Lethal action of bacteriophage lambda S gene.

The functions of the bacteriophage lambda lysis genes S, R, and Rz were investigated. Different combinations of wild-type and inactive alleles of all three lysis genes were cloned into the plasmid pBH20 and were expressed under the control of a lac operator-promoter. The involvement of the Rz gene in lysis was proposed in our previous work and was confirmed by the Mg2+-dependent lysis defect of clones in which part of the Rz gene is deleted. Membrane vesicles prepared from induced S+ cells were shown to have a severely reduced capacity for active transport of glucose; this defect was detectable at least 20 min before lysis. Cell viability was also shown to decrease very soon after induction, long before physiological death and lysis; this decrease in viability is absolutely dependent on S expression and independent of R and Rz. The nonviable fraction of cells at any time after induction was demonstrated to be equal to the fraction committed to eventual lysis. Induction of an Sts clone showed that the S gene product is stable and capable of inducing lysis long after the cessation of synthesis of S gene product. A model for S action is proposed.     

Facile and gentle method for quantitative lysis of Escherichia coli and Salmonella typhimurium

Garrett et al. (Mol. Gen. Genet. 182:326-331, 1981) constructed strains of Escherichia coli harboring derivatives of plasmid pBR322 that carry the lysis genes (S, R, and Rz) of phage lambda. The plasmid construction placed the genes under control of the lactose operon operator-promotor (and thus of lac repressor). Induction of E. coli strains carrying these plasmids resulted in rapid lysis of the culture unless the S gene was defective, in which case the cells grew normally. A freeze-thaw treatment of induced cells carrying an S- plasmid gave quantitative lysis of either E. coli or Salmonella typhimurium cells under exceptionally gentle conditions. The method was equally effective on exponential phase cells and stationary phase cells and was readily extended to a large number of independent cultures.     

Three functions of bacteriophage P1 involved in cell lysis.

Amber and deletion mutants were used to assign functions in cell lysis to three late genes of bacteriophage P1. Two of these genes, lydA and lydB of the dar operon, are 330 and 444 bp in length, respectively, with the stop codon of lydA overlapping the start codon of lydB. The third, gene 17, is 558 bp in length and is located in an otherwise uncharacterized operon. A search with the predicted amino acid sequence of LydA for secondary motifs revealed a holin protein-like structure. Comparison of the deduced amino acid sequence of gene 17 with sequences of proteins in the SwissProt database revealed homologies with the proteins of the T4 lysozyme family. The sequence of lydB is novel and exhibited no known extended homology. To study the effect of gp17, LydA, and LydB in vivo, their genes were cloned in a single operon under the control of the inducible T7 promoter, resulting in plasmid pAW1440. A second plasmid, pAW1442, is identical to pAW1440 but has lydB deleted. Induction of the T7 promoter resulted in a rapid lysis of cells harboring pAW1442. In contrast, cells harboring pAW1440 revealed only a small decrease in optical density at 600 nm compared with cells harboring vector alone. The rapid lysis phenotype in the absence of active LydB suggests that this novel protein might be an antagonist of the holin LydA.     

The lysis function of RNA bacteriophage Qbeta is mediated by the maturation (A2) protein

Complete or partial cDNA sequences of the RNA bacteriophage Qbeta were cloned in plasmids under the control of the lambdaP(L) promoter to allow regulated expression in Escherichia coli harbouring the gene for the temperature-sensitive lambdaCI857 repressor. Induction of the complete Qbeta sequence leads to a 100-fold increase in phage production, accompanied by cell lysis. Induction of the 5'-terminal sequence containing the intact maturation protein (A2) cistron also causes cell lysis. Alterations of the A2 cistron, leading to proteins either devoid of approximately 20% of the C-terminal region or of six internal amino acids, abolish the lysis function. Expression of other cistrons in addition to the A2 cistron does not enhance host lysis. Thus, in Qbeta, the A2 protein, in addition to its functions as maturation protein, appears to trigger cell lysis. This contrasts with the situation in the distantly related group I RNA phages such as f2 and MS2 where a small lysis polypeptide is coded for by a region overlapping the end of the coat gene and the beginning of the replicase gene.     

The immunity and lysis genes of ColN plasmid pCHAP4

Summary Nucleotide sequencing of part of the plasmid pCHAP4, which encodes the ca. 42000 Da putative poreforming colicin N, confirmed previous results indicating that the colicin N immunity gene (cni) and the colicin release or lysis gene (cnl) are located immediately downstream from the colicin N structural gene (cna) in the order cna-cni-cnl. The cni gene is transcribed in the opposite direction to cna and probably encodes an M_r 15239 Da protein. The putative immunity protein was detected among the [³⁵S]methionine-labelled proteins produced by minicells carrying cni cloned under lac promoter control, and when the gene was subcloned into expression vectors under the control of a bacteriophage T7 promoter. Deletion of the region immediately upstream from cni completely abolished colicin N immunity, presumably because the natural promoter had been deleted. cnl is in the same operon as cna, and encodes a typical Col plasmid pro-lysis protein comprising a signal peptide and a 34 residue mature polypeptide with high homology to all but one of the other known Col lysis proteins, including the fatty acylated amino-terminal cysteine residue which was specifically labelled with ³H-palmitate. Cell fractionation studies indicated that the cnl gene product was located predominantly in the outer membrane.     

