Tn5cos: a transposon for restriction mapping of large plasmids using phage lambda terminase.

A method for the rapid restriction mapping of large plasmids has been developed. A 400-bp fragment of phage lambda DNA containing the cos region has been inserted into Tn5. After in vivo transposition of this Tn5cos element into the plasmid of choice, the plasmid is isolated and linearized at its cos site with phage lambda terminase (Ter). Such Ter linearization was about 70% efficient. After partial digestion of the linear molecules with the appropriate restriction enzyme, the products are selectively labelled at the right or left cohesive phage lambda DNA termini by hybridization with digoxygenin (DIG)-11-dUTP-labelled (using terminal transferase) oligodeoxyribonucleotides complementary to the single-stranded cos ends. After pulsed field gel electrophoresis, the labelled fragments are visualized in the dried gel using a DIG-detection kit. The restriction map can be directly determined from the 'ladder' of partial digestion products.     

The Nul subunit of bacteriophage lambda terminase binds to specific sites in cos DNA.

The maturation and packaging of bacteriophage lambda DNA are under the control of the multifunctional viral terminase enzyme, which is composed of the protein products of Nu1 and A, the two most leftward genes of the phage chromosome. Terminase binds selectively to the cohesive end site (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12-base single-stranded cohesive ends of the mature phage genome. The purified gpNu1 subunit of terminase forms specific complexes with cos lambda DNA. DNase I footprinting experiments showed that gpNu1 bound to three distinct regions near the extreme left end of the lambda chromosome. These regions coincided with two 16-base-pair sequences (CTGTCGTTTCCTTTCT) that were in inverted orientation, as well as a truncated version of this sequence. Bear et al. (J. Virol. 52:966-972,1984) isolated a mutant phage which contained a CG to TA transition at the 10th position of the rightmost 16-base-pair sequence, and this phage (termed lambda cos 154) exhibits a defect in DNA maturation when it replicates in Escherichia coli which is deficient in integration host factor. Footprinting experiments with cos 154 DNA showed that gpNu1 could not bind to the site which contained the mutation but could protect the other two sites. Since the DNA-packaging specificity of terminase resides in the gpNu1 subunit, these studies suggest that terminase uses these three sites as recognition sequences for specific binding to cos lambda.     

In phage lambda, cos is a recombinator in the red pathway

Among lambda particles carrying chromosomes that have failed to replicate during a lytic cycle cross there is a high frequency of Red-mediated recombination near the right-hand end. Earlier work has shown that this recombination is dependent on cos (cohesive end site), the packaging origin of lambda. In contrast to the prediction of the break-copy model proposed earlier, we find a high recombination rate near cos even when only one of the two participating parents has a functional cos at that locus. The exchange is accompanied by loss of the stimulating cos in the recombination product, irrespective of the marker configurations: a+b+cos- rather than a+b+cos+ is produced in the cross a+b-cos- x a-b+cos+ as well as in the cross a+b-cos+ x a-b+cos-. Further analyses of these and earlier data allow the formulation of a detailed model for cos-stimulated, Red-mediated genetic exchange. In this model, cos stimulates exchange by virtue of being a double-strand cut site. The model has several features like that proposed for yeast. This role of cos in the Red pathway contrasts with the role of cos in the RecBC pathway, in which cos serves as an entry site for a recombinase that stimulates exchanges far from cos.     

The functional asymmetry of cosN, the nicking site for bacteriophage lambda DNA packaging, is dependent on the terminase binding site, cosB.

cosN is the site at which terminase, the DNA packaging enzyme of phage lambda, introduces staggered nicks into viral concatemeric DNA to initiate genome packaging. Although the nick positions and many of the base pairs of cosN show 2-fold rotational symmetry, cosN is functionally asymmetric. That is, the cosN G2C mutation in the left half-site (cosNL) causes a strong virus growth defect whereas the symmetrically disposed cosN C11G mutation in the right half-site (cosNR) does not affect virus growth. The experiments reported here test the proposal that the genetic asymmetry of cosN results from terminase interactions with cosB, a binding site to the right of cosN. In the presence of cosB, the left half-site mutation, cosN G2C, strongly affected the cos cleavage reaction, while the symmetric right half-site mutation, cosN C11G, had little effect. In the absence of cosB, the two mutations moderately reduced the rate of cos cleavage by the same amount. The results indicated that the functional asymmetry of cosNdepends on the presence of cosB. A model is discussed in which terminase-cosN interactions in the nicking complex are assisted by anchoring of terminase to cosB.     

