Recombinant P4 bacteriophages propagate as viable lytic phages or as autonomous plasmids in Klebsiella pneumoniae

The plasmid status of satellite bacteriophage P4

P4 is a natural phasmid (phage-plasmid) that exploits different modes of propagation in its host Escherichia coli. Extracellularly, P4 is a virion, with a tailed icosahedral head, which encapsidates the 11.6-kb-long double-stranded DNA genome. After infection of the E. coli host, P4 DNA can integrate into the bacterial chromosome and be maintained in a repressed state (lysogeny). Alternatively, P4 can replicate as a free DNA molecule; this leads to either the lytic cycle or the plasmid state, depending on the presence or absence of the genome of a helper phage P2 in the E. coli host. As a phage, P4 is thus a satellite of P2 phage, depending on the helper genes for all the morphogenetic functions, whereas for all its episomal functions (integration and immunity, multicopy plasmid replication) P4 is completely autonomous from the helper. Replication of P4 DNA depends on its alpha protein, a multifunctional polypeptide that exhibits primase and helicase activity and binds specifically the P4 origin. Replication starts from a unique point, ori1, and proceeds bidirectionally in a straight theta-type mode. P4 negatively regulates the plasmid copy number at several levels. An unusual mechanism of copy number control is based on protein-protein interaction: the P4-encoded Cnr protein interacts with the alpha gene product, inhibiting its replication potential. Furthermore, expression of the replication genes cnr and alpha is regulated in a complex way that involves modulation of promoter activity by positive and negative factors and multiple mechanisms of transcription elongation-termination control. Thus, the relatively small P4 genome encodes mostly regulatory functions, required for its propagation both as an episomal element and as a temperate satellite phage. Plasmids that, like P4, propagate horizontally via a specific transduction mechanism have also been found in the Archaea. The presence of P4-like prophages or cryptic prophages often associated with accessory bacterial functions attests to the contribution of satellite phages to bacterial evolution.

A complex control system for transcriptional activation from the sid promoter of bacteriophage P4

The sid gene promoter (Psid), which controls expression of the late genes from satellite phage P4, is activated by a unique class of small DNA-binding proteins. The activators from both satellite and helper phages stimulate transcription from Psid. These activators bind to sites centered at position -55 in all the helper and satellite phage late promoters. P4 Psid is unique in that it has an additional activator binding site centered at position -18 (site II). We have constructed a mutant of site II that no longer binds activators. Transcription under the control of satellite phage activators is increased by the site II mutation. In contrast, helper phage activators do not show this increase in transcription from Psid mutated at site II. Competition gel shift analysis reveals that the P4 satellite phage activator, Delta, binds eightfold better to site II than to site I. The products of the sid transcription unit are needed only when a helper phage is present; thus, the satellite phage activators repress transcription until the helper is present to supply a nonrepressing activator.

Cnr protein, the negative regulator of bacteriophage P4 replication, stimulates specific DNA binding of its initiator protein alpha

Bacteriophage P4 DNA replication depends upon the phage-encoded alpha protein, which has DNA helicase and DNA primase activity and can specifically bind to the replication origin (ori) and to the cis replicating region (crr). The P4 Cnr protein functions as a negative regulator of P4 replication, and P4 does not replicate in cells that overexpress cnr. We searched for P4 mutants that suppressed this phenotype (Cnr resistant [alpha cr]). Eight independent mutants that grew in the presence of high levels of Cnr were obtained. None of these can establish the plasmid state. Each of these mutations lies in the DNA binding domain of gp alpha that occupies the C terminus of the protein. Five different sequence changes were found: T675M, G732V (three times), G732W (twice), L733V, and L737V. A TrxA-Cnr fusion protein does not bind DNA by itself but stimulates the ori and crr binding abilities of alpha protein in vitro. The alpha cr mutant proteins were still able to bind specifically to ori or crr, but specific DNA binding was less stimulated by the TrxA-Cnr protein. We present evidence that Cnr protein interacts with the gp alpha domain that binds specifically to DNA and that gp(alpha)cr mutations impair this interaction. We hypothesize that gp alpha-Cnr interaction is essential for the control of P4 DNA replication.

