Characterization of the bacteriophage phi29-encoded protein p16.7: a membrane protein involved in phage DNA replication

An early expressed operon, located at the right end of the linear bacteriophage phi29 genome, contains open reading frame (ORF)16.7, whose deduced protein sequence of 130 amino acids is conserved in phi29-related phages. Here, we show that this ORF actually encodes a protein, p16.7, which is abundantly and early expressed after infection. p16.7 is a membrane protein, and the N-terminally located transmembrane-spanning domain is required for its membrane localization. The variant p16.7A, in which the N-terminal membrane anchor was replaced by a histidine-tag, was purified and characterized. Purified p16.7A was shown to form dimers in solution. To study the in vivo role of p16.7, a phi29 mutant containing a suppressible mutation in gene 16.7 was constructed. In vivo phage DNA replication was affected in the absence of p16.7, especially at early infection times. Based on the results, the putative role of p16.7 in in vivo phi29 DNA replication is discussed.     

The Bacillus subtilis phage phi 29 protein p16.7, involved in phi 29 DNA replication, is a membrane-localized single-stranded DNA-binding protein.

The functional role of the phi 29-encoded integral membrane protein p16.7 in phage DNA replication was studied using a soluble variant, p16.7A, lacking the N-terminal membrane-spanning domain. Because of the protein-primed mechanism of DNA replication, the bacteriophage phi 29 replication intermediates contain long stretches of single-stranded DNA (ssDNA). Protein p16.7A was found to be an ssDNA-binding protein. In addition, by direct and functional analysis we show that protein p16.7A binds to the stretches of ssDNA of the phi 29 DNA replication intermediates. Properties of protein p16.7A were compared with those of the phi 29-encoded single-stranded DNA-binding protein p5. The results obtained show that both proteins have different, non-overlapping functions. The likely role of p16.7 in attaching phi 29 DNA replication intermediates to the membrane of the infected cell is discussed. Homologues of gene 16.7 are present in phi 29-related phages, suggesting that the proposed role of p16.7 is conserved in this family of phages.     

Structural basis for membrane anchorage of viral phi29 DNA during replication

Prokaryotic DNA replication is compartmentalized at the cellular membrane. Functional and biochemical studies showed that the Bacillus subtilis phage 29-encoded membrane protein p16.7 is directly involved in the organization of membrane-associated viral DNA replication. The structure of the functional domain of p16.7 in complex with DNA, presented here, reveals the multimerization mode of the protein and provides insights in the organization of the phage genome at the membrane of the infected cell.     

In vivo assembly of phage phi 29 replication protein p1 into membrane-associated multimeric structures

The mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown. In the case of the Bacillus subtilis phage 29, the viral protein p1 enhances the rate of in vivo viral DNA replication. Previous work showed that p1 generates highly ordered structures in vitro. We now show that protein p1, like integral membrane proteins, has an amphiphilic nature. Furthermore, immunoelectron microscopy studies reveal that p1 has a peripheral subcellular location. By combining in vivo chemical cross-linking and cell fractionation techniques, we also demonstrate that p1 assembles in infected cells into multimeric structures that are associated with the bacterial membrane. These structures exist both during viral DNA replication and when 29 DNA synthesis is blocked due to the lack of viral replisome components. In addition, protein p1 encoded by plasmid generates membrane-associated multimers and supports DNA replication of a p1-lacking mutant phage, suggesting that the pre-assembled structures are functional. We propose that a phage structure assembled on the cell membrane provides a specific site for 29 DNA replication.     