Requirement for a functional host cell autolytic enzyme system for lysis of Escherichia coli by bacteriophage phi X174

Escherichia coli VC30 is a temperature-sensitive mutant which is defective in autolysis. Strain VC30 lyses at 30 degrees C when treated with beta-lactam antibiotics or D-cycloserine or when deprived of diaminiopimelic acid. The same treatments inhibit growth of the mutant at 42 degrees C but do not cause lysis. Strain VC30 was used here to investigate the mechanism of host cell lysis induced by bacteriophage phi X 174. Strain VC30 was transformed with plasmid pUH12, which carries the cloned lysis gene (gene E) of phage phi X174 under the control of the lac operator-promoter, and with plasmid pMC7, which encodes the lac repressor to keep the E gene silent. Infection of strain VC30(pUH12)(pMC7) with phage phi X174 culminated in lysis at 30 degrees C. At 42 degrees C, intracellular phage development was normal, but lysis did not occur unless a temperature downshift to 30 degrees C was imposed. Similarly, induction of the cloned phi X174 gene E with isopropyl-beta-D-thiogalactoside resulted in lysis at 30 degrees C but not at 42 degrees C. Temperature downshift of the induced culture to 30 degrees C resulted in lysis even in the presence of chloramphenicol. These results indicate that host cell lysis by phage phi X174 is dependent on a functional cellular autolytic enzyme system.     

Versatile cloning vectors derived from the runaway-replication plasmid pKN402

Two cloning vectors have been constructed employing runaway-replication mutants of plasmid R1. One of these, pMOB45, carries tetracycline and chloramphenicol resistance. The other, pMOB48, carries chloramphenicol resistance, lacOP, and an assayable part of the lacPOZ operon. Both of these plasmids can be amplified to high levels by heat induction, which condition does not lead to inhibition of protein synthesis; thus the plasmid can produce large amounts of DNA and protein. In pMOB48, a unique BamHI site is present near the amino-terminus of the beta-galactosidase gene. Chimeras formed by the insertion of restriction fragments at this site can be detected on X-gal plates, and can be used for the lacIq-controlled expression of proteins which are fused to the amino-terminus of beta-galactosidase. Induction with IPTG at 40 degrees C leads to the synthesis of extremely high levels of proteins whose gene have been cloned into this site.     

Phi X174 E complements lambda S and R dysfunction for host cell lysis.

Hybrid lambda phages which have the E lysis gene of the bacteriophage phi X174 in cis to defective nonsense and deletion alleles of the normal lambda lysis genes S and R have been constructed and shown to be fully competent for plaque-forming ability, which demonstrates that the single-gene, lysozyme-independent lysis system of phi X174 and related phages can serve the lytic function for large complex phages. These hybrid phages are unable to form plaques on a slyD host. Moreover, plaque morphology indicates that in E-mediated lysis the soluble lambda R endolysin can participate in lysis, indicating that the protein E-mediated lesions are not completely sealed off from the periplasm.     

Dual start motif in two lambdoid S genes unrelated to lambda S

The lysis gene region of phage 21 contains three overlapping reading frames, designated S21, R21, and Rz21 on the basis of the analogy with the SRRz gene cluster of phage lambda. The 71-codon S21 gene complements lambda Sam7 for lysis function but shows no detectable homology with S lambda in the amino acid or nucleotide sequence. A highly related DNA sequence from the bacteriophage PA-2 was found by computer search of the GenBank data base. Correction of this sequence by insertion of a single base revealed another 71-codon reading frame, which is accordingly designated the SPA-2 gene and is 85% identical to S21. There are thus two unrelated classes of S genes; class I, consisting of the homologous 107-codon S lambda and 108-codon P22 gene 13, and class II, consisting of the 71-codon S21 and SPA-2 genes. The codon sequence Met-Lys-(X)-Met...begins all four genes. The two Met codons in S lambda and 13 have been shown to serve as translational starts for distinct polypeptide products which have opposing functions: the shorter polypeptide serves as the lethal lysis effector, whereas the longer polypeptide acts as a lysis inhibitor. To test whether this same system exists in the class II S genes, the Met-I and Met-4 codons of S21 were altered in inducible plasmid clones and the resultant lysis profiles were monitored. Elimination of the Met-1 start results in increased toxicity, and lysis, although not complete, begins earlier, which suggests that both starts are used in the scheduling of lysis by S21 and is consistent with the idea that the 71- and 68-residue products act as a lysis inhibitor and a lysis effector, respectively. In addition, the R gene of 21 was shown to be related to P22 gene 19, which encodes a true lysozyme activity, and was also found to be nearly identical to PA-2 ORF2. We infer that the 21 and PA-2 R genes both encode lysozymes in the T4 e gene family. These three genes form a second class lambdoid R genes, with the lambda R gene being the sole member of the first class. The existence of two interchangeable but unrelated classes of S genes and R genes is discussed in terms of a model of bacteriophage evolution in which the individual gene is the unit of evolution.     

