The construction in vitro of transducing derivatives of phage lambda

Summary Methods are described for the construction of plaque-forming, transducing derivatives of phage lambda, using appropriate receptor genomes and fragments of DNA generated by the restriction enzymes endo R.EcoRI and endo R.HindIII. The general properties of the transducing derivatives are described and discussed. Plaque-forming phages carrying the E. coli trp, his, cysB, thyA, supD, supE, supF, hsd, tna and lig genes have been isolated.     

The net hydration of phage lambda

The banding density of phage lambda varies with the activity of water when the phage particles are banded in a series of different cesium salts. The results are comparable to those Hearst and Vinograd for free DNA. Lambda phage ghosts show less net hydration than the phage particles and band in a fairly narrow range of densities in these cesium salts. The phage banding density may be predicted to a first approximation by a simple additive approximation: the total net hydration of the phage is approximately equal to the net hydrations of free λ DNA λ hosts, all measured at the same water activity. The simple additive approximation is not adequate, however, to explain the banding density differences between a deletion mutant and phage lambda in the different cesium salts. The density differences evidently are sensitive to second-order effects: they apparently are affected by a restriction of DNA hydration inside the phage head, which depends both on water activity and on DNA length (or free volume inside the phage head). This becomes a striking effect in Cs₂SO₄ solutions where the net DNA hydration is large. Changing the phage banding density by substituting 5-bromouracil for thymine, which increases the DNA mass while leaving the DNA volume relatively unchanged, gives results consistent with a restriction of the net DNA hydration that depends on the DNA volume. Data on the sedimentation velocity behavior that λ and λb₂ in diferrent salts are presented and discussed. It appears possible to estimate the size of a DNA deletion from the phage sedimentation coefficient.     

The topological mechanism of phage lambda integrase.

Bacteriophage lambda integrase (Int) is a versatile site-specific recombinase. In concert with other proteins, it mediates phage integration into and excision out of the bacterial chromosome. Int recombines intramolecular sites in inverse or direct orientation or sites on separate DNA molecules. This wide spectrum of Int-mediated reactions has, however, hindered our understanding of the topology of Int recombination. By systematically analyzing the topology of Int reaction products and using a mathematical method called tangles, we deduce a unified model for Int recombination. We find that, even in the absence of (-) supercoiling, all Int reactions are chiral, producing one of two possible enantiomers of each product. We propose that this chirality reflects a right-handed DNA crossing within or between recombination sites in the synaptic complex that favors formation of right-handed Holliday junction intermediates. We demonstrate that the change in linking number associated with excisive inversion with relaxed DNA is equally +2 and -2, reflecting two different substrates with different topology but the same chirality. Additionally, we deduce that integrative Int recombination differs from excisive recombination only by additional plectonemic (-) DNA crossings in the synaptic complex: two with supercoiled substrates and one with relaxed substrates. The generality of our results is indicated by our finding that two other members of the integrase superfamily of recombinases, Flp of yeast and Cre of phage P1, show the same intrinsic chirality as lambda Int.     

Binding and bending of the lambda replication origin by the phage O protein.

We have characterized the binding of lambda phage replication initiation protein O to the phage origin of replication. The minimal DNA segment required for O binding is the single iteron, a 19-bp sequence of hyphenated dyad symmetry that is repeated with variations four times in the origin. The isolated amino terminus of O protein is also sufficient to bind DNA. Electrophoretic studies show that the amino terminus of O protein induces bending of a single iteron. The DNA-protein interaction was characterized by ethylation interference, dimethyl sulfate protection and neocarzinostatin footprinting. Points of DNA-protein contact are largely concentrated in two areas symmetrically disposed with respect to the dyad symmetry of the iteron. This suggests the protein interacts as a dimer with half sites in the DNA. However, a few non-symmetrical contacts are found, indicating that O protein may distort the helix. This may correlate with the bending effects demonstrated electrophoretically. Cylindrical DNA projections were used to model O protein binding to the lambda origin and compare it with the lambda repressor-operator interaction. Whereas bound repressor nearly encircles the DNA in the major groove, O protein leaves the major groove on the opposite side exposed.     

