LambdaattB-attP, a lambda derivative containing both sites involved in integrative recombination

An Escherichia coli mutant unable to support site-specific recombination of bacteriophage lambda

We report the isolation of mutations in, and the characterization of, an Escherichia coli gene, hip, that is required for site-specific recombination of phage lambda. hip mutants are recessive and are located near minute 20 on the linkage map. The gene product is not vital to bacterial growth, since deletion mutants are viable. The absence of hip product reduces lambda integration to barely detectable levels and also reduces prophage excision, but less drastically. Certain mutations in the lambda int gene partially restore integration and excision in hip- hosts. Homologous recombination promoted by recA does not require hip function. In addition to their defect in site-specific recombination, hip mutants are unable to support lytic growth of phage Mu or of certain lambda mutants. Their pleiotropic phenotype closely resembles that of himA mutants, but complementation, mapping and DNA sequencing show that hip and himA are different genes.

An integration-proficient int mutant of bacteriophage lambda

We have isolated and characterized a novel int mutant of phage lambda. 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.

Mutations in the DNA gyrB gene that are temperature sensitive for lambda site-specific recombination, Mu growth, and plasmid maintenance

We report the isolation of two mutations in the gyrB gene of Escherichia coli K12 obtained from an initial selection for resistance to coumermycin A1 and a subsequent screening for bacteria that fail to support site-specific recombination of phage lambda, i.e., Him-. These two mutations have a temperature-sensitive Him- phenotype, supporting site-specific recombination efficiently at low temperature, but inefficiently at high temperatures. Like other Him mutants, the gyrB-him mutants fail to plate phage Mu; again this defect is observed only at high temperatures. Additional thermally sensitive characteristics have also been observed; growth of lambda as well as maintenance of the plasmids pBR322 and F' gal are reduced at high temperature. Restriction of foreign DNA imposed by a P1 prophage is also reduced in these mutants. The temperature-sensitive phenotypic characteristics imposed by both the gyrB-him-230(Ts) and gyrB-him-231(Ts) mutations correlate with in vitro studies that show decreased gyrase activity, especially at higher temperatures, and in vivo studies showing reduced supercoiling of lambda DNA in the mutants at high temperature.

Retroregulation: control of integrase expression by the b2 region of bacteriophages lambda and 434

Genetic fusions constructed by a combination of in vivo and in vitro techniques have been used to investigate the cis-regulatory role of a 250-base-pair segment of b2 DNA in the expression of int transcripts originating from three different promoters PI, PL, and PTRP. It has been established that (a) the PI and PTRP transcripts, which produce functional int protein, are efficiently terminated by the b2 segment, (b) in the same test system, the PL transcript, which does not result in functional integrase, is not terminated by the b2 segment, (c) this b2 (sib) effect does not depend on genes lying between int and N on the phage genome, (d) the sib effect is also observed with the b2 DNA of phage 434, which resembles that of lambda between -197 and att but diverges radically from it to the left of base -197.

Probing cII and himA action at the integrase promoter pi of bacteriophage lambda

Plasmids were constructed to supply cII-coded protein for activation of the phage promoter pI. Using a fusion which expresses lacZ from pI. We can accurately follow activation of pI without having to assay int activity in vivo. A large excess of cII protein compared to a normal lytic infection stimulates lacZ expression about 10-fold over the basal level. The int-c226 constitutive allele of pI is not further activated by cII even though its level of lacZ expression is less than the maximal cII-activated expression from wild type pI. A himA-deleted strain also shows activation, demonstrating that there is no absolute requirement for the himA gene product for cII-stimulated transcription at pI.

