Role of the cro gene in bacteriophage lambda development

Previous experiments have shown that the product of the cro gene of baeteriophage λ can exert an anti-repression activity, defined by the capacity of certain “cro-constitutive” defective lysogens to channel a superinfecting λ phage toward lytic development. We have used a combination of biological and biochemical assays to draw two main conclusions concerning this anti-repression activity: (1) after infection of a cro-constitutive cell, the superinfecting phage is unable to establish repression because it is unable to commence synthesis of cI protein (λ repressor) at a substantial rate; (2) the cause of this diminished synthesis of cI protein is the capacity of cro product to repress synthesis of the cII and cIII proteins, which normally activate the cI gene to establish repression in an infected cell. From our experiments and those of others, we suggest that cro product possesses a repression activity which is similar to that of the cI protein itself, but normally exerts a very different physiological role: the turnoff of synthesis of replication, recombination and regulation proteins as the virus enters the late stage of lytic development.     

Proposed alpha-helical super-secondary structure associated with protein-dna recognition

Knowledge of the three-dimensional structure of the bacteriophage λ Cro repressor, combined with an analysis of amino acid sequences and DNA coding sequences for this and other proteins that recognize and bind specific base sequences of double-helical DNA, suggests that a portion of the structure of the Cro repressor that is involved in DNA binding also occurs in the Cro protein from bacteriophage 434, the cII protein from bacteriophage λ, the Salmonella phage P22 c2 repressor and the cI repressor from bacteriophage λ. This α-helical super-secondary structure may be a common structural motif in proteins that bind double-helical DNA in a base sequence-specific manner.     

Repression by the cI protein of phage λ: in vitro inhibition of RNA synthesis

We have studied the in vitro repression of RNA synthesis by the cI protein of phage λ. We find that highly purified cI protein is an effective and specific repressor of RNA synthesis from the early gene region of λ DNA. Under optimal conditions at least 95% of the early gene RNA synthesis is repressed and this repression is eliminated or severely impaired by the use of λ DNA-carrying operator-type mutations which reduce the binding affinity of the cI protein. Highly effective repression can be demonstrated only through the use of the initiation-inhibitor rifampicin, which presumably, selects “properly” initiated RNA chains; thus we can by-pass in vitro but not yet solve the problem of how the host polymerase initiates specifically in vivo from the immediate-early promoter sites.     

An analysis of repressor overproduction by the lambda cIIIs mutant.

Efficient lysogenization of Escherichia coli K12 by bacteriophage λ requires the high level of synthesis of the phage repressor shortly after infection. This high level of synthesis of repressor requires the action of the λ eII and cIII proteins. Certain mutants of λ (λcIIIs) appear to have excess $\text{c}\text{II}\text{c}\text{III}$ activity and can lysogenize more efficiently than λ⁺. The basis for the enhanced lysogenization is that, while two or more infecting phage are necessary for λ⁺ to lysogenize, a single infecting λcIIIs particle is sufficient for lysogenization. Also, repressor levels in cells infected with λcIIIs are higher than in those infected with λ⁺. I report here that repressor overproduction by λcIIIs (1) is due to a much higher rate of repressor synthesis than that of λ⁺; (2) is most marked at low multiplicities of infection, possibly because λcIIIs produces repressor much more efficiently than λ⁺ as a singly infecting phage.     

