Properties of hybrids between Salmonella phage P22 and coliphage lambda

"N" transcription antitermination proteins of bacteriophages lambda, phi 21 and P22

Comparison is made among the amino acid sequences of three transcription antitermination proteins, based upon the DNA sequences of their genes in bacteriophages lambda, phi 21 and P22. The three proteins are all small (about 100 amino acids), hydrophilic and basic, but otherwise show little homology. A basic region near the amino terminus has several amino acid positions common to all three proteins and is the locus of mutations that alter six different amino acid positions inactivating the lambda N protein. A less basic region near the center is the locus of three mutations affecting the interaction of lambda N with host nusA protein. The N gene of phi 21 has an amino terminus more like that of P22, and a carboxy terminus clearly related to that of lambda.

Conservation of genome form but not sequence in the transcription antitermination determinants of bacteriophages lambda, phi 21 and P22

Comparisons are made among DNA sequences upstream from terminators in both leftwards and rightwards early operons of related coliphages lambda, phi 21 and P22. These sequences include both left and right determinants of response to phage-coded antitermination proteins, "N", as well as the N structural genes themselves. Despite almost total disparity of DNA sequence, the three genomes can be discerned to include the same elements in the same order and spacing: downstream from the early left promoter are sequentially a site of recognition for host nusA protein, a dyad symmetry "nut" essential for N function in lambda, overlapping sites for processing of the transcript by RNAase III and then the N structural genes; downstream from the cro gene on the right are sites of nusA recognition and nut dyad symmetries homologous to those on the left. Because the N proteins of lambda, phi 21 and P22 do not for the most part complement each other, a specific site of N recognition has been postulated for each N-responding operon. The nut dyad symmetry qualifies as such a site, since the loop of the left dyad in lambda is marked by mutations that block N function leftwards, and since DNA sequences here show close homology between the loops of left and right dyads for each phage, but less if not little homology for different phages.

Assembly-controlled autogenous modulation of bacteriophage P22 scaffolding protein gene expression

In the assembly of bacteriophage P22, precursor particles containing two major proteins, the gene 5 coat protein and the gene 8 scaffolding protein, package the DNA molecule. During the encapsidation reaction all of the scaffolding protein molecules are released intact and subsequently participate in further rounds of DNA encapsidation. We have previously shown that even though it lies in the center of the late region of the genetic map, the scaffolding protein gene is not always expressed coordinately with the remainder of the late proteins and that some feature of the phage assembly process affects its expression. We present here in vivo experiments which show that there is an inverse correlation between the amount of unassembled scaffolding protein and the rate of scaffolding protein synthesis and that long amber fragments of the scaffolding protein can turn down the synthesis of intact scaffolding protein in trans. These results support a model for scaffolding protein regulation in which the feature of the assembly process which modulates the rate of scaffolding protein synthesis is the amount of unassembled scaffolding protein itself.

Autoregulation of the bacteriophage P22 scaffolding protein gene

During the formation of each bacteriophage P22 head, about 250 molecules of the product of gene 8, scaffolding protein, coassemble with and dictate correct assembly of the coat protein into a proper shell structure. At approximately the time that DNA is inserted inside the coat protein shell, all of the scaffolding protein molecules leave the structure. They remain active and participate in several subsequent rounds of shell assembly. Previous work has shown that scaffolding protein gene expression is affected by the head assembly process and has generated the hypothesis that unassembled scaffolding protein negatively modulates the expression of its own gene but that it lacks this activity when complexed with coat protein in proheads. To test this model, a P22 restriction fragment containing the scaffolding and coat protein genes was cloned under control of the lac promoter. These cloned genes were then expressed in an in vitro DNA-dependent transcription-translation reaction. The addition of purified scaffolding protein to this reaction resulted in reduced scaffolding protein synthesis relative to coat and tail protein synthesis to an extent and at a protein concentration that was consistent with the observed reduction in vivo. We conclude that scaffolding protein synthesis is autoregulated and that scaffolding protein is the only phage-coded protein required for this process. In addition, these experiments provide additional evidence that this autoregulation is posttranscriptional.