Inducible cell lysis system for the study of natural transformation and environmental fate of DNA released by cell death.

Two novel conditional broad-host-range cell lysis systems have been developed for the study of natural transformation in bacteria and the environmental fate of DNA released by cell death. Plasmid pDKL02 consists of lysis genes S, R, and Rz from bacteriophage lambda under the control of the Ptac promoter. The addition of inducer to Escherichia coli, Acinetobacter calcoaceticus, or Pseudomonas stutzeri containing plasmid pDKL02 resulted in cell lysis coincident with the release of high amounts of nucleic acids into the surrounding medium. The utility of this lysis system for the study of natural transformation with DNA released from lysed cells was assessed with differentially marked but otherwise isogenic donor-recipient pairs of P. stutzeri JM300 and A. calcoaceticus BD4. Transformation frequencies obtained with lysis-released DNA and DNA purified by conventional methods and assessed by the use of antibiotic resistance (P. stutzeri) or amino acid prototrophy (A. calcoaceticus) for markers were comparable. A second cell lysis plasmid, pDKL01, contains the lysis gene E from bacteriophage phi X174 and causes lysis of E. coli and P. stutzeri bacteria by activating cellular autolysins. Whereas DNA released from pDKL02-containing bacteria persists in the culture broth for days, that from induced pDKL01-containing bacteria is degraded immediately after release. The lysis system involving pDKL02 is thus useful for the study of both the fate of DNA released naturally into the environment by dead cells and gene transfer by natural transformation in the environment in that biochemically unmanipulated DNA containing defined sequences and coding for selective phenotypes can be released into a selected environment at a specific time point. This will allow kinetic measurements that will answer some of the current ecological questions about the fate and biological potential of environmental DNA to be made.     

Evaluation of the interaction of phi X174 gene products E and K in E-mediated lysis of Escherichia coli.

Gene K of bacteriophage phi X174 was cloned, and its gene product was localized in the cell envelope of Escherichia coli. Compared with the sole expression of the phi X174 lysis gene E, the simultaneous expression of the K and E genes had no effect on scheduling of cell lysis. Therefore, a direct interaction of proteins E and K could be excluded. In contrast, phi X174 infection of a host carrying a plasmid expressing gene K resulted in a delayed lysis and an apparent increase in phage titer.     

Mutational analysis of bacteriophage lambda lysis gene S

A plasmid carrying the bacteriophage lambda lysis genes under lac control was subjected to hydroxylamine mutagenesis, and mutations eliminating the host lethality of the S gene were selected. DNA sequence analysis revealed 48 single-base mutations which resulted in alterations within the coding sequence of the S gene. Thirty-three different missense alleles were generated. Most of the missense changes clustered in the first two-thirds of the molecule from the N terminus. A simple model for the disposition of the S protein within the inner membrane can be derived from inspection of the primary sequence. In the first 60 residues, there are two distinct stretches of predominantly hydrophobic amino acids, each region having a net neutral charge and extending for at least 20 residues. These regions resemble canonical membrane-spanning domains. In the model, the two domains span the bilayer as a pair of net neutral charge helices, and the N-terminal 10 to 12 residues extend into the periplasm. The mutational pattern is largely consistent with the model. Charge changes within the putative imbedded regions render the protein nonfunctional. Loss of glycine residues at crucial reverse-turn domains which would be required to reorient the molecule to reenter the membrane also inactivate the molecule. Finally, a number of neutral and rather subtle mutations such as Ala to Val and Met to Ile are found, mostly within the putative spanning regions. Although no obvious explanation exists for this subtle and heterogeneous class of mutations, it is noted that all of the changes result in a loss of alpha-helical character as predicted by Chou-Fasman theoretical analysis. Alternative explanations for some of these changes are also possible, including a reduction in net translation rate due to substitution of a rare codon for a common one. The model and the pattern of mutations have implications for the probable oligomerization of the S protein at the time of endolysin release at the end of the vegetative growth period.     

Genetic and physiological control of host cell lysis by bacteriophage lambda.

The timing of host cell lysis at the end of the lytic cycle of phage lambda is under complex control. The lambda S protein stimulates lysis. Another physiological system, the lysis regulator, inhibitis lysis from occurring prematurely. The effects of a series of phage and bacterial mutations on these controls are described. They show that the lambda rex gene plays a role in regulating lysis under suboptimal growth conditions. In certain mutant cells, and especially under anaerobic culture conditions, the rex gene aids in the scheduling of host cell lysis. The data also suggest that the lysis regulator may control the transition of the lambda S protein from an inactive to an active state.