites” scattered around the E. coli chromosome. The first DNA sequence analysis of such a secondary att site, that occurring in the galT gene, is reported here, and several features pertinent to the mechanism of int-dependent site-specific recombination are discussed.Previous studies have shown that the crossover in int-dependent recombination must be somewhere within a 15 bp sequence (core region) common to the phage and primary bacterial att sites, as well as to the left and right prophage att sites which are at the junctures between prophage and host DNA. Comparison of the galT secondary prophage att sites with the primary prophage att sites allows determination of the analogous “core” region in the galT secondary att site. The 15 bp sequence thus identified shows an interrupted homology (8 out of 15) with the wild-type core. The extent and arrangement of nonhomologous bases allow precise placement of the crossover point for this recombination to the +4–+5 internucleotide bond of the core region.Sequences flanking the core region show no obvious homology with analogous sequences of the phage or primary bacterial att sites. Comparison of the galT left prophage att site with the analogous wild-type site is of particular interest and is discussed in relation to binding studies with purified int protein.     

Site-specific integration of the phage ΦCTX genome into the Pseudomonas aeruginosa chromosome: characterization of the functional integrase gene located close to and upstream of attP

The site-specific integration of the phage ?CTX genome, which carries the gene for a pore-forming cytotoxin, into the Pseudomonas aeruginosa chromosome was analysed. The 1,167 by integrase gene, int, located immediately upstream of the attachment site, attP, was characterized using plasmid constructs, harbouring the integration functions, and serving as an integration probe in both P. aeruginosa and Escherichia coli. The attP plasmids p1000/p400 in the presence of the int plasmid pIBH and attP-int plasmids pINT/pINTS can be stably integrated into the P. aeruginosa chromosome. Successful recombination between the attP plasmid p1000 and the attB plasmid p5.1, in the presence of the int plasmid pIBH in E. coli HB101 showed that the int gene is active in trans in E. coli. The int gene product was detected as a 43 kDa protein in E. coli maxicells harbouring pINT. Proposed integration arm regions downstream of attP are not necessary for the integration process. pINT and phage ?CTX could be integrated together into P. aeruginosa chromosomal DNA, yielding double integrates.     

Heterocyst division in two blue-green algae

Bacteriophage 16-6-12 of Rhizobium lupini has a long, non-contractile tail and a head which is hexagonal in outline. The tail is 140 nm in length, 11 nm in diameter, and carries a short terminal fiber. Analysis of the tail structure by optical diffraction indicates that it is of the helical “stacked disc” type. After phenol-extraction from purified particles, the DNA of phage 16-6-12 can circularize in vitro. No significant difference in contour length was observed between the linear (14.34±0.28 μm) and circular (14.44±0.24 μm) forms of molecules. After partial denaturation with alkali an AT-GC-map was constructed, which shows an asymmetric distribution of AT- and GC-rich regions. It is concluded that this phage DNA can circularize due to the presence of cohesive ends and that it is not circularly permuted.     

Prophage lambda at unusual chromosomal locations: III. The components of the secondary attachment sites

The integration of phage λ occurs by a reciprocal genetic exchange, promoted by the product of phage int gene, at specific sites on the phage and bacterial genomes (att's). Lysogenic bacteria thus contain two att's which bracket the inserted prophage. Genetically, the phage, bacterial and prophage att's differ from each other, indicating that each site has specific elements which segregate during recombination.In hosts that lack the bacterial att, phage integration occurs at about 0.5% the normal frequency. It results from Int-promoted recombination between the phage att and any one of many secondary sites in the bacterial genome. To analyze these sites, we measured Int-promoted recombination at the secondary prophage att's. We found that they differed from the normal prophage att's and from the phage att. The secondary sites, therefore, do not appear to carry any of the specific elements of the phage or bacterial att's.The transducing phage isolated from secondary site lysogens integrate at two loci. In the absence of helper, they insert via homology with the bacterial DNA. Co-infection with helper results in their integration at the normal bacterial att.     

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.     

Bacteriophage N3 of Haemophilus influenzae. IV. Intracellular events during infection by Haemophilus influenzae phage and transfection by its DNA

Intracellular events following infection of competent Haemophilus influenzae cells by N3 phage or transfection by DNA from phage were examined. After infection by whole phage three forms of intracellular phage DNA were observed by sedimentation velocity analysis. These forms are probably twisted circles, open circles and linear duplexes. In transfection only about 15% of the phage DNA is efficiently taken up by the competent cells. After entry of phage DNA into wild-type cells in transfection the DNA is degraded at early times, but later some of the fragments are reassembled, resulting in molecules that sediment faster than the monomer length of phage DNA. These presumably concatamer forms are generated by recombination. In strain rec-1 the fast-sedimenting molecules do not appear and degradation of phage DNA is even more pronounced than in the wild-type cells. Since rec-1 is transfected with much lower efficiency than the wild-type our hypothesis is that both fragmentation and generation of fast-sedimenting phage DNA by recombination are required for efficient transfection. These results also show that although phage N3 codes for its own recombination system it cannot operate in the early stages of transfection and succesful transfection is entirely dependent upon the host recombination system.     