Sequence analysis of a region from the early right operon in phage P22 including the replication genes 18 and 12

A comparison of a 3000-bp sequence of Salmonella phage P22, coding for gene c1 and the replication genes 18 and 12, with the analogous cII-O-P region of coliphage lambda permits the localization of transcriptional signals, an oop RNA species, and the origin of replication (ori) within gene 18. Gene c1 and the amino terminal region of gene 18 show homology to the respective lambda genes. In the ori domain of the replicator proteins the homology to phi 82 is most pronounced. Of two lambda:repP22 hybrids (lambda with replication genes of P22) analysed, one codes for a hybrid O/18 protein with 30 N-terminal amino acids coded for by lambda. Gene 12 is nonhomologous to its lambda counterpart (gene P), but closely related to dnaB of Escherichia coli. A ren gene is missing, whereas two open reading frames (ORFs) distal to gene 12 are almost identical to those in the lambda nin region. We try to account for the occurrence and location of highly conserved sequences among the lambdoid phages by assigning them a role in recombinational reassortment of functional units during the evolution of this phage family.

Evidence that a nucleotide sequence, "boxA," is involved in the action of the NusA protein

We report the isolation of a mutation, boxA1, in the nutR region of the phage lambda genome. The nutR region, located downstream of the pR promoter, includes the site nutR where the lambda N protein is thought to act to render subsequent transcription termination-resistant. We have previously suggested that the boxA sequence, 5'CGCTCTTA3' (or its RNA analog), located 8 bp promoter-proximal to nutR, might be the recognition site for the E. coli host factor, NusA, which has been shown to be necessary for N action. The boxA1 mutation, an A:T to T:A transversion, results in a changed boxA sequence upstream of nutR, CGCTCTTT. This change is necessary for lambda to effectively use the NusA of Salmonella typhimurium, a NusA function not normally active with the N product of lambda. Other lambdoid phages with unique N functions and nut sites that are normally active with the NusA of Salmonella have boxA sequences with the terminal three Ts. Moreover, sequences closely resembling boxA have been found near transcription termination sequences in E. coli operons where NusA has been shown to be involved in termination. These findings identify boxA as an important recognition signal for the NusA protein.

Homology among DNA-binding proteins suggests use of a conserved super-secondary structure

The amino acid sequences of the repressor and cro proteins of phages lambda, 434 and P22 are homologous, especially in a region in which repressor and lambda cro have a similar alpha-helix-turn-alpha-helix secondary structure. Model-building studies indicate that this structure is important in DNA binding, and we suggest it may be a common feature of many DNa-binding proteins.

MB78, a virulent bacteriophage of Salmonella typhimurium

The isolation and some properties of a virulent bacteriophage of Salmonella typhimurium, MB78, which is morphologically, serologically, and physiologically unrelated to P22, are reported. The phage has a noncontractile long tail with partite ends. It cannot multiply in minimal medium in the presence of citrate. MB78-infected cells are, however, killed in such medium. This phage cannot grow in rifampin-resistant mutants of the host. The latent period of growth of this phage is much shorter than that of P22. Both sieA and sieB genes of the resident P22 prophage are required to exclude the superinfecting MB78 phage, whereas all temperate phages related to P22 are excluded by either one or both of the genes individually. Restriction endonuclease cleavage patterns of P22 and MB78 are distinctly different. The absence of homology between the two phages P22 and MB78 suggests that MB78 is not related to phage P22.