Phasmids: hybrids between ColE1 plasmids and E. coli bacteriophage lambda

Plasmids carrying cloned lambda att sites may be integrated into the bacteriophage genome by the site-specific recombination mechanism of lambda. The cross, referred to as "lifting" the plasmid, requires mixed infection of an Escherichia coli strain carrying the plasmid with two appropriately constructed "lifting" lambda phages. One phage donates a short left arm and the other donates a short right arm. These two short arms are of insufficient length to produce a viable phage genome and yield no recombinants when crossed on standard bacteria. However, viable recombinants are obtained when the genome length is extended by integration of one or more plasmids. We call these recombinants phasmids. They contain multiple att sites introduced at the ends of the integrated plasmids, and in the presence of integrase, recombination between these att sites can be exploited to effect release of the plasmid components. These novel genetic elements can be used in a variety of ways as vectors in genetic manipulation experiments. Sequences cloned in phasmids may be studied as a component of either a plasmid and or of a phage, and easily interconverted between the two states.

Downstream regulation of int gene expression by the b2 region in phage lambda

Expression of the int gene after phage lambda infection normally requires the products of genes cII and cIII. However, when the phage carries a deletion in the nonessential b2 region adjacent to int, efficient synthesis of active Int protein does not require cII and cIII function. This inhibition of Int synthesis by nucleotide sequences downstream from the int structural gene behaves in a cis-dominant fashion in mixed infections. It is specific for PL- and not pI-initiated transcripts. Based on these observations, and those of others, a model is proposed in which Int translation from the pL transcript is inhibited by the interaction of downstream b2 nucleotide sequences and nucleotide sequences in the int region. The data imply a novel temporal mechanism regulating prophage lambda induction: circularization of the prophage genome results in the transposition of inhibitory b2 region sequences next to int and blocks further Int protein synthesis beyond the low level required for excision. As a consequence of this process, the control of int expression is transferred from the pL promoter to pI and the cII/cIII system. Such a genetic regulatory mechanism involving the rearrangement of genetic elements downstream from a structural gene may be of general use during development in other systems.

Frequent site-specific deletion of coliphage lambda murine sarcoma virus recombinants and its use in the identification of a retrovirus integration site

Stocks of hybrid lambda phages carrying the complete integrated provirus of either m1 or HT1 Moloney murine sarcoma virus, as well as flanking host sequences, frequently contain significant numbers of phages carrying a specific deletion. This deletion arises from a recombination event between the terminally repeated sequences in the provirus that deletes the unique Moloney murine sarcoma virus sequences bracketed by the terminally repeated sequences. Physical mapping has shown that the deletion phage retains one complete copy of the terminally repeated sequence and the flanking mink host sequences. One such deletion, lambdaHT1r+, was used to characterize a mink genomic DNA sequence that contains an HT1 Moloney murine sarcoma virus integration site. This integration site sequence from normal mink cells was also cloned into phage lambda. An analysis of the heteroduplexes between the integration site and the lambdaHT1r+ deletion indicated that no major rearrangement of host sequences occurred upon integration of the Moloney murine sarcoma provirus.

An E. coli gene product required for lambda site-specific recombination

We report characteristics of himA mutations of E. coli, selected for their inability to support the site-specific recombination reaction involved in the formation of lysogens by bacteriophage lambda. The himA allele lies at minute 38 on the chromosome. Three noncomplementing and closely linked mutations define the himA locus; one is a nonsense mutation which shows that the gene product is a protein. HimA mutations reduce both lambda integrative and excisive site-specific recombination. Since dominance tests demonstrate that himA mutations are recessive, it is probable that the himA protein is either a necessary component for site-specific recombination or, alternatively, regulates the expression of such a function. HimA mutations exhibit pleiotropic effects. They reduce integration of phages that have different attachment specificities from lambda and inhibit the growth of phage mu. In addition, himA mutations reduce precise excision of integrated phage mu as well as Tn elements. This pleiotropy suggests that the role of himA protein is nonspecific. Since all of the processes affected by himA mutations ultimately rely on protein-DNA interactions, we suggest that himA protein may act in an auxillary manner to facilitate these interactions.