Multiple regulatory mechanisms controlling phage-plasmid P4 propagation

Bacteriophage P4 autonomous replication may result in the lytic cycle or in plasmid maintenance, depending, respectively, on the presence or absence of the helper phage P2 genome in the Escherichia coli host cell. Alternatively, P4 may lysogenize the bacterial host and be maintained in an immune-integrated condition. A key step in the choice between the lytic/plasmid vs. the lysogenic condition is the regulation of P4 alpha operon. This operon may be transcribed from two promoters, PLE and PLL, and encodes both immunity (promoter proximal) and replication (promoter distal) functions. PLE is a constitutive promoter and transcription of the downstream replication genes is regulated by transcription termination. The trans-acting immunity factor that controls premature transcription termination is a short RNA encoded in the PLE proximal part of the operon. Expression of the replication functions in the lytic/plasmid condition is achieved by activation of the PLL promoter. Transcription from PLL is insensitive to the termination mechanism that acts on transcription starting from PLE.PLL is also negatively regulated by P4 orf88, the first gene downstream of PLL. An additional control on P4 DNA replication is exerted by the P4 cnr gene product.

Mechanisms of genome propagation and helper exploitation by satellite phage P4

Temperate coliphage P2 and satellite phage P4 have icosahedral capsids and contractile tails with side tail fibers. Because P4 requires all the capsid, tail, and lysis genes (late genes) of P2, the genomes of these phages are in constant communication during P4 development. The P4 genome (11,624 bp) and the P2 genome (33.8 kb) share homologous cos sites of 55 bp which are essential for generating 19-bp cohesive ends but are otherwise dissimilar. P4 turns on the expression of helper phage late genes by two mechanisms: derepression of P2 prophage and transactivation of P2 late-gene promoters. P4 also exploits the morphopoietic pathway of P2 by controlling the capsid size to fit its smaller genome. The P4 sid gene product is responsible for capsid size determination, and the P2 capsid gene product, gpN, is used to build both sizes. The P2 capsid contains 420 capsid protein subunits, and P4 contains 240 subunits. The size reduction appears to involve a major change of the whole hexamer complex. The P4 particles are less stable to heat inactivation, unless their capsids are coated with a P4-encoded decoration protein (the psu gene product). P4 uses a small RNA molecule as its immunity factor. Expression of P4 replication functions is prevented by premature transcription termination effected by this small RNA molecule, which contains a sequence that is complementary to a sequence in the transcript that it terminates.

Cloning and transposon vectors derived from satellite bacteriophage P4 for genetic manipulation of Pseudomonas and other gram-negative bacteria

We developed transposon and cloning shuttle vectors for genetic manipulation of Pseudomonas and other gram-negative bacteria, exploiting the unique properties and the broad host range of the satellite bacteriophage P4. P4::Tn5 AP-1 and P4::Tn5 AP-2 are suicide transposon vectors which have been used for efficient Tn5 mutagenesis in Pseudomonas putida. pKGB2 is a phasmid vector with a cloning capacity of about 7.5 kb; useful unique cloning sites are SacI and SacII in the streptomycin resistance determinant and PvuI and XhoI in the kanamycin resistance determinant. pKGB4 is a cosmid derived from pKGB2 and carries the additional cloning site SmaI in the kanamycin resistance determinant; its cloning capacity is about 18 kb. These vectors and their recombined derivatives were transferred from Escherichia coli to P. putida by transduction and may be used for other bacterial species susceptible to P4 infection.

A phasmid shuttle vector for the cloning of complex operons in Salmonella

Phasmid (phage plasmid hybrid) P4 vir1 can be propagated in Escherichia coli as a helper-dependent lytic phage, as a plasmid, or as a prophage. On the basis of an understanding of these modes of propagation, derivatives of P4 have been constructed for use as cloning vectors. In this report we demonstrate that phasmid P4 (i) will propagate as a helper-dependent lytic phage and as a plasmid in Salmonella spp. and (ii) can be used as a high efficiency phage shuttle vector for the reversible transfer of cloned genes between Salmonella spp. and E. coli. For both E. coli and Salmonella spp., P4 phage-mediated gene transfer proved to be only 10-fold lower than plaquing efficiency. For the case of Salmonella spp., this frequency is ca. 10(4)-fold more efficient than is typically found for the transformation of DNA molecules. The usefulness of this cloning vector system for analyses of pathogenic virulence factors is demonstrated by the cloning and expression of both the P pilus adhesin operon and the hemolysin operon of uropathogenic E. coli.

Participation of the lytic replicon in bacteriophage P1 plasmid maintenance

P1 bacteriophage carries at least two replicons: a plasmid replicon and a viral lytic replicon. Since the isolated plasmid replicon can maintain itself stably at the low copy number characteristic of intact P1 prophage, it has been assumed that this replicon is responsible for driving prophage replication. We provide evidence that when replication from the plasmid replicon is prevented, prophage replication continues, albeit at a reduced rate. The residual plasmid replication is due to incomplete repression of the lytic replicon by the c1 immunity repressor. Incomplete repression was particularly evident in lysogens of the thermoinducible P1 c1.100 prophage, whose replication at 32 degrees C remained almost unaffected when use of the plasmid replicon was prevented. Moreover, the average plasmid copy number of P1 in a P1 c1.100 lysogen was elevated with respect to the copy number of P1 c1+. The capacity of the lytic replicon to act as an auxiliary in plasmid maintenance may contribute to the extraordinary stability of P1 plasmid prophage.

