Genetic studies of coliphage P1. I. Mapping by use of prophage deletions

Haemophilus influenzae HP1 Bacteriophage Encodes a Lytic Cassette with a Pinholin and a Signal-Arrest-Release Endolysin

HP1 is a temperate bacteriophage, belonging to the Myoviridae family and infecting Haemophilus influenzae Rd. By in silico analysis and molecular cloning, we characterized lys and hol gene products, present in the previously proposed lytic module of HP1 phage. The amino acid sequence of the lys gene product revealed the presence of signal-arrest-release (SAR) and muraminidase domains, characteristic for some endolysins. HP1 endolysin was able to induce lysis on its own when cloned and expressed in Escherichia coli, but the new phage release from infected H. influenzae cells was suppressed by inhibition of the secretion (sec) pathway. Protein encoded by hol gene is a transmembrane protein, with unusual C-out and N-in topology, when overexpressed/activated. Its overexpression in E. coli did not allow the formation of large pores (lack of leakage of β-galactosidase), but caused cell death (decrease in viable cell count) without lysis (turbidity remained constant). These data suggest that lys gene encodes a SAR-endolysin and that the hol gene product is a pinholin. HP1 SAR-endolysin is responsible for cell lysis and HP1 pinholin seems to regulate the cell lysis and the phage progeny release from H. influenzae cells, as new phage release from the natural host was inhibited by deletion of the hol gene.

Phage lysis: three steps, three choices, one outcome

The lysis of bacterial hosts by double-strand DNA bacteriophages, once thought to reflect merely the accumulation of sufficient lysozyme activity during the infection cycle, has been revealed to recently been revealed to be a carefully regulated and temporally scheduled process. For phages of Gramnegative hosts, there are three steps, corresponding to subversion of each of the three layers of the cell envelope: inner membrane, peptidoglycan, and outer membrane. The pathway is controlled at the level of the cytoplasmic membrane. In canonical lysis, a phage encoded protein, the holin, accumulates harmlessly in the cytoplasmic membrane until triggering at an allele-specific time to form micron-scale holes. This allows the soluble endolysin to escape from the cytoplasm to degrade the peptidoglycan. Recently a parallel pathway has been elucidated in which a different type of holin, the pinholin, which, instead of triggering to form large holes, triggers to form small, heptameric channels that serve to depolarize the membrane. Pinholins are associated with SAR endolysins, which accumulate in the periplasm as inactive, membrane-tethered enzymes. Pinholin triggering collapses the proton motive force, allowing the SAR endolysins to refold to an active form and attack the peptidoglycan. Surprisingly, a third step, the disruption of the outer membrane is also required. This is usually achieved by a spanin complex, consisting of a small outer membrane lipoprotein and an integral cytoplasmic membrane protein, designated as o-spanin and i-spanin, respectively. Without spanin function, lysis is blocked and progeny virions are trapped in dead spherical cells, suggesting that the outer membrane has considerable tensile strength. In addition to two-component spanins, there are some single-component spanins, or u-spanins, that have an N-terminal outer-membrane lipoprotein signal and a C-terminal transmembrane domain. A possible mechanism for spanin function to disrupt the outer membrane is to catalyze fusion of the inner and outer membranes.

Mutations in coliphage p1 affecting host cell lysis

A total of 103 amber mutants of coliphage P1 were tested for lysis of nonpermissive cells. Of these, 83 caused cell lysis at the normal lysis time and have defects in particle morphogenesis. Five amber mutants, with mutations in the same gene (gene 2), caused premature lysis and may have a defect in a lysis regulator. Fifteen amber mutants were unable to cause cell lysis. Artificially lysed cells infected with five of these mutants produced viable phage particles, and phage particles were seen in thin sections of unlysed, infected cells. However, phage production by these mutants was not continued after the normal lysis time. We conclude that the defect of these five mutants is in a lysis function. The five mutations were found to be in the same gene (designated gene 17). The remaining 10 amber mutants, whose mutations were found to be in the same gene (gene 10), were also unable to cause cell lysis. They differed from those in gene 17 in that no viable phage particles were produced from artificially lysed cells, and no phage particles were seen in thin sections of unlysed, infected cells. We conclude that the gene 10 mutants cannot synthesize late proteins, and it is possible that gene 10 may code for a regulator of late gene expression for P1.