Enlarged model of lambda phage ontogenesis

An enlarged threshold model of the Regulatory System of Development of λ-Phage (RSDP λ-2) is built. It includes 15 synthetic blocks of proteins and mRNAs and four blocks corresponding to the other ontogenetic processes: two-stage replication, integration and excision of phage genome, formation of oligomers of regulatory proteins, regulation of bacteriallysis. By way of computer simulation of the RSDP λ-2 model the dynamics of concentrations of all main proteins, respective fractions of mRNAs and DNA are described in the lytic and lysogenic regimes of phage ontogenesis. Results obtained are in good agreement with available experimental data. The dependence of a portion (%) of lysogenic responses on the multiplicity $\text{k}$ of phage infection of bacterial culture, is built. This curve has a maximum point in accordance with the experimental data of P. Kourilsky (1973).     

The origin of phage virology.

The history of bacteriophage (phage) had its start in 1915, when Twort isolated an unusual filterable and infectious agent from excrete of patients struck by diarrhoea; this discovery was followed by an analogous, and probably independent, finding of d'Hérelle in 1917. For several years phage research made scant progress but great attention was paid to the question of phage nature, which saw the contrast between d'Hérelle and Bordet's views (living against chemical nature, respectively). This situation changed with the independent discovery of lysogeny, in 1925, thanks to Bordet and Bail: this phenomenon was considered of genetical origin, a view that Wollman interpreted by assimilating the properties of phage to those of gene (according to a previous idea of Muller). In the 1930s, Burnet's work opened a new era by demonstrating the occurrence of several species of phages and their antigenic property. In the same period, the physical and chemical characteristics of these viruses were disclosed thanks, in particular, to the work of Schlesinger, who first demonstrated that a virus (phage) was constituted of nucleoproteins. The peculiarity of phage was finally shown after the invention of electron microscope: H. Ruska, in 1940, and Anderson and Luria in the next years, obtained the first images of tailed phages, a finding that strongly helped the investigation on the first steps of the infection process. The decisive impulse to phage virology came from Delbrück, a physicist who entered biology giving it a new arrangement. The so-called "phage group" assembled brilliant minds (Luria, Hershey and Delbrück himself, and later a dozen of other scientists): this group faced three fundamental questions of phage virology, i.e., the mechanisms of attack, multiplication and lysis. In ten years' time, phage virology became an integrant part of molecular biology, also thanks to the discovery of the genetical properties of DNA: in such scientific context, Delbrück, Luria and Hershey's works emerged for the absolute excellence of their results, which led such scientists to Nobel prize. Lysogeny was however neglected by the phage group: this singular property shared by bacteria and phages was instead investigated by Lwoff's group, in Paris, and explained in its fundamental features during the 1950s. The "phage's saga" has gone on being an important division of molecular biology till today, and its history is far from being over.     

Filter-supported preparation of lambda phage DNA

A rapid and simple method is described for the isolation of DNA from phage lambda which requires neither special equipment nor expensive material such as cesium chloride for ultracentrifugation nor extractions with organic solvents or ethanol precipitation. Microgram quantities of lambda DNA are obtained in less than 2 h from 90-mm plate lysates or 5-ml liquid cultures. The method allows the simultaneous isolation of large numbers of probes, e.g., clones from phage libraries. Lambda phages are precipitated by polyethylene glycol/sodium chloride and recovered by low speed centrifugation onto glass fiber filters positioned in disposable syringes. The DNA of phages is released by a 50% formamide/4 M sodium perchlorate solution, washed in filter-bound form, eluted with a small volume of low-salt buffer or water, and finally recovered by centrifugation. Comparison of the DNA isolated by this method with that obtained by two conventional procedures reveals both a similar recovery and a similar suitability for restriction enzyme digestion and subcloning.     