Alternative promoters in the development of bacteriophage plasmid P4

Infection of Escherichia coli with the satellite virus P4 without its helper bacteriophage P2 leads either to the immune integrated state or to the nonimmune multicopy plasmid condition. We analyzed the transcription pattern of the phage plasmid P4 early and late after infection and during the stable plasmid or lysogenic condition. The early postinfection phase is characterized by the leftward transcription of an operon including the genes cI (P4 immunity) and alpha (replication). This early transcript starts from the promoter PLE, which shows a good homology with the E. coli sigma 70 promoter. At later times, the transcription of this operon starts from a different promoter, PLL, located 400 base pairs upstream of PLE, and sharing little homology with the canonical E. coli promoter sequence; a longer transcript encoding an additional open reading frame is thus produced. PLL shares two boxes of homology with the P4 late promoter PSID, positively regulated by the P4 delta gene product, and depends on delta function for its full activation. In the multicopy plasmid state, the transcription pattern is similar to that observed at late times after infection. Since in the plasmid state not only is P4 immunity not expressed but its establishment is prevented, even though the P4 cI gene is transcribed, the P4 cI function may be regulated at the posttranscriptional level. In the immune state, transcription starts from PLE but does not continue to cover the P4 alpha gene. This suggests that P4 immunity acts by prematurely terminating transcription initiated at PLE.

Conservation of structure and location of Rhizobium meliloti and Klebsiella pneumoniae nifB genes

Using transposon Tn5-mediated mutagenesis, an essential Rhizobium meliloti nitrogen fixation (nif) gene was identified and located directly downstream of the regulatory gene nifA. Maxicell and DNA sequence analysis demonstrated that the new gene is transcribed in the same direction as nifA and codes for a 54-kilodalton protein. In Klebsiella pneumoniae, the nifBQ operon is located directly downstream of a gene which is structurally and functionally homologous to the R. meliloti nifA gene. The DNA sequences of the K. pneumoniae nifB and nifQ genes (which code for 51- and 20-kilodalton proteins, respectively) were determined. The DNA sequence of the newly identified R. meliloti gene was approximately 50% homologous to the K. pneumoniae nifB gene. R. meliloti does not contain a gene homologous to nifQ directly downstream of nifB. The R. meliloti nifB product shares approximately 40% amino acid homology with the K. pneumoniae nifB product, and 10 of the 12 cysteine residues of the R. meliloti nifB product are conserved with 10 of the 17 cysteine residues of the K. pneumoniae nifB product.

Paraquat-mediated selection for mutations in the manganese-superoxide dismutase gene sodA

We report the unexpected result that Escherichia coli isolates containing a multicopy plasmid (pDT1.5) carrying the manganese-superoxide dismutase gene sodA were more sensitive than the wild type to paraquat-mediated growth inhibition. The pDT1.5 locus responsible for the paraquat-sensitive phenotype was delimited to a 0.6-kilobase segment by transposon Tn5 mutagenesis. Moreover, superoxide dismutase activity was the same as in the wild type in strains carrying pDT1.5::Tn5 insertions mapping to the 0.6-kilobase locus. These data identify the 0.6-kilobase segment as the locus of sodA and establish an association between growth inhibition by paraquat and the function of the plasmid-borne sodA gene.

Regulation of the plasmid state of the genetic element P4

After infection of sensitive cells in the absence of a helper phage, the satellite bacteriophage P4 enters a temporary phase of uncommitted replication followed by commitment to either the repressed-integrated condition or the derepressed-high copy number mode of replication. The transient phase and the stable plasmid condition differ from each other in the pattern of protein synthesis, in the rate of P4 DNA replication and in the expression of some gene functions. The regulatory condition characteristic of the P4 plasmid state affects a superinfecting genome, preventing the establishment of the P4 immune condition.