Sequence, Transcription Activity, and Evolutionary Origin of the R-BodyCoding Plasmid pKAP298 from the Intracellular Parasitic BacteriumCaedibacter taeniospiralis

We isolated the intracellular parasitic bacterium Caedibacter taeniospiralis from cultures of the freshwater ciliate Paramecium tetraurelia strain 298. Plasmid pKAP298 as well as the total RNA were isolated from the bacteria. pKAP298 was totally sequenced (49.1 kb; NCBI accession number AY422720). From southern blots of pKAP-fragments and Digoxigenin-labeled cDNA of the Caedibacter-RNA, we generated transcription maps of pKAP298. The observed transcription activity indicated functions of the plasmid besides the synthesis of the R-body, a complex protein inclusion associated with toxic effects of Caedibacter cells on host paramecia. We identified 63 potential protein coding regions on pKAP298, and a novel transposon as well as known transposons were characterized. A group II intron was identified. Homologies with putative phage genes were detected on pKAP298 that direct to the evolution of pKAP298 from a bacteriophage. This original phage most probably belonged to the Caudovirales. Hints on a toxin coding region of pKAP298 are given: a protein with homology to the Soj-/ParA-family also has homologies to a membrane associated ATPase, which is involved in eukaryotic ATPase dependent ion carriers and may be associated with toxic effects on paramecia ingesting this protein.

Second-site suppressors of the bacteriophage P1 virs mutant reveal the interdependence of the c4, icd, and ant genes in the P1 immI operon

The immI operon of phage P1 contains the genes c4, icd, and ant, which are transcribed in that order from the same constitutive promoter, P51b. The gene c4 encodes an antisense RNA which inhibits the synthesis of an antirepressor by acting on a target ant mRNA. Interaction depends on the complementarity of two pairs of short sequences encompassing virs+ and the ribosome-binding site involved in ant expression. Accordingly, in a P1 virs mutant phage, antirepressor is synthesized constitutively. We have isolated lysogen-proficient, second-site suppressors of P1 virs in order to evaluate the interdependence of the immI-specific genes. From a total of 17 suppressors analyzed, 15 were found to be located in the icd gene. They were identified as frameshift mutations, containing base insertions or deletions in tandem repeats of a single base pair. One suppressor was identified as a P51b promoter-down mutation; the second site of another suppressor was found to be located in the c4 gene. Furthermore, it was shown that virs cannot be suppressed by ant (icd+) suppressors. The results confirm the model that the immI operon is transcribed as a unit, that the icd and ant genes are translationally coupled, and that the constitutive synthesis of Icd protein alone is lethal to the bacterial cell. The existence of a c4 suppressor of virs, whose effect is not yet known, points to a still more complex regulation of antirepressor synthesis than was anticipated from the model.

Bacteriophage P1 genes involved in the recognition and cleavage of the phage packaging site (pac)

The packaging of bacteriophage P1 DNA is initiated by cleavage of the viral DNA at a specific site, designated pac. The proteins necessary for that cleavage, and the genes that encode those proteins, are described in this report. By sequencing wild-type P1 DNA and DNA derived from various P1 amber mutants that are deficient in pac cleavage, two distinct genes, referred to as pacA and pacB, were identified. These genes appear to be coordinately transcribed with an upstream P1 gene that encodes a regulator of late P1 gene expression (gene 10). pacA is located upstream from pacB and contains the 161 base-pair pac cleavage site. The predicted sizes of the PacA and PacB proteins are 45 kDa and 56 kDa, respectively. These proteins have been identified on SDS-polyacrylamide gels using extracts derived from Escherichia coli cells that express these genes under the control of a bacteriophage T7 promoter. Extracts prepared from cells expressing both PacA and PacB are proficient for site-specific cleavage of the P1 packaging site, whereas those lacking either protein are not. However, the two defective extracts can complement each other to restore functional pac cleavage activity. Thus, PacA and PacB are two essential bacteriophage proteins required for recognition and cleavage of the P1 packaging site. PacB extracts also contain a second P1 protein that is encoded within the pacB gene. We have identified this protein on SDS-polyacrylamide gels and have shown that it is translated in the same reading frame as is PacB. Its role, if any, in pac cleavage is yet to be determined.