Primary structure of the phage P22 repressor and its gene c2

The amino acid sequence of the Salmonella phage P2 repressor and the DNA sequence of its gene c2 have been determined. Sequential Edman degradations on intact P22 repressor and repressor peptides generated by proteolytic and chemical cleavages have been overlapped to give approximately 97% of the complete protein sequence. Additionally, the nucleotide sequence of the P22 c2 repressor gene has been determined by DNA sequencing techniques. The DNA sequence and partial protein sequence are collinear and together define the complete amino acid sequence of P22 repressor. The repressor is a single-chain 216 amino acid polypeptide. Basic residues in the sequence tend to be clustered, and residues 9-20 are highly basic, containing five arginyl and three lysyl residues. The carboxyl-terminal 133 amino acids of the c2 repressor are homologous to the carboxyl-terminal sequence of the coliphage lambda cI repressor. The amino-terminal sequences of these two repressors show little similarity.

Colinearity between the DNAs of Epstein-Barr virus and herpesvirus papio

Epstein Barr virus (EBV) and herpesvirus papio (HVPapio) DNAs share a common format and 40% homology. Labeled cloned fragments of EBV DNA were hybridized to blots of XbaI, EcoRI, HindIII, and SalI fragments of HVPapio DNA. EBV fragments which mapped from 2 x 10(6) to 54 x 10(6) and from 59 x 10(6) to 106 x 10(6) daltons hybridized to fragments at identical map positions in HVPapio DNA. Regions of nonhomology were demonstrated at 0 x 10(6) to 2 x 10(6), 54 x 10(6) to 59 10(6), and 106 x 10(6) to 115 x 10(6) daltons.

Host requirements for growth of lambda-P22 hybrid in Escherichia coli

The requirements for growth of bacteriophage lambda containing the deoxyribonucleic acid replication region from Salmonella phage P22 were determined in a burst size experiment. The products of genes dnaE, dnaJ, dnaK, dnaY, dnaZ, and seg were required, but not the products of genes dnaA, dnaB, dnaC, and dnaX. This lambda-P22 hybrid phage was also dependent on polA for growth at 32 degrees C.

Repression of ant synthesis early in the lytic cycle of phage P22

Using SDS-polyacrylamide gel electrophoresis to study the early expression of P22 genes we show that early expression of the ant-gene (imm I region) is turned off after 6-8 min, independent of the 'late' acting mnt-repressor. A semi-clear mutant called cir5 is defective for this early ant turn-off. The mutation cir5 maps in the imm I region of P22 between genes mnt and ant. P22 cir5 mutants are defective for a repressor which acts in trans to regulate early ant synthesis. There appears to be no absolute requirement of the cir5 allele for the establishment of lysogeny. The overproduction of ant in the P22 cir5 mutant leads to a marked increase in abortive infections, killing the infected cells. The cir5-phenotype can be suppressed by an ant- mutation.

lambda altSF: a phage variant that acquired the ability to substitute specific sets of genes at high frequency

We report the isolation of lambda altSF, a variant of Escherichia coli phage lambda that substitutes sets of genes at high frequency. Two forms of the variant phage have been studied: lambda altSF lambda, which exhibits the immunity (repressor recognition) of phage lambda, and lambda altSF22, which exhibits the immunity of Salmonella phage P22. Lysates made from single plaques of lambda altSF lambda contain 10-30% phage of the P22 form. Similarly, lysates from single plaques of lambda altSF22 contain as much as 1% phage of the lambda form. Heteroduplex analyses reveal the following features of the lambda altSF chromosomes: (i) each form has the immunity genes appropriate to its immune phenotype, (ii) the substituted segments include genes involved in regulation and replication, and (iii) the alt phages have unusual additions and substitutions of DNA not normally found associated with either immunity region. In the case of lambda altSF lambda, there is a small insertion in the region of the cI gene. Because revertants that lose this inserted DNA concomitantly lose the ability to substitute, we conclude that the insertion plays a role in the substitution process. In the case of change from lambda altSF lambda to lambda altSF22, the substituting P22 genes are derived from the E. coli host. We have identified a set of Salmonella phage P22 genes in a standard nonlysogenic strain of E. coli K-12 that is apparently carried in a silent form. The reason for this lack of expression is not obvious, because this P22 material includes structural genes and associated promoters and is potentially active. When this set of genes substitutes for the analogous set of genetic material on the genome of lambda altSF lambda, the P22 genes are expressed in a normal manner.