Mutational analysis of the Klebsiella pneumoniae nitrogenase promoter: sequences essential for positive control by nifA and ntrC (glnG) products

ntr (nitrogen regulated) and nif (nitrogen fixation) promoters are structurally similar to each other but bear no resemblance to canonic Escherichia coli promoters. ntr promoters are normally activated by the ntrC (glnG) product, but they can also be activated by the ntrC-related Klebsiella pneumoniae nifA product. In contrast, nif promoters of K. pneumoniae such as the nitrogenase (nifH) promoter can only be nifA activated. In this paper, we report the isolation and characterization of 28 mutants of the K. pneumoniae nifH promoter. Class A mutants no longer respond to nifA-mediated transcription, and class B mutants can now respond to ntrC-mediated activation. These two classes of mutants define sequences important to nifA- and ntrC-mediated transcription. Most surprising is that a single base change is sufficient to convert a nifA-activated promoter into an ntrC-activated one.

Plasmid mode of propagation of the genetic element P4

The satellite bacteriophage P4, in the presence of a helper phage, can enter either the lytic or the lysogenic cycle. In the absence of the helper, P4 can integrate in the bacterial chromosome. In addition, the partially immunity-insensitive mutant P4 vir1 can be maintained as a plasmid. We have found that in the absence of the helper, P4 wt also can be maintained as a plasmid, and that both P4 wt and P4 vir1 have two options for their intracellular propagation: a repressed-integrated or a derepressed-high copy number plasmid mode of maintenance. In the repressed mode, the P4 wt genome is only found integrated into the bacterial chromosome, while the P4 vir1 is found also as a low copy number plasmid coexisting with the integrated P4 vir1 genome. The clones carrying P4 in the derepressed-high copy number plasmid state are obtained at low frequency (0.3%) upon infection with P4 wt, while the vir1 mutation increases this frequency about 300-fold. Such clones can be distinguished easily because of their typical colony morphology (rosettes), due to the presence of filamentous cells. Filamentation of the bacterial host suggests that the presence of derepressed P4 genomes in high copy number interferes with the normal cell division mechanism. The derepressed clones are rather stable, but may revert spontaneously to the repressed state. Spontaneous transition from the repressed to the derepressed state was not observed; however, it can be induced by P2 or P4 vir1 superinfection of P4 wt and P4 vir1 lysogens or by growing the P4 vir1 lysogens up to the late exponential phase. The ability of P4 to choose either of two stable states and the potential to shift between these two modes of propagation indicate that the synthesis of the immunity repressor is regulated.

Phasmid P4: manipulation of plasmid copy number and induction from the integrated state

"Phasmid" P4 is unusual in that it is capable of (i) temperate, (ii) lytic, helper-dependent, and (iii) plasmid modes of propagation. In this report we characterize most of the known P4 genetic functions as to their essential or nonessential roles in the stable maintenance of plasmid P4 vir1 (pP4 vir1 (pP4 vir1). We also identify growth conditions that can be used to stably maintain pP4 vir1 at any one of several different copy number levels (n = 1 to 3, n = 10 to 15, or n = 30 to 40). Analyses of a temperature-sensitive alpha derivative of pP4 vir1 show that shifting the temperature from 37 to 42 degrees C allows this mutant to maintain an integrated copy of the plasmid, whereas replication of free copies is repressed because of the nonpermissive condition for their DNA synthesis. Conversely, a shift from 42 to 37 degrees C can be used to reinstate plasmid propagation. The utility of the inducible states of pP4 vir1 is discussed with respect to its attributes as a vector with the potential for cloning inserts of DNA up to 33,000 base pairs in a wide range of bacterial hosts.

Conditionally replicating plasmid vectors that can integrate into the Klebsiella pneumoniae chromosome via bacteriophage P4 site-specific recombination

P4 is a satellite phage of P2 and is dependent on phage P2 gene products for virion assembly and cell lysis. Previously, we showed that a virulent mutant of phage P4 (P4 vir1) could be used as a multicopy, autonomously replicating plasmid vector in Escherichia coli and Klebsiella pneumoniae in the absence of the P2 helper. In addition to establishing lysogeny as a self-replicating plasmid, it has been shown that P4 can also lysogenize E. coli via site-specific integration into the host chromosome. In this study, we show that P4 also integrates into the K. pneumoniae chromosome at a specific site. In contrast to that in E. coli, however, site-specific integration in K. pneumoniae does not require the int gene of P4. We utilized the alternative modes of P4 lysogenization (plasmid replication or integration) to construct cloning vectors derived from P4 vir1 that could exist in either lysogenic mode, depending on the host strain used. These vectors carry an amber mutation in the DNA primase gene alpha, which blocks DNA replication in an Su- host and allows the selection of lysogenic strains with integrated prophages. In contrast, these vectors can be propagated as plasmids in an Su+ host where replication is allowed. To demonstrate the utility of this type of vector, we show that certain nitrogen fixation (nif) genes of K. pneumoniae, which otherwise inhibit nif gene expression when present on multicopy plasmids, do not exhibit inhibitory effects when introduced as merodiploids via P4 site-specific integration.