The c4 repressors of bacteriophages P1 and P7 are antisense RNAs

The c4 repressors of P1 and P7 inhibit antirepressor synthesis and are solely responsible for heteroimmunity of the phages. We show that c4 is a new type of antisense RNA acting on a target, ant mRNA, that is transcribed from the same promoter. Interaction depends on complementarity of two pairs of short sequences encompassing the ribosome binding site involved in ant expression. We demonstrate that heteroimmunity of P1 and P7 is due to just two substitutions in each of the complementary sequences of c4 and ant mRNA. Based on P1-P7 sequence comparison and a mutant analysis, we propose a secondary structure model for c4 RNA, with the complementary regions in loops as important sites for antisense control.

Organization of the immunity region immI of bacteriophage P1 and synthesis of the P1 antirepressor

The immI region of bacteriophage P1 includes the ant/reb gene, which encodes the antirepressor protein, and the c4 gene, which encodes a repressor molecule that negatively regulates antirepressor synthesis. The antirepressor interferes with the activity of the P1 repressor of lytic function, the product of the c1 gene. We have determined the DNA sequences of the immI region of P1 wild-type and the mutants virs, ant16, ant17, and reb22. Using suitable P1 immI DNA subfragments cloned into a vector of the T7 bacteriophage RNA polymerase expression system the antirepressor protein(s) was overproduced. On the basis of positions of immI mutations and the sizes of ant gene products, the following organizational feature of the P1 immI region is suggested: (1) the genes c4 and ant are cotranscribed in that order from the same promoter in the clockwise direction of the P1 genetic map; (2) an open reading frame for an unknown gene is located in between c4 and ant; (3) the site at which the c4 repressor acts is located within the c4 structural gene; (4) two antirepressor proteins of molecular weights 42,000 and 32,000 are encoded by a single open reading frame, with the smaller protein initiating at an in-frame start codon; (5) transcription of immI is regulated via a c1-controlled operator, Op51, indicating a communication between the immunity systems immC and immI.

Recognition and cleavage of the bacteriophage P1 packaging site (pac). I. Differential processing of the cleaved ends in vivo

The packaging of bacteriophage P1 DNA into viral capsids is initiated at a specific DNA site called pac. During packaging, that site is cleaved and at least one of the resulting ends is encapsidated into a P1 virion. We show here that pac is located on a 620 base-pair fragment of P1 DNA (EcoRI-20). When that fragment is inserted into the chromosome of cells that are then infected with P1, packaging of host DNA into phage particles is initiated at pac and proceeds down the chromosome, unidirectionally, for about five to ten P1 "headfuls" (about 5 X 10(5) to 10 X 10(5) bases of DNA). Using an assay for pac cleavage that does not depend on DNA packaging, we have identified a set of five amber mutations that are mapped adjacent to pac, and that define a gene (gene 9) essential for pac cleavage. Amber mutations that are located in genes necessary for viral capsid formation (genes 4, 8 and 23), or in a gene necessary for "late" protein synthesis (gene 10), do not affect pac cleavage. The latter result suggests that the synthesis of the pac cleavage protein is not regulated co-ordinately with other phage morphogenesis proteins. The products of pac cleavage were analyzed using two different DNA substrates. In one case, a single copy of pac was placed in the chromosome of P1-sensitive cells. When those cells were infected with P1, we could detect the cleavage of as much as 70% of the pac-containing DNA. The pac end destined to be packaged in the virion was detected five to 20 times more efficiently than was the other end. Since this result is obtained whether or not the infecting P1 phage can encapsidate the cut pac site, the differential detection of pac ends is not simply a consequence of one end being packaged and the other not. In a second case, pac was located in cells on a small (5 X 10(3) bases) multicopy plasmid. When those cells were infected with P1, neither pac end was detected efficiently after P1 infection, unless the cells carried a recBCD- mutation. In recBCD- cells, the results with plasmid-pac substrates were similar to those obtained with chromosomally integrated pac substrates. We interpret these results to mean that, following pac cleavage, the end destined to be packaged is protected from cellular nucleases while the other end is degraded by the action of at least two nucleases, one of which is the product of the host recBCD gene.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression and proteolytic processing of the darA antirestriction gene product of bacteriophage P1