Enlarged model of lambda phage ontogenesis

An enlarged threshold model of the Regulatory System of Development of λ -Phage (RSDP λ-2) is built. It includes 15 synthetic blocks of proteins and mRNAs and four blocks corresponding to the other ontogenetic processes: two-stage replication, integration and excision of phage genome, formation of oligomers of regulatory proteins, regulation of bacteriallysis. By way of computer simulation of the RSDP A-2 model the dynamics of concentrations of all main proteins, respective fractions of mRNAs and DNA are described in the lytic and lysogenic regimes of phage ontogenesis. Results obtained are in good agreement with available experimental data. The dependence of a portion (%) of lysogenic responses on the multiplicity $\text{k}$ of phage infection of bacterial culture, is built. This curve has a maximum point in accordance with the experimental data of P. Kourilsky (1973).     

Rapid isolation of phage lambda DNA

A modified procedure in two versions (micro, for 10 ml of phage lysate, and macro, for 200-500 ml) is described for preparing lambda phage DNA. The main advantage of the modified method is that it gives a possibility to isolate high-quality DNA from lambda phage lysates in 2-3 hrs. Only standard solutions (TE, NaCl, SDS, MgCl2, EDTA, RNAse A) were used throughout the whole protocol. Incubation with DNAse I and proteinase K was omitted and in microvariant concentration of the phage by PEG 6000 was excluded. Digestion by RNAse A was performed in solution with EDTA and SDS and leads to RNA degradation. The yields of DNA (0.5-2 micrograms per ml of L-broth) are similar to those obtained by other methods. DNA quality is better than in the samples of DNA prepared by other express-methods and practically the same as after CsCl centrifugation. DNA can be used for splitting by restriction enzymes, cloning and gene library construction.     

N-terminal sequence of phage lambda repressor

Summary Lambda repressor was purified from an E. coli strain which produces 150 times more lambda repressor than a single lysogen. The sequence of the fifty N-terminal residues was determined by automated Edman degradation. It contains 43% of all arginine and lysine residues of the chain and constitutes according to the genetic data of Oppenheim et al. (1975) a substantial part of the operator-DNA-binding site of the repressor.     

The production of generalized transducing phage by bacteriophage lambda

Generalized tranduction has for about 30 years been a major tool in the genetic manipulation of bacterial chromosomes. However, throughout that time little progress has been made in understanding how generalized transducing particles are produced. The experiments presented in this paper use phage λ to assess some of the factors that affect that process. The results of those experiments indicate: (1) the production of generalized transducing particles by bacteriophage λ is inhibited by the phage λ exonuclease (Exo). Also inhibited by λ Exo is the production of λdocR particles, a class of particles whose packaging is initiated in bacterial DNA and terminated at the normal phage packaging site, cos. In contrast, the production of λdocL particles, a class of particles whose packaging is initiated at cos and terminated in bacterial DNA, is unaffected by λ Exo; (2) λ-generalized transducing particles are not detected in induced lysis-defective (S⁻) λ lysogens until about 60–90 min after prophage induction. Since wild-type λ would normally lyse cells by 60 min, the production of λ-generalized transducing particles depends on the phage being lysis-defective; (3) if transducing lysates are prepared by phage infection then the frequency of generalized transduction for different bacterial markers varies over a 10–20-fold range. In contrast, if transducing lysates are prepared by the induction of a λ lysogen containing an excision-defective prophage, then the variation in transduction frequency is much greater, and markers adjacent to, and on both sides of, the prophage are transduced with much higher frequencies than are other markers ; (4) if the prophage is replication-defective then the increased transduction of prophage-proximal markers is eliminated; (5) measurements of total DNA in induced lysogens indicate that part of the increase in transduction frequency following prophage induction can be accounted for by an increase in the amount of prophage-proximal bacterial DNA in the cell. Measurements of DNA in transducing particles indicate that the rest of the increase is probably due to the preferential packaging of the prophage-proximal bacterial DNA.