Temperate Coliphage HK022: Clear Plaque Mutants and Preliminary Vegetative Map

Wild type phage HK022 was mutagenized by N-methyl-N′-nitro-N-nitrosoguanidine to induce clear plaque mutants. A total of 225 clear plaque mutants were isolated and 198 of these were assignable to one or the other of the two complementation groups of the corresponding cistrons which have been designated as cI and cII, respectively. Approximately 25% of the c mutants were found to be temperature-sensitive (cts); producing turbid plaques at 32 C and clear plaques at 38 C and above. From complementation tests involving cI and cII mutants, bacteria lysogenic for cII prophage were frequently obtained. Double lysogens harboring a cI and a cII prophage were infrequently found and single lysogens harboring only a cI prophage have not been recovered. Bacterial lysogens harboring a prophage carrying a cts mutation in the cI cistron were readily obtainable. However, such lysogens show a lethal phenotype at 40 C and above, although they appear to be fully viable at 32 C. It is shown that by incubation of lysogens harboring a cts mutant of the cI cistron at 42 C, it is possible to isolate cryptic lysogens which are non-immune but harbor at least one of the phage sus⁺ alleles. Genetic data involving cI, cII, and two complementing sus mutants of essential genes are presented. From these data the following vegetative map is deduced: sus4–cII-cI-sus3.     

Lambda CIN-1, a New Mutation Which Enhances Lysogenization by Bacteriophage Lambda, and the Genetic Structure of the Lambda CY Region

Seven lambda cy mutants have been mapped within a small region located approximately halfway between the rightward boundary of the imm⁴³⁴ region and the lambda cII gene. The seven mutants lie at four sites separated by a total distance of about 12 nucleotide pairs, as estimated from recombination frequencies. Six of the seven mutants lie on the right side of the cy fine structure map, spanning a total distance of about 3–5 nucleotide pairs. Lying approximately 11–21 nucleotide pairs to the left of the leftmost cy mutant is a newly described mutation called cin-1, for c independent. The cin-1 mutation allows some lysogenization when coupled with any cy, cII or cIII mutant, but not when coupled with a defective cI gene. The cin-1 mutation, like cy mutants, has a cis-dominant action upon the cI gene in mixed infections. The observation that λimm⁴³⁴ cin-1 cy2001 lysogenizes efficiently, but not λimm⁴³⁴ cin-1 cy2001 cII68 nor any other λimm⁴³⁴ cin-1 cy derivative, is interpreted to mean that all of the cy mutants on the right side of the cy fine structure map inactivate a binding site for cII/cIII function, but that cy2001, the single mutant on the left side of the cy fine structure map, does not inactivate that binding site.     

Kinetics of bacteriophage lambda repressor synthesis directed by the PRE promoter: influence of temperature, multiplicity of infection, and mutation of PRM or the cro gene

Summary Expression of the P _RE (establishment) pathway for repressor synthesis is regulated both by phage-specific genetic elements and by physiological conditions. Here we describe the effects of temperature, multiplicity of infection, mutations in the cro gene, and a mutation in P _RM on P _RE-directed repressor synthesis. As Reichardt (1975a) has shown, repressor synthesis begins 5–15 min after infection by wildtype phage, and is shut off at 20–30 min after infection, depending on the temperature. At 43°, synthesis starts sooner, shuts off earlier, and leads to lower repressor levels than are attained at lower temperatures. Experiments with the temperature sensitive mutant crots20 demonstrate that, as had been shown previously in experiments at 30° and 37° C, cro protein is responsible for the shut-off of repressor synthesis at 43°. In addition to the effects of temperature, the kinetics of repressor synthesis are strongly affected by multiplicity of infection (moi). At mois greater than 10, repressor synthesis after infection by wildtype at 30° is dramatically inhibited. Unexpectedly, the P _RM mutation prm116, under certain conditions, can alleviate both cro-mediated shutoff and the inhibition of P _RE-directed repressor synthesis at high moi. These effects of prm116 are observed only at low temperature (30°–32° C) and at mois of about 6–10 or greater; they also appear to be cis-specific. Possible mechanisms for the effects of the prm116 mutation are discussed. Finally, these studies demonstrate that crots20, which was isolated as a temperature-sensitive lethal mutation in the cro gene (Herskowitz, unpublished), is temperature-sensitive with respect to the ability to shutoff P _RE-directed repressor synthesis; however, even at low temperature (30° C), the crots20 gene product is only partially active.     