The darA gene coding for one of the two bacteriophage P1 antirestriction functions is expressed late after infection or induction. The protein is made as a high-molecular-weight soluble precursor. This is proteolytically cleaved to the mature form, which is a structural component of the phage head. Defective mutants of the phage have been found in which the synthesis of gpdarA is normal but processing does not take place. These mutations all map to the same region of the P1 genome and we propose that they lie in the structural gene for the processing protease.

Regulation of the ban gene containing operon of prophage P1

A physical map of the ban gene of P1 and sites relevant to its regulation has been deduced from cloning of the appropriate regions of P1 wild-type and of P1 ban regulatory mutants. The cloning required the presence of P1 repressor in the cell confirming the existence of a repressible ban operon (Austin et al. 1978). Evidence for additional member(s) of that operon is presented. Of particular interest for understanding the regulation of ban are the relative positions of a binding site for the P1 repressor and of the regulatory mutations bac and crr that render ban expression constitutive. The results reveal a repressible operon-like structure of about 4 kb within the P1 EcoRI-3 fragment that comprises a c1 repressor binding site/bac - additional gene(s) - crr/ban in the clockwise direction of the circular map of P1.

IS30, a new insertion sequence of Escherichia coli K12

Three independent spontaneous mutations of prophage P1 affecting the ability of the phage to reproduce vegetatively are due to the insertion of a mobile genetic element, called IS30. The same sequence is also carried in the R plasmid NR 1-Basel, but not in the parental plasmid NR 1. Southern hybridisation study indicates that the Escherichia coli K 12 chromosome carries several copies of IS30 as a normal resident. IS30 is 1.2 kb long and contains unique restriction cleavage sites for BglII, ClaI, HindIII, NciI and HincII, and it is cleaved twice by the enzymes HpaII and TaqI. The ends of IS30 are formed by 26 bp long inverted repeats with 3 bases mismatched. Upon transposition IS30 generates a duplication of only 2 bp of the target. The following observations suggest a pronounced specificity in target selection by IS30. In transposition to the phage P1 genome a single integration site was used three times independently, and in both orientations. A short region of sequence homology has been identified between the P1 and NR 1-Basel insertion sites. IS30 has mediated cointegration as well as deletion. The entire IS30 sequences were duplicated in the cointegrates between a pBR322 derivative containing IS30 and the genome of phage P1-15, and several loci on the P1-15 genome served as fusion sites, some of which were used more than once.

Coliphage P1 morphogenesis: analysis of mutants by electron microscopy

We used electron microscopy and serum blocking power tests to determine the phenotypes of 47 phage P1 amber mutants that have defects in particle morphogenesis. Eleven mutants showed head defects, 30 showed tail defects, and 6 had a defect in particle maturation (which could be either in the head or in the tail). Consideration of previous complementation test results, genetic and physical positions of the mutations, and phenotypes of the mutants allowed assignment of most of the 47 mutations to genes. Thus, a minimum of 12 tail genes, 4 head genes, and 1 particle maturation gene are now known for P1. Of the 12 tail genes, 1 (gene 19, located within the invertible C loop) codes for tail fibers, 6 (genes 3, 5, 16, 20, 21, and 26) code for baseplate components (although one of these genes could code for the tail tube), 1 (gene 22) codes for the sheath, 1 (gene 6) affects tail length, 2 (genes 7 and 25) are involved in tail stability, and 1 (gene 24) either codes for a baseplate component or is involved in tail stability. Of the four head genes, gene 9 codes for a protein required for DNA packaging. The function of head gene 4 is unclear. Head gene 8 probably codes for a minor head protein, whereas head gene 23 could code for either a minor head protein or the major head protein. Excluding the particle maturation gene (gene 1), the 12 tail genes are clustered in three regions of the P1 physical genome. The four head genes are at four separate locations. However, some P1 head genes have not yet been detected and could be located in two regions (for which there are no known genes) adjacent to genes 4 and 8. The P1 morphogenetic gene clusters are interrupted by many genes that are expressed in the prophage.

