On the internal structure of bacteriophage lambda

The structure of bacteriophage lambda has been studied by electron microscopy of negatively stained particles. The phage particles will eject their DNA if they are heated or dialyzed against a chelating agent. The ghost particles, so formed, have a channel running down their tails. Since the channel is not visible in normal particles, the channel may be filled with part of the DNA molecule. Up to 30% of the ghosts contain round objects about half the internal diameter of the head. The round objects, called "cores," have the same buoyant density as the coat protein. The core may be a protein spool about which the phage DNA is wound.     

Crystal structure of the excisionase-DNA complex from bacteriophage lambda

The excisionase (Xis) protein from bacteriophage lambda is the best characterized member of a large family of recombination directionality factors that control integrase-mediated DNA rearrangements. It triggers phage excision by cooperatively binding to sites X1 and X2 within the phage, bending DNA significantly and recruiting the phage-encoded integrase (Int) protein to site P2. We have determined the co-crystal structure of Xis with its X2 DNA-binding site at 1.7A resolution. Xis forms a unique winged-helix motif that interacts with the major and minor grooves of its binding site using an alpha-helix and an ordered beta-hairpin (wing), respectively. Recognition is achieved through an elaborate water-mediated hydrogen-bonding network at the major groove interface, while the preformed hairpin forms largely non-specific interactions with the minor groove. The structure of the complex provides insights into how Xis recruits Int cooperatively, and suggests a plausible mechanism by which it may distort longer DNA fragments significantly. It reveals a surface on the protein that is likely to mediate Xis-Xis interactions required for its cooperative binding to DNA.     

The rolling-circle replicative structure of a bacteriophage lambda DNA

Intermediates of λ DNA replication in the second half of the latent period have been isolated and investigated in the electron microscope. The isolated replicative structures were predominantly single-branched “$\text{rolling-circle}$” replicative forms. The long linear tails (concatemers) may be the precursor of mature λ DNA.     

Hyperfine structure in melting profile of bacteriophage lambda DNA.

A high-resolution plotter of differential melting profiles of DNA, RNA, or related biopolymers with an on-line mini-computer is described. With this device, more than 15 transition steps were identified in the thermal melting profile of DNA from bacteriophage lambda. These fine structures were found to be reproducible, and some of them disappear in the deletion mutant. To Examine the melting profile, computer simulations for several hypothetical polynucleotide sequences were performed, and compared with experimental data. The sharp peaks that appeared in the differential melting profile of λ DNA may come from some homogeneous sequences of 500 bases or longer.     

Fluorescence study of secondary structure of DNA within bacteriophage lambda

Bromoacetaldehyde (BAA) was used to study the secondary structure of DNA in lambda-phage particles. It was determined that about 1% of the adenines in the intraphage lambda-DNA reacts readily with BAA, thus, they are placed in DNA sites with disturbed complementary interactions. These adenines are close to the tryptophan residues of the phage protein. Fluorescence emission of epsilon A in the intraphage DNA is dramatically quenched. This, apparently, indicates the interaction between epsilon A and Trp- and/or Tyr- and/or Met-residues of phage protein.     

Surface structure of in vitro assembled bacteriophage lambda polyheads.

Interstrand cross-links induced by psoralen-plus-light are removed from the DNA of Escherichia coli, and this reaction is effected by the uvrA, uvrB, uvrC and polA (5′ → 3′ exonuclease) gene products. During cross-link removal, cellular DNA strands are cut so that, upon denaturation, the DNA dissociates into segments having an average molecular weight about equal to twice the average distance between cross-links. These strand cuts are persistent in cells, having a half-life of more than 20 minutes.The structure of cross-linked DNA undergoing repair was further investigated by use of density and radioactively labeled isotopes. These experiments demonstrate that two strand cuts are made in one DNA strand near each cross-link, one on each side of one arm of the cross-link. A mechanism is proposed for cross-link removal. The endonuclease coded for by the uvrA and B genes makes an incision on the 5′ side of one arm of a cross-link. Polymerase I (5′ → 3′ exonuclease) then makes a second cut on the 3′ side, in the same strand. This allows the strands to be separated during denaturation, but would leave the second arm of the cross-linking structure still attached to the uncut strand. The persistence of strand cuts at cross-links suggests that rejoining, dependent upon repair polymerization and ligation, is blocked by such a partially excised cross-linking residue. Initial stages of cross-link removal appear to be similar to pyrimidine dimer excision, but intermediates generated by these processes differ substantially in structure and repair must be completed by different mechanisms.     

Lysogenization by bacteriophage lambda

Summary An easy and sensitive way of measuring the proportion of E. coli cells which are lysogenized by lambda phage or lambda mutants has been devised. With this assay it was possible to analyse the lysogenic response as a function of the average phage input per cell. The results indicate that lysogenization of exponentially growing cells requires that the cells are infected by at least two phages able to replicate, or three or four phages unable to replicate.     

Regulation of directionality in bacteriophage lambda site-specific recombination: structure of the Xis protein

Upon induction of a bacteriophage lambda lysogen, a site-specific recombination reaction excises the phage genome from the chromosome of its bacterial host. A critical regulator of this process is the phage-encoded excisionase (Xis) protein, which functions both as a DNA architectural factor and by cooperatively recruiting integrase to an adjacent binding site specifically required for excision. Here we present the three-dimensional structure of Xis and the results of a structure-based mutagenesis study to define the molecular basis of its function. Xis adopts an unusual "winged"-helix motif that is modeled to interact with the major- and minor-grooves of its binding site through a single alpha-helix and loop structure ("wing"), respectively. The C-terminal tail of Xis, which is required for cooperative binding with integrase, is unstructured in the absence of DNA. We propose that asymmetric bending of DNA by Xis positions its unstructured C-terminal tail for direct contacts with the N-terminal DNA-binding domain of integrase and that an ensuing disordered to ordered transition of the tail may act to stabilize the formation of the tripartite integrase-Xis-DNA complex required for phage excision.     

Deletion mutants of bacteriophage lambda

Summary The high frequency of recombination which results from site-specific recombination acting on certain attachment site configurations leads to unlinkage of the genes on either side of att.     

Head-tail connector of bacteriophage lambda

The head-tail connector of phage λ, a protein knob inside the head shell to which the tail attaches, is composed primarily of head protein gpB ⁴ and its cleaved form gpB¹. All of the gpB and gpB¹ in the virion is located in the connector. gpFII, the protein that is thought to form the site on the head to which the tail binds, is also located in the connector. Head proteins gpE, gpD, X1 and X2 are not components of the connector. These assignments were made by disrupting virions with guanidine hydrochloride, in such a way that heads and tails separate with the connectors attached to the tails, and determining which head proteins co-purify with the tails.We find that lysates from a λE^? infection contain a high proportion of tails with connectors attached. (Gene E codes for the major component of the head shell.) Connectors are also present on tails from a λE^?C^? infection, arguing that gpE, gpC, and their processed forms, X1 and X2, are all unnecessary for assembly of biologically competent connectors. The gpB in the connectors on E^? and E^?C^? tails is in the uncleaved form. Connectors are not seen on tails from infections by λE^?B^?, λE^?FII^?, or λE^? in a groE^? host.