A secondary attachment site for bacteriophage lambda in trpC of E. coli

We have determined the nucleotide sequence of a secondary lambda attachment site in trpC. Direct sequence analysis of lambdatrp transducing phage DNA fragments carrying the two prophage attachment sites reveals a 6 nucleotide homology in the crossover region which is a subset of the 15 nucleotide core sequence in the primary lambda attachment site: GCTTTTTTATACTAA. This 6 nucleotide sequence is also present in the intact trpC genome at the attachment site, as shown by analysis of trpC mRNA spanning this region.

ColE1 cloning of a ribosomal RNA promoter region from lambdarifd18 by selection for lambda integration and excision functions

The expression of the ribosomal RNA gene carried by the lambda transducing phage lambdarifd18 is shown to be subject to stringent amino acid control. lambdarifd18 DNA was digested with endonuclease EcoRI and ligated to similarly restricted ColE1 plasmid DNA. Selection for expression of lambda integration and excision gene activity carried by the same DNA fragment results in cloning of the promoter proximal portion of the 16S ribosomal RNA gene. The resulting chemera expresses lambda integration and excision functions as well as encoding the promoter proximal half of a 16S ribosomal RNA gene.

In vitro packaging of a lambda Dam vector containing EcoRI DNA fragments of Escherichia coli and phage P1

In this report we describe a coliphage lambda vector system for cloning endo R. EcoRI DNA fragments. This system differs significantly from those previously described in two ways. First, restricted and ligated DNA is encapsidated in vitro. Second, with increasing lambda DNA size in the range 78 to 100% that of wild-type, the efficiency of DNA encapsidation into infectious phage particles markedly increases. For lambda wild-type DNA the efficiency of in vitro packaging (10(6) to 10(7) plaques produced per microgram of added DNA) is equal to, or better than, the standard CaCl2 transfection method. The use of a Dam mutation to facilitate recognition of size classes of inserted fragments is described. Using this vector and in vitro packaging, several E. coli and phage P1 and R.EcoRI fragments were cloned.

Restriction assay for integrative recombination of bacteriophage lambda DNA in vitro: requirement for closed circular DNA substrate

A novel assay has been developed for in vitro genetic recombination of DNA. Substrate and product DNAs are cleaved with a restriction endonuclease and the resulting fragments are separated by electrophoresis in agarose gels. The substrate DNA has been chosen so that the recombination to be studied deletes a segment of DNA. The remaining DNA gives rise to a unique restriciton fragment, as does the DNA segment that has been removed. The method provides a convenient and physical, rather than genetic, assessment of the conversion of parental to recombinant DNA. This method has been applied to an in vitro system that carries out integrative recombination of bacteriophage lambda. We find that, different molecular forms of DNA tested, closed circular DNA is the only efficient substrate. Linear DNA and three kinds of circular DNA containing interruptions are at best very poor substrates. The implications of this surprising result are discussed. In addition, we show that the in vitro recombination system completes the breaking and rejoining steps of recombination. No stable DNA intermediates involving chiasmata or broken end structures are found.

Integrative recombination of bacteriophage lambda DNA in vitro

An in vitro system for the production of integrative recombinant DNA of bacteriophage lambda is described. The in vitro recombination mimics the in vivo integration of viral DNA into host DNA in its requirement for int gene product, for the presence of a thermolabile component, and for the limitation of the recombination to a pair of specialized sites (attachment sites) on the DNA. The enzymes are extracted from Escherichia coli containing phage lambda gene products. The substrate is the DNA from lambda-attB-attP, a phage variant that contains two attachment sites on the same chromosome. The product is a recombinant phage chromosome that has lost the DNA between the attachment sites. The parental and recombinant DNA are distinguished following transfection to mature phage in spheroplasts. The reaction requires ATP, Mg++, spermidine, and a monovalent cation. Recombination occurs preferentially between attachment sites on the same molecule. The enzymatic activity is completely inhibited by extracts containing xis gene product.