Prophage substitution and prophage loss from superinfected Escherichia coli recA(P1) lysogens

It is shown that the plasmid prophage P1 can be displaced by a superinfecting P1 phage in Escherichia coli recA(P1) lysogens. Six widely separated phage markers were used to distinguish between residual recombination and total substitution. It is further shown that superinfection of recA lysogens can lead to loss of both phage (curing). These two phenomena, previously reported in Rec+ strains, are thus independent of host recombination and may result from perturbations of some function involved in plasmid maintenance.

A new pleiotropic bacteriophage P1 mutation, bof, affecting c1 repression activity, the expression of plasmid incompatibility and the expression of certain constitutive prophage genes

In bacteriophage P1 an amber mutation in a new gene, bof, has been isolated. The bof-1 phage mutant exhibits a pleiotropic phenotype; bof product is non-essential, and acts as a positive modulator. In P1 bac-1 mutants, in which a dnaB analog product, ban, is expressed constitutively, the bof product activates ban expression both in the prophage state and in lytic growth: P1 bof bac prophages have a reduced ban activity and in lytic growth P1 bof bac phages show a lower ban activity than P1 wild type. This effect on ban activity is observed specifically in P1 bac-1 mutants; it is not mediated by the c1 repressor of the lytic functions (repressor of the ban operon) since this effect occurs even if the phage carries a heat sensitive c1 repressor. Thus we concluded that the bac mutation put the ban operon under an abnormal, unknown control, modulated by the bof product. P1 bof lysogens show an increased immunity to superinfecting P1 phage and are affected in their inducibility properties; in the presence of the altered c1-100 repressor, bof product is required for maintenance of lysogeny, as shown by the induction of P1 c1-100 bof-1 lysogens at 30 degrees. P1 bof superinfecting phage can be established together with a resident P1 bof prophage in a recA host, unlike P1 wild type which cannot form double lysogens. P1 bof double lysogens are unstable and segregate one or the other prophage. P1 Cm bof and P1 Km bof lysogens show higher levels of antibiotic resistance than the corresponding bof+ lysogens. The bof gene has been mapped, in an interval defined by P1 prophage deletion end points, far from both ban and c1. All bof phenotypes are reversed by single mutations.

Studies of a plasmid coding for tetracycline resistance and hydrogen sulfide production incompatible with the prophage P1

The plasmid pIP231, determining tetracycline resistance and hydrogen sulfide production is shown to belong to incompatibility group Y and to code for a restriction and modification system. Unlike the IncY plasmids, P7 and P15B, plasmid pIP231 shows only little genetic and physical homology with P1 prophage.

Analysis of bacteriophage P1 immunity by using lambda-P1 recombinants constructed in vitro

We describe the dissection and reconstruction of a complex control circuit, the P1 immunity system, by a method that involves inserting EcoRI-generated fragments of P1 DNA into lambda vectors that can then be sequentially inserted into a bacterial cell. Using these techniques we have isolated lambda-P1 hybrid phages that express the products of P1 genes c1, c4, ant, and ban and, in appropriately constructed lysogens, confirmed the roles played by the first three of these products in phage immunity. In addition we have localized to particular P1 fragments the sites requisite for expression and repression of these gene products. The analysis leads to the conclusion that gpant acts in trans to antagonize repression mediated by gpc1, in support of one of two proposed models for gpant action. Moreover, two features of the immunity system are revealed: (i) a hitherto unknown component that effects gpc1 repression; and (ii) an unexpected ability of gpc4 to channel a superinfecting c1+ phage into the lysogenic state, which suggests that gpc4 activity regulates the establishment phase of lysogeny.