Structure of the bacteriophage lambda cohesive end site. Genetic analysis of the site (cosN) at which nicks are introduced by terminase.

A collection of mutations affecting the site (cosN) at which the bacteriophage lambda DNA packaging enzyme, terminase, introduces nicks to generate mature lambda chromosomes has been studied. A good correlation was found for mutational effects on burst size, accumulation of unused proheads, packaging of DNA into heads and cos cutting by terminase in vitro, indicating that defective cosN cleavage by terminase is the molecular explanation for the phenotypic effects of the mutations. Although the base-pairs of cosN display partial twofold rotational symmetry, cosN was found to be asymmetric functionally. Certain mutations to the left side of the center of rotational symmetry have more pronounced phenotypic effects than rotationally symmetric mutations to the right. The cosN11G mutation has no phenotypic effects when present as a single mutation, but does affect DNA packaging and cosN cutting in the presence of the symmetrically disposed cosN2C mutation. Mutations that decrease cosN cleavage result in the accumulation of unexpanded proheads, indicating that prohead expansion depends on cosN cutting.     

Interference with phage lambda development by the small subunit of the phage 21 terminase, gp1.

Bacteriophage lambda development is blocked in cells carrying a plasmid that expresses the terminase genes of phage 21. The interference is caused by the small subunit of phage 21 terminase, gp1. Mutants of lambda able to form plaques in the presence of gp1 include sti mutants. One such mutation, sti30, is an A. T-to-G.C transition mutation at base pair 184 on the lambda chromosome. The sti30 mutation extends the length of the ribosome-binding sequence of the Nul gene that is complementary to the 3' end of the 16S rRNA from GGA to GGAG. The sti30 mutation causes a approximately 50-fold increase in the level of expression of a Nul-lacZ reporter gene, indicating that the sti30 mutation overcomes the gp1 inhibition by increasing the level of expression of gpNul. Although the Nul and A genes of lambda overlap, the sti30 mutation has little effect on the level of gpA expression, indicating that translational coupling does not occur.     

Integration host factor (IHF) stimulates binding of the gpNu1 subunit of lambda terminase to cos DNA.

The lambda terminase enzyme binds to the cohesive end sites (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12 bp single-stranded cohesive ends of the mature phage genome. In vitro this endonucleolytic cleavage requires spermidine, magnesium ions, ATP and a host factor. One of the E. coli proteins which can fulfill this latter requirement is Integration Host Factor (IHF). IHF and the gpNu1 subunit of terminase can bind simultaneously to their own specific binding sites at cos. DNase I footprinting experiments suggest that IHF may promote gpNu1 binding. Although no specific gpNu1 binding to the left side of cos can be detected, this DNA segment does play a specific role since a cos fragment that does not include the left side or whose left side is replaced by non-cos sequences, is unable to bind gpNu1 unless either spermidine or IHF is present. Binding studies on the right side of cos using individual or combinations of gpNu1 binding sites I, II and III indicate that binding at sites I and II is not optimal unless site III is present.     

Prediction of an ATP reactive center in the small subunit, gpNu1, of the phage lambda terminase enzyme

The small subunit of the bacteriophage lambda terminase enzyme, the product of the phage's Nu1 gene, is shown to contain amino acid segments homologous to those present in a large number of ATPases. In keeping with these predictions, the purified protein has been found to hydrolyze ATP with a relatively low turnover number. Terminase holoenzyme is a known ATPase, and the biochemical significance of an ATP-interactive center situated in the gpNu1 subunit is discussed.     

Structure of the bacteriophage lambda cohesive end site: location of the sites of terminase binding (cosB) and nicking (cosN)

The extents of the sites for nicking (cosN) and binding (cosB) of bacteriophage lambda DNA by terminase have been determined by studying cos cleavage and terminase binding in vitro. The cosN site is located in the segment from -22 to +24 bp (numbered from the center of the cohesive end sequence in the circular lambda genome). The cosB site is located in the segment from +51 to +120 (the +120 boundary determined by Miwa and Matsubara, 1983). Additional sequences are necessary for packaging into infectious phage particles, including regions to the left (Rz gene side) of cosN, and between cosN and cosB. Small deletions (7 and 11 bp) between cosN and cosB abolish packaging in vivo without affecting cos binding and cleavage in vitro, whereas a large deletion (26 bp) abolishes packaging in vivo and cleavage in vitro.     