A theory of modular evolution for bacteriophages

The modular theory of virus evolution has clear experimental support among the temperate bacteriophages of the enteric bacteria. However, there is also similar genetic and DNA heteroduplex evidence for such evolution among other families of bacteriophages: the virulent bacteriophages of the enterics comprise several families: the T-even group, the T3-T7 group (which has many members among different species of bacteria, including bacteria as widely divergent as E. coli and Caulobacter crescentus. It nicely explains the diffusion of very similar homologous bacteriophages into hosts whose own DNAs have diverged very greatly from each other in nucleotide sequence. It also accounts for the rigorous maintenance of regulatory schemes while units of function (including regions coding for proteins) diverge more rapidly. It should also be noted that the considerations that make modular evolution seem advantageous for bacteriophages apply equally well to viruses of higher organisms. Furthermore, the kinds of heteroduplex similarity observed among animal viruses are reminiscent of what is found for bacteriophages. Viruses found in widely divergent hosts show much greater similarity than would be expected; quite possibly animal viruses also evolve as a population of interchangeable modules.

Induction of lambdoid prophages by amino acid deprivation: differential inducibility; role of recA

Lambda prophage in auxotrophic lysogens can be induced by omission of one or combinations of the required amino acids from the culture medium. Such amino acid deprivation can result in nearly as effective induction of lambda as thymine deprivation. Prophage 424 is also induced equally effectively under both conditions although to a lesser extent than lambda. By contrast prophage 21 and lambda i21 are differentially induced effectively by thymine deprivation and virtually not at all during amino acid deprivation. The same differential induction of 21 and equivalent induction of lambda and 424 occur when all three prophages are present in the same lysogen. Increasing the levels of lambda repressor with a cI carrying-plasmid prevented amino acidless induction of lambda as did the lambda ind- mutation. A recA, but not a recB, mutation in the host prevented induction by amino acid deprivation. A recC mutant host showed increased spontaneous induction of lambda and 21 prophages. The findings reported are used as an argument that the recA protease probably is not itself acting as the inducing protease and that a likely source of the observed specificity is an effector molecule. Different effector molecules may be produced in response to different exigent situations, to which the phage repressors may have evolved sensitivity. lambda i80 was inducible both by amino acid and thymine deprivation.

Growth of Salmonella bacteriophage P22 in Escherichia coli dna(Ts) mutants

Salmonella bacteriophage P22 grows in two deoxyribonucleic acid initiation mutants of Escherichia coli under nonpermissive conditions, dnaA and dnaC. Functional products of genes dnaE, dnaZ, lig, dnaK, and dnaG are indispensable for deoxyribonucleic acid replication of P22. In 11 E. coli dnaB mutants belonging to all phenotypic groups, phage were produced at 42 degrees C.

Conservation and variation of nucleotide sequences within related bacterial genomes: enterobacteria

We have assessed the degree of relatedness of several portions of the Escherichia coli genome to the corresponding portions of the genomes of representative enteric bacteria, using the Southern transfer and hybridization technique (E. Southern, J. Mol. Biol. 98:503-517, 1975). The degree of relatedness varied among the regions examined. Judging both by the relative amounts of deoxyribonucleic acid in the various enteric genomes that are highly homologous and by the conservation of positions of restriction enzyme cleavage sites in these regions, the enteric genomes have diverged to greater extents in some parts of the genomes than in others. Portions of the genomes (including the tnaA and thyA genes, the trp operon, and one other unassigned segment) appear to have evolved in concert with the genome as a whole. By contrast, the lacZ gene and portions of the genome that are homologous to phage lambda vary more widely, perhaps reflecting a separate evolutionary origin for these segments of deoxyribonucleic acid.