int-h: An int mutation of phage lambda that enhances site-specific recombination

The mutation int-h3 maps in the int gene of coliphage λ and results in the synthesis of an integrase with enhanced activity, which is manifested by an ability to support λ site-specific recombination relatively efficiently under conditions where the wild-type integrase functions inefficiently. The level of site-specific recombination seen in the presence of the int⁺ integrase in himA^? hosts is greatly reduced, as measured by lysogen formation, intramolecular site-specific integration and excision, and excision of a cryptic λ prophage. In contrast, the int-h3 integrase shows relatively high levels of activities under these conditions. Int-h3 is also more active in other host mutants (himB and hip) that reduce λ site-specific recombination. In the absence of the normal attB site, the frequency of lysogen formation (at secondary sites) by λ int⁺ is reduced 200 fold. Although λ int-h3 will integrate preferentially at the attB site if it is present, the mutant phage forms lysogens at a high frequency in attB-deleted hosts. λ int-h3 requires himA function for integration at secondary sites. The fact that the int-h3 integrase uses the same att sites as well as the same host functions as the int⁺ integrase suggests that the mutation results in a quantitative rather than a qualitative change in integrase activity; that is, the int-h3 integrase is more active. The mutant integrase supports site-specific recombination with att sites that carry the att24 mutation. We propose that the int-h3 integrase is endowed with an enhanced ability to recognize att sequences, including some that are not effectively recognized by wild-type integrase.     

Fitness Cost Implications of PhiC31-Mediated Site-Specific Integrations in Target-Site Strains of the Mexican Fruit Fly,Anastrepha ludens (Diptera: Tephritidae)

Site-specific recombination technologies are powerful new tools for the manipulation of genomic DNA in insects that can improve transgenesis strategies such as targeting transgene insertions, allowing transgene cassette exchange and DNA mobilization for transgene stabilization. However, understanding the fitness cost implications of these manipulations for transgenic strain applications is critical. In this study independent piggyBac-mediated attP target-sites marked with DsRed were created in several genomic positions in the Mexican fruit fly, Anastrepha ludens. Two of these strains, one having an autosomal (attP_F7) and the other a Y-linked (attP_2-M6y) integration, exhibited fitness parameters (dynamic demography and sexual competitiveness) similar to wild type flies. These strains were thus selected for targeted insertion using, for the first time in mexfly, the phiC31-integrase recombination system to insert an additional EGFP-marked transgene to determine its effect on host strain fitness. Fitness tests showed that the integration event in the int_2-M6y recombinant strain had no significant effect, while the int_F7 recombinant strain exhibited significantly lower fitness relative to the original attP_F7 target-site host strain. These results indicate that while targeted transgene integrations can be achieved without an additional fitness cost, at some genomic positions insertion of additional DNA into a previously integrated transgene can have a significant negative effect. Thus, for targeted transgene insertions fitness costs must be evaluated both previous to and subsequent to new site-specific insertions in the target-site strain.     

An integration-proficient int mutant of bacteriophage lambda

Summary We have isolated and characterized a novel int mutant of phage . This mutant promotes efficient recombination between the phage and bacterial attachment sites, but, unlike wild type, does not promote efficient recombination of any other pair of attachment sites tested in most conditions. IN particular, recombination between two phage or two prophage attachment sites is poor relative to the wild type frequency. We attribute this unusual phenotype to differences in the distribution of int protein binding sites among different attachment sites (Ross and Landy 1982, 1983). We suggest that int protein molecules bound to one of two recombining DNAs interact with empty sites or with bound proteins on the other, and that the mutant protein acts efficiently only if the distribution of protein binding sites within the two attachment sites is that of the attP-attB pair. Similar discrimination among attachment site pairs by wild type int protein may also modulate recombination frequencies.     

Mechanisms involved in the formation of plaque-forming derivatives from over-sized hybrid phages between bacteriophage P1 and the R plasmid NR1

Three case histories document how subsequent events of genomic rearrangements and selection interplay in the evolution of infectious bacteriophage genomes carrying acquired genes. Two of the phages studied were plaque-forming P1CmTc recombinants derived from P1Cm1 and P1Tc1, both of which are hybrids between phage P1 and the R plasmid NR1. In the formation of the P1CmTc4 genome a postulated intermediate underwent IS1-mediated deletion formation. From the same intermediate P1CmTc1 must have evolved by IS1-mediated inversion followed by homologous recombination with a parental phage DNA. The third case documents formation of the P1Cm2 genome by “illegitimate” intramolecular recombination in the genome of P1-r-det, a hybrid between P1 and NR1.     

Involement of supertwisted DNA in integrative recombination of bacteriophage lambda.

Negatively supertwisted closed circular DNA is the primary substrate for integrative recombination of phage λ DNA in vitro. Closed circular λ DNA without supertwists must be converted to the supertwisted form by the action of Escherichia coli DNA gyrase before efficient recombination can occur. When negatively supertwisted substrate is provided, E. coli DNA gyrase and its cofactors are dispensable components of recombination reaction mixtures. In the absence of DNA gyrase activity, circular DNA considerably less negatively twisted than naturally occurring supercoils is an effective substrate, but positively supertwisted DNA appears to be an ineffective substrate.The predominant products of integrative recombination in vitro are covalently closed circles. The closure of the recombined sites appears to occur without appreciable DNA synthesis and without the action of E. coli DNA ligase. No detectable difference can be observed between the degree of supertwisting of product DNA and that of unrecombined DNA. These facts suggest that the resealing of broken DNA strands is an integral part of the recombination reaction mechanism and is closely coupled with the breakage and realignment steps of recombination.     

Location of DNA ends in P2, 186, P4 and lambda bacteriophage heads

When mature phage particles were suspended in a solution containing formaldehyde (0.07 m-Na⁺, pH 9.0, 10% HCHO for 10 min at 23 °C) and the mixture then spread for electron microscopy in the presence of 50% formamide and cytochrome c, the phage lysed and a high proportion of the DNA molecules were seen to be attached to phage tails. The phage tails were found to be attached at only one end of each DNA molecule and denaturation mapping showed that this end was unique for each of the phages P2, 186, P4 and λ. It is argued that in these mature phage particles one specific end of the DNA molecule is present at the head-tail attachment site.