These results are most easily interpreted in terms of a model for the initiation of bacterial DNA packaging by λ, in which the proteins involved (Ter) do not recognize any particular sequence in bacterial DNA but rather     

Gal transduction by phage lambda: on the origin and nature of LFT transducing genomes

Summary There are at least two classes of transducing particles made on the induction of normal lysogens: the first is capable of transducing by the insertion of the whole transducing genome into the host chromosome, so its genome must be capable of circularizing; the second transduces less well by insertion—perhaps not at all; if it does not transduce by insertion then its genome need not be linear.The formation of a transducing genome can be accomplished in three steps: (a) breaking the lysogenic bacterial chromosomes in two places, (b) joining the fragment ends together to form a circular structure, (c) opening the circle (by ter) to form a linear genome. If the resultant structure meets the requirements for packaging, it may be formed into a transducing phage, like a bougus .Any meaningful rearrangement of these steps in which step (b) is omitted or delayed leads to the formation of genomes, which are (1) unable to transduce by insertion (because both of its mature ends are unexposed) and (2) are on the average smaller than genomes which are capable of transducing by insertion (so the resultant transducing phage is less dense). Consequence (2) has been confirmed.We assume that the red function of catalyzes the joining of broken DNA molecules to each other. So red is responsible for rehealing the product of (a) back into a lysogenic chromosome and for catalyzing step (b), the healing of fragment ends into a circular structure. The much elevated level of stable transductants on induction of red ^– lysogens hereby is explained.Supported by grant E-2862 of the U.S.P.H.S. to Dr. Allan Campell.     

W-mutagenesis in the bisulfite-treated lambda phage

Survival of phage lambda cI857 inactivated by bisulfite (pH 5.6, 37 degrees C) is higher (the dose modification factor approx. 1.2) and frequency of bisulfite-induced c-mutations 2-4-fold lower on the lawn of the wild-type strain ung+, as compared to ung-1 mutant deficient in uracil-DNA glycosylase. Irradiation of host cells by a moderate UV dose inducing SOS repair system enhances the frequency of bisulfite-induced c-mutations 2-3-fold in the wild-type (ung+) host, but not in the ung-1 mutant. It is suggested that W-mutagenesis in bisulfite-treated lambda phage in the ung+ cells is due to SOS repair of apyrimidinic sites which are produced during excision of uracil residues, the products of cytosine deamination.     

Transactivation of p'R promoter of phage lambda

The host-vector system for efficient expression of the cloned genes under the control of transactivated promoter p'R of bacteriophage lambda has been elaborated. The Q protein activating p'R promoter is coded by the defective prophage constructed in vitro by means of excision of the late phage genes between the distant sites of the restriction endonuclease MluI and change of the central SalI fragment carrying the kill gene for the kanamycin resistance gene. The general recombination system is impaired during the change, thus the bacteriophage DNA can be obtained from the induced RecA cells as a plasmid DNA. The induction of the prophage results in a sharp increase of beta-lactamase synthesis (30% of soluble cell protein) under the control of p'R promoter in a plasmid derived of pBR322.     

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.     

Dimeric intermediates of recombination in phage lambda

Biparental lambda phage DNA dimers formed by the Rec recombination system of E. coli were isolated in the absence of DNA replication and phage maturation. The RecA but not the RecB gene is required for dimer formation. Dimers are primarily circular but can also be branched circular or linear. In circular dimers the crossover points are distributed uniformly along the chromosome, even in the presence of the RecB-dependent Chi recombinational hotspots. Thus in the absence of DNA synthesis and maturation, the Rec system can act reciprocally both in the presence and absence of the RecB gene; this lack of RecB participation accounts for the observed lack of Chi activity.