DNA packaging steps in bacteriophage lambda head assembly

Petit λ is an empty spherical shell of protein which appears wherever λ grows. If phage DNA and petit λ are added to a cell-free extract of induced lysogenic bacteria, then phage particles are formed that contain the DNA and protein from the petit λ. Petit λ is transformed, without dissociation, into a phage head by addition of DNA and more phage proteins.The products of ten genes, nine phage and one host, are required for λ head assembly. Among these, the products of four phage genes, E, B, C, and Nu3 and of the host gene groE are involved in the synthesis of petit λ, consequently these proteins are dispensable for head assembly in extracts to which petit λ has been added. The products of genes A and D allow DNA to combine with petit λ to form a head that has normal morphology. In an extract, DNA can react with A product and petit λ to become partially DNAase-resistant, as if an unstable DNA-filled intermediate were formed. ATP and spermidine are needed at this stage. This intermediate is subsequently stabilized by addition of D product. The data suggest a pathway for head assembly.     

Lambda phage cro repressor: Non-specific DNA binding

The interaction of lambda phage cro repressor with double-stranded non-specific DNA has been investigated by monitoring the quenching of its intrinsic tyrosyl fluorescence. The McGhee & von Hippel (1974) analysis of the binding of cro repressor to DNA showed that cro repressor undergoes structural variations in the ionic strength range from 0.04 to 0.18m-KCl. Under these salt conditions, the excluded binding site size of cro repressor on the DNA lattice changes from three to four base-pairs (6 to 8 nucleotides) at the lower ionic strengths, to seven to eight base-pairs (14 to 16 nucleotides) at the higher ionic strength. Quaternary structure variation, which does not cause the excluded site size variation, was also noted at low ionic strengths. Evidence is presented to indicate that cro repressor binds only one side of the DNA helix, such that cro repressor covers a stretch of 14 to 16 nucleotides along one side of the helix in the presence of 0.2 m-salt. Under conditions where the cro repressor structure is constant, approximately nine ion-pairs are formed in the cro repressor-non-specific DNA complex. These results are in agreement with the model proposed by Anderson et al. (1981).     

Bacterial Cell Division Regulation: Lysogenization of Conditional Cell Division lon− Mutants of Escherichia coli by Bacteriophage Lambda

The lon⁻ mutants of Escherichia coli grow apparently normally except that, after temporary periods of inhibition of deoxyribonucleic acid synthesis, septum formation is specifically inhibited. Under these conditions, long, multinucleate, nonseptate filaments result. The lon⁻ mutation also creates a defect such that wild-type bacteriophage λ fails to lysogenize lon⁻ mutants efficiently and consequently forms clear plaques on a lon⁻ host. Two lines of evidence suggest that this failure probably results from interference with expression of the λcI gene, which codes for repressor, or with repressor action:-(i) when a lon⁻ mutant was infected with a λcII, cIII, or c Y mutant, there was an additive effect between the lon⁻ mutation and the λc mutations upon reduction of lysogenization frequency; and (ii) lon⁻ mutants permitted the growth of the λcro⁻ mutant under conditions in which the repressor was active. The isolation of λ mutants (λtp) which gained the ability to form turbid plaques on lon⁻ cells is also reported.     

Gene N regulator function of phage λimm21: Evidence that a site of N action differs from a site of N recognition

We report the isolation and characterization of a new mutation in the hybrid phage λimm21. Both genetic and physiological studies demonstrate that this new mutation, N_21?1, is similar to N mutations of phage λ. As in the case of the N gene of λ (Ni_λ), the N_21?1 mutation maps immediately to the left of the cI gene and has a pleiotropic effect on the expression of phage functions. Although these studies strongly suggest that phage 21 has an N function, they do not definitely locate the N_21?1 mutation within the N₂₁ structural gene.Reported here are studies demonstrating that N₂₁ acts in trans, similar to N_λ, to stimulate the expression of phage functions. N products show an immunity specificity; N₂₁ being only active on phage carrying the immunity region of phage 21, while the n_λ is only active on phage carrying the immunity region of λ or phage 434. However, one site of action for N_λ can be rescued from phage 21. We propose that the specificity of an N function is determined by its sites of recognition and that these sites may be different from the sites of N action.