Packaging of ColE1 DNA having a lambda phage cohesive end site.

The mechanism of lambda phage-mediated transduction of hybrid colicin E1 DNAs of various lengths was studied, and factors influencing the formation of these transducing particles were investigated. The results were as follows: 1. The presence of a cohesive end site of lambda phage (coslambda) on colicin E1 DNA was essential for packaging of the DNA. 2. Packaging of colicin E1 DNAs, which carry coslambda with molecular sizes corresponding to 68% of that of lambda phage DNA, was observed in the absence of all known recombination functions of E. coli K-12 and of lambda phage. 3. Hybrid colicin E1 DNAs having coslambda with molecular sizes corresponding to 28% of that of lambda phage DNA were packaged within lambda phage particles as trimers; hybrid DNAs with coslambda of 40 and 47% of the length of lambda phage DNA were packaged as dimers; and those with molecular sizes of 68% of that of lambda phage DNA were packaged mostly as monomers. These results demonstrated that two factors are essential for the packaging of DNAs within lambda phage particles; the presence of coslambda on the DNA molecule and an appropriate size of DNA.     

Formation of oligomeric structures from plasmid DNA carrying cos lambda that is packaged into bacteriophage lambda heads.

Plasmids that carry cos lambda, the region necessary for lambda phage packaging and that are as small as four kilobases in size can be packaged into lambda phage heads in head-to-tail tandem oligomeric structures. Multimeric oligomers as large as undecamers have been detected. Oligomer formation depends upon the products of red and gam of lambda, and the general recombination occurs between different plasmids that share homologous DNA regions. The packaging efficiency of plasmids depends on its copy number in cells and its genome size. Upon injection into a cell, the DNA establishes itself as a plasmid in a tandem structure. When such a plasmid in a high oligomeric structure is used as the source of packaging DNA, the packaging efficiency of the plasmids is elevated. The oligomers are stable in recA cells, whereas they drift toward lower oligomers in recA+ cells.     

The interaction of E. coli integration host factor and lambda cos DNA: multiple complex formation and protein-induced bending.

The interaction of E. coli's integration Host Factor (IHF) with fragments of lambda DNA containing the cos site has been studied by gel-mobility retardation and electron microscopy. The cos fragment used in the mobility assays is 398 bp and spans a region from 48,298 to 194 on the lambda chromosome. Several different complexes of IHF with this fragment can be distinguished by their differential mobility on polyacrylamide gels. Relative band intensities indicate that the formation of a complex between IHF and this DNA fragment has an equilibrium binding constant of the same magnitude as DNA fragments containing lambda's attP site. Gel-mobility retardation and electron microscopy have been employed to show that IHF sharply bends DNA near cos and to map the bending site. The protein-induced bend is near an intrinsic bend due to DNA sequence. The position of the bend suggests that IHF's role in lambda DNA packaging may be the enhancement of terminase binding/cos cutting by manipulating DNA structure.     

An intermediate in the phage lambda site-specific recombination reaction is revealed by phosphorothioate substitution in DNA.

It has been proposed that phage lambda site-specific recombination proceeds via two independent strand exchanges: the first exchange forming a Holliday-structure which is then converted into complete recombinant products by the second strand exchange. If this hypothesis is correct, one should be able to trap the putative Holliday intermediate by preventing the second strand exchange. In this paper, we show that substitution of phosphorothioate for phosphate in one strand of a recombination site is an effective way to block recombination while permitting the accumulation of a novel structure. This effect is seen only when phosphorothioate is positioned at a point of potential cleavage by Int recombinase, demonstrating that the inhibition of strand exchange is highly specific. Analysis of the novel structure that accumulates in these reactions proves that it contains a Holliday joint. Holliday-structures can also be detected in unblocked recombinations but are present at very low levels. The characteristics of Holliday-structure formation that we describe substantiate the proposed recombination pathway.     

Genetic analysis of mutations affecting terminase, the bacteriophage lambda DNA packaging enzyme, that suppress mutations in cosB, the terminase binding site.