The site controlling the specificity of N action is outside the promoter-operator region: a triple hybrid phage lambda N21 imm434nin5

A short interval of homology between imm lambda, imm434 and imm21 DNAs was identified near the leftward promoter-operator region. This homology, denoted Hs, was revealed by electron microscopic examination of lambda imm lambda/lambda imm21 and lambda imm434/lambda imm21 heteroduplexes, and permitted us to construct a special lambda hybrid (lambda hyB) which contains the N region of phage 21 and the adjacent imm region from phage 434. This triple hybrid, labmda N21 imm434nin5, was analysed by genetic, transcriptional and electronic micrographic techniques. Its leftward and rightward promoter-operator regions are of phage 434 specificity and are controlled by the 434 repressor. Surprisingly, the N21 gene of lambda hyB was found to be defective, perhaps to preserve the viability of the hybrid. Its leftward N-recognition system (nutL) is of phage 21 specificity since it responds only to the N21 function in complementation tests, as measured by antitermination of leftward transcription initiated at the pL promotor in the imm434 region. We conclude, therefore, that the pLoL region of 434 contains no information for the specificity of N antitermination. Both lambda imm21 and lambda hyB were found to be missing the tL1 terminator function (see also Salstrom and Szybalski, 1978b). In these phages, the tL2 terminator was found to be only 60% effective under N21 conditions, and therefore expression of their red-gam genes is sufficient to endow the lambda hyB and lambda N21- imm21nin5 phages with the Fec+ phenotype.

The activity of ant product of the Salmonella phage P22 against the closely related but heteroimmune phage L

P22 mutants defective in the early gene 24 are complemented by phage L in mixed infection. P22 12- and P22 23- mutants are not complemented by phage L. Gene function 24 of an L prophage is turned on by a superinfecting P22 24- mutant and complements the missing function of the defective P22 phage. Since this transactivation of prophage gene 24 depends on a functional gene ant in the superinfecting P22 mutant, it indicates derepression for leftward directed gene expression in prophage L. On the contrary neither the rightward directed expression of gene 12 nor of gene 23 in prophage L. can be turned on by superinfecting P22 24- 12- or P22 24- 23- mutants (and also not by P22 12- and P22 23-) to a degree sufficient for complementation of simultaneously superinfecting L virB 12- or L virB 23- mutants. The failure to detect release of repression for rightward directed gene expression of prophage L corresponds to the earlier observation (Prell, 1975) that P22 superinfecting L lysogens cannot release replication inhibition for simultaneously infecting phage L. The results are discussed with respect to the mechanism underlying the different action of P22 antirepressor in L and in P22 lysogens.

Purification and properties of phage P22 c2 repressor

The c2 repressor of phage P22 has been purified to homogeneity. It specifically binds to lambdaimm21 and P22 DNA. Its affinity for the presumed operator mutant P22 virB is reduced. The initial dissociation rates of the complex between c2 repressor and lambdaimm21 DNA are 0.02 min-1 at 0 degrees C, 0.08 min-1 at 20 degrees C and 0.17 min-1 at 32 degrees C. The dissociation rates of complexes formed between the c2 repressor and the lambdaimm21 operators OR, OL and OR vira were measured and compared to the corresponding rates obtained with 21 cI repressor.

Genetic studies of hybrids between coliphage lambda and salmonella phage P22: genetic analysis of the P22-lambda hybrid class

P22-lambda hybrids which retain the protein coat of P22 have been isolated and characterized into two types. Type 1 hybrids which have the c through O-P genes of lambda are unable to grow lytically on Salmonella typhimurium. On the other hand, type 2 hybrids which contain only the c region of lambda, plated on S. typhimurium. Both hybrid types retained the generalized transducing and antigenic conversion capabilities of P22.