Effects of mutations in the immunity system of bacteriophage P1

A mutant of bacteriophage P1 that made an altered c1 repressor is described. The mutant c1 product had two configurations: in lysogens, at high temperatures, it permitted constitutive expression of the normally repressed DNA replication function ban and was insensitive to the action of ant, a product expressed by the virulent mutant P1virs and by the heteroimmune phage P7 (formerly phiamp+) and normally able to overcome c1 repression; in mutant lysogens at low temperatures, the mutant repressor was apparently normal (able to repress ban and sensitive to ant action). Genetic studies of this mutant led to the isolation of a derivative that formed unstable lysogens. These studies suggested that the ban product was normally under c1 control; they further showed that ant overcame c1 repression by inactivating c1 rather than by creating a bypass of repressor activity.

Maintenance of bacteriophage P1 plasmid

Three mutants of bacteriophage P1 affected in their ability to maintain the lysogenic state stably are described here. These mutants were normal in lytic growth, but lysogenic derivatives segregated nonlysogens at abnormally high rates (1 to 30% per division). Cells harboring these mutant prophages were elongated or filamentous. The mutations responsible for this prophage instability fell into two classes on the bases of their genetic location, their effect on the ability to lysogenize recA bacteria, and their suppressibility by ant mutations eliminating antirepressor activity. The two mutants that were able to form recA lysogens showed the same prophage instability and partial inhibition of cell division in recA as in rec+ lysogens. The fact that plasmid-linked mutations can cause prophage instability suggests that P1 codes for at least some of the functions determining its own autonomy and segregation.

Physical mapping of BglII, BamHI, EcoRI, HindIII and PstI restriction fragments of bacteriophage P1 DNA

A cleavage map of bacteriophage P1 DNA was established by reciprocal double digestion with various restriction endonucleases. The enzymes used and, in parenthesis, the number of their cleavage sites on the P1clts genome are: PstI (1), HindIII(3), BglII (11), BamHI (14) and EcoRI (26). The relative order of the PstI, HindIII and BglII sites, as well as the order of 13 out of the 14 BamHI sites and of 17 out of the 26 EcoRI sites was determined. The P1 genome was divided into 100 map units and the PstI site was arbitrarily chosen as reference point at map unit 20. DNA packaging into phage heads starts preferentially at map unit 92 and it proceeds towards higher map units. The two inverted repeat sequences of P1 DNA map about at units 30 and 34.

Genetic studies of coliphage P1. III. Extended genetic map

An extensive genetic map of coliphage P1 has been constructed for 113 amber mutants, using primarily a modification of the conventional complementation spot test. These spot tests failed to classify the mutants into cistrons, but when they were quantitated they permitted assignment of the mutants into 10 linkage clusters. Furthermore, a linear order could be deduced for most of the mutants within each cluster. This strongly suggested that recombination was the predominant event generating plaques and that, for the practical purpose of rapid genetic mapping, such spot tests could be considered as a series of two-factor crosses. Six of the 10 linkage clusters correlated with the P1 genetic map established by Scott (1968). The locations of the remaining four clusters were determined by three-factor crosses and by prophage deletion mapping. The nonrandom occurrence of termini for 14 deletion prophages, which we established previously (Walker and Walker, 1975), and the coincidence of these termini with five out of ten regions demarcating the linkage clusters are discussed. Complementation tests in liquid frequently gave ambiguous results. Therefore, cistron designations were not assigned.

Genetic studies of coliphage P1. II. Relatedness to P7

Using semiquantitative spot tests, 107 independently isolated amber mutants of P1 were shown to be rescued by a nonpermissive strain of Escherichia coli lysogenic for P7 (previously called phiamp), indicating extensive genetic relatedness between P1 and P7. The amount of rescue observed varied with mutants from different genetic linkage clusters of P1. Although these rescue tests cannot distinguish between recombination, complementation, transactivation, or combinations thereof, a major role is indicated for recombination.