Terminase, the DNA packaging enzyme of phage lambda, binds to lambda DNA at a site called cosB, and introduces staggered nicks at an adjacent site, cosN, to generate the cohesive ends of virion lambda DNA molecules. Terminase also is involved in separation of the cohesive ends and in binding the prohead, the empty protein shell into which lambda DNA is packaged. Terminase is a DNA-dependent ATPase, and both subunits, gpNu1 and gpA, have ATPase activity. cosB contains a series of gpNu1 binding sites, R3, R2 and R1; between R3 and R2 is a binding site, I1, for integration host factor (IHF), the Escherichia coli DNA bending protein. In this work, a series of mutations in Nu1 have been isolated as suppressors of cosB mutations. One of the Nu1 mutations is identical to the previously described Nu1ms1/ohm1 mutation predicted to cause the change L40F in the 181 amino acid-long gpNu1. Three other Nu1 missense mutations, the Nu1ms2 (L40I), ms3 (Q97K) and ms4 (A92G) mutations, have been isolated; the relative strengths of suppression of cosB mutations by the Nu1ms mutations are: ms1 > ms2 > ms3 > ms4. The Nu1 missense mutations all affect amino acid residues that lie outside of the putative helix-turn-helix DNA binding motif of gpNu1. The Nu1ms1 and Nu1ms2 mutations alter an amino acid residue (L40) that lies directly between two segments of gpNu1 proposed to be involved in ATP binding and hydrolysis; thus these mutations are likely to alter the gpNu1 ATP-binding site. The Nu1ms3 and Nu1ms4 mutations both affect amino acid residues in the central region of gpNu1 that is predicted to form a hydrophilic alpha-helix. To explain how the Nu1ms mutations suppress cosB defects, models involving alterations of the DNA binding and/or catalytic properties of terminase are considered. The results also indicate that terminase occupancy of a single gpNu1 binding site (R3) is necessary and sufficient for the efficient initiation of DNA packaging; the Nu1ms1, ms2 and ms3 mutations permit IHF-independent plaque formation by a phage lacking R2 and R1.     

Restriction and modification of phage 47 and lambda by R factors

S. panama 47 (antibiotic-sensitive, phage pattern A) was infected with R factors from a number of field strains of Enterobacteriaceae (Salmonella, Escherichia coli, Citrobacter, Enterobacter, Klebsiella andProteus) isolated from human and animal sources. These R factors could be grouped into 11 types i.e. R1 R11 on the basis of induced changes in the phage type of the recipient.R8 and R11 renderS. panama resistant to the phages A H:S. panama 47 (R3) and 47 (R6) adsorb the phages A F, but there is no phage multiplication: phages G and H are considered to be restricted and modified in these strains. The R factors R5 and R7 also exert restriction and modification on a number of the typing phages A H. The nature of the changes in phage pattern brought about by R4, R9 and R10 is not understood. R2 does not exert restriction (i.e. no change in phage pattern). The R factors were also investigated for the fi (fertility inhibition) and spp (restriction of phage ) markers.The R factors R3 R11 readily segregate, in the sense that the restriction and modification loci, and occasionally the Resistance Transfer Factor as a whole was frequently lost after R transfer. These 9 types of R factors were encountered infrequently in the present material.Resistance to tetracycline inS.panama is nearly always due to R factors of type R1. In other members of Enterobacteriaceae, notably inE.coli, R1 is less frequently found than R2.     

The fate of phage lambda DNA in lambda-infected minicells.

The fate of phage lambda DNA in lambda-infected Escherichia coli minicells harboring the plasmid ColE1, and in plasmid-free minicells, were studied. Binding of lambda DNA to the minicell membrane, and formation of the supercoiled covalently-closed circular structure has been demonstrated. Phage infection abolishes plasmid DNA synthesis. Only a very slight, non-replicative lambda DNA synthesis occurs, soon after infection. This synthesis is associated with fragments of lambda DNA arising during, or soon after its penetration.     

Ion etching of bacteriophage lambda: evidence that the right end of the DNA is located at the outside of the phage DNA mass.

Bacteriophage lambda was etched in an Ar+ plasma under conditions in which the capsid and some of the DNA were eroded (by sputtering) from the particle surface. Analysis of the DNA remaining in etched phage demonstrated an enrichment in sequences derived from the left end and middle of the genome; sequences from the right end were selectively lost. The results suggest that the DNA in the mature phage is arranged with its left end toward the center and its right end toward the exterior of the overall DNA mass. Since the left end is the first to enter the phage prohead, the results are most compatible with the view that prohead filling also proceeds from the center to the exterior of the cavity. The suggested arrangement of lambda DNA is comparable to that observed in phage T4 and is consistent with the spiral-fold model of packaged DNA.