Activation of Klebsiella pneumoniae and Rhizobium meliloti nitrogenase promoters by gln (ntr) regulatory proteins

We have studied the expression, in different Escherichia coli gln (ntr) mutants, of fusions (constructed in vitro) of the nifHDK (nitrogenase) promoters from Klebsiella pneumoniae and Rhizobium meliloti to E. coli lacZ. Derepression of the K. pneumoniae nifH::lacZ fusion requires the glnF (ntrA) gene product in addition to the K. pneumoniae nifA gene product, indicating that regulation of the K. pneumoniae nif genes is more closely integrated with the overall nitrogen control system than previously demonstrated. Derepression of the R. meliloti nifH::lacZ fusion in E. coli by the K. pneumoniae nifA gene product (which we had previously shown) exhibits the same requirement for glnF. Derepression of the R. meliloti nifH::lacZ fusion, but not the K. pneumoniae nifH::lacZ fusion, can be mediated by the glnG (ntrC) gene product, suggesting that the gln regulatory genes might directly regulate the symbiotic nitrogen fixation genes in Rhizobium.

Promoters regulated by the glnG (ntrC) and nifA gene products share a heptameric consensus sequence in the -15 region

We have determined the nucleotide sequences of the Klebsiella pneumoniae nifL (regulation of N2 fixation genes) and the Escherichia coli glnA (glutamine synthetase) promoters. We compared these sequences with the published sequences of three other promoters that, like the nifL and glnA promoters, are activated by the general nitrogen regulators glnF (ntrA) and glnG (ntrC). The three promoters are the argTr (arginine transport) and dhuA (histidine transport) promoters of Salmonella typhimurium and the nifH (nitrogenase) promoter of Rhizobium meliloti. All five sequences (with at most one mismatch) contain the heptameric consensus sequence T-T-T-T-G-C-A. In the R. meliloti nifH and K. pneumoniae nifL promoters, in which the transcription initiation sites have been determined, the consensus sequence is situated in the -15 region. We recently reported that the K. pneumoniae nifA product, which activates nif genes, can substitute for the glnG (ntrC) product in activating promoters of several genes involved in nitrogen assimilation, including the nifL, the glnA, and the R. meliloti nifH promoters. It is likely that nifA also activates the S. typhimurium argTr and dhuA promoters. In contrast, the glnG product cannot substitute for the nifA product in the activation of the K. pneumoniae nifH (nitrogenase) promoter. Consistent with this latter observation, and supporting the conclusion that the T-T-T-T-G-C-A sequence is a regulatory site for glnG product activation, the K. pneumoniae nifH promoter (C-C-C-T-G-C-A) has only partial similarity with the T-T-T-T-G-C-A consensus sequence in the -15 region.

Klebsiella pneumoniae nifA product activates the Rhizobium meliloti nitrogenase promoter

Bacteria in the genus Rhizobium normally fix nitrogen only when they interact with leguminous plants to produce on the roots a highly differentiated structure, the nodule, within which the bacteria differentiate into nitrogen-fixing bacteroids. By contrast, the enteric bacterium Klebsiella pneumoniae reduces nitrogen in a free-living state in conditions of low oxygen tension and deficiency of fixed nitrogen. In K. pneumoniae, the overall circuitry by which nitrogen-fixation (nif) genes are regulated has been elucidated. In response to ammonia starvation, the product of the glnG gene activates transcription of the nifLA operon; this activation is dependent on the product of glnF (ref. 4). The nifA gene product is in turn required for transcription of all the other nif genes, including the nifHDK operon which codes for the subunits of nitrogenase. In contrast, very little is known about the sequence of events involved in the regulated change in rhizobial nif gene expression associated with bacteroid differentiation. In the work described here, we identify the K. pneumoniae and Rhizobium meliloti nifHDK promoters by mapping the in vivo start points of transcription. By defining and comparing the DNA sequences of these two promoters, we find that they share an unexpected degree of homology. Further, by constructing fusions of each of the two promoters to the lacZ gene from Escherichia coli, we show that both promoters are activated by the product of the K. pneumoniae nifA gene.

Regulation of nitrogen metabolism genes by nifA gene product in Klebsiella pneumoniae

The Klebsiella pneumoniae nifA gene product, which is known to activate expression of the nitrogen fixation (nif) structural genes, is shown here also to be able to substitute for the product of the gene glnG (ntrC) in the regulation of other nitrogen metabolism genes. An evolutionary relationship between the nifA and glnG genes is suggested.