Dynamics of DNA ejection from bacteriophage

The ejection of DNA from a bacterial virus (i.e., phage) into its host cell is a biologically important example of the translocation of a macromolecular chain along its length through a membrane. The simplest mechanism for this motion is diffusion, but in the case of phage ejection a significant driving force derives from the high degree of stress to which the DNA is subjected in the viral capsid. The translocation is further sped up by the ratcheting and entropic forces associated with proteins that bind to the viral DNA in the host cell cytoplasm. We formulate a generalized diffusion equation that includes these various pushing and pulling effects and make estimates of the corresponding speedups in the overall translocation process. Stress in the capsid is the dominant factor throughout early ejection, with the pull due to binding particles taking over at later stages. Confinement effects are also investigated, in the case where the phage injects its DNA into a volume comparable to the capsid size. Our results suggest a series of in vitro experiments involving the ejection of DNA into vesicles filled with varying amounts of binding proteins from phage whose state of stress is controlled by ambient salt conditions or by tuning genome length.     

The integral membrane protein p16.7 organizes in vivo phi29 DNA replication through interaction with both the terminal protein and ssDNA

Remarkably little is known about the in vivo organization of membrane-associated prokaryotic DNA replication or the proteins involved. We have studied this fundamental process using the Bacillus subtilis phage phi29 as a model system. Previously, we demonstrated that the phi29-encoded dimeric integral membrane protein p16.7 binds to ssDNA and is involved in the organization of membrane-associated phi29 DNA replication. Here we demonstrate that p16.7 forms multimers, both in vitro and in vivo, and interacts with the phi29 terminal protein. In addition, we show that in vitro multimerization is enhanced in the presence of ssDNA and that the C-terminal region of p16.7 is required for multimerization but not for ssDNA binding or interaction with the terminal protein. Moreover, we provide evidence that the ability of p16.7 to form multimers is crucial for its ssDNA-binding mode. These and previous results indicate that p16.7 encompasses four distinct modules. An integrated model of the structural and functional domains of p16.7 in relation to the organization of in vivo phi29 DNA replication is presented.     

Use of M13mp phages to study gene regulation, structure and function: cloning and recombinational analysis of genes of the Salmonella typhimurium histidine operon

A restriction map was determined for a phi 80 lambda dhis transducing phage DNA carrying the Salmonella typhimurium histidine operon. DNA fragments containing the promoter/regulatory region and the first two structural genes of the histidine operon (hisOGD) were identified by their ability to direct regulated synthesis of histidinol dehydrogenase (product of hisD) in a coupled in vitro protein synthesizing system. A 3.1-kb SalI-EcoRI restriction fragment containing the hisOGD region, was subcloned into phage M13mp8 and M13mp9 RF DNAs. Methods are described for shuttling mutant and wild-type bacterial DNA sequences between the M13mp::his phage and host bacterial genomes. Of novel importance is the use of the phage M13 gene II amber mutation to obtain integration of the M13mp::his phage genome into the homologous his region of the bacterial chromosome following transduction of recipients lacking an amber suppressor. This method can be used to facilitate allele replacement with genes carried on M13 transducing phages.     

Structural and functional analysis of phi29 p16.7C dimerization mutants: identification of a novel aromatic cage dimerization motif

Prokaryotic DNA replication is compartmentalized at the cellular membrane. The Bacillus subtilis phage varphi29-encoded membrane protein p16.7 is one of the few proteins known to be involved in the organization of prokaryotic membrane-associated DNA replication. The functional DNA binding domain of p16.7 is constituted by its C-terminal half, p16.7C, which forms high affinity dimers in solution and which can form higher order oligomers. Recently, the solution and crystal structures of p16.7C and the crystal structure of the p16.7C-DNA complex have been solved. Here, we have studied the p16.7C dimerization process and the structural and functional roles of p16.7 residues Trp-116 and Asn-120 and its last nine C-terminal amino acids, which form an extended tail. The results obtained show that transition of folded dimers into unfolded monomers occurs without stable intermediates and that both Trp-116 and the C-terminal tail are important for dimerization and functionality of p16.7C. Residue Trp-116 is involved in formation of a novel aromatic cage dimerization motif, which we call "Pro cage." Finally, whereas residue Asn-120 plays a minor role in p16.7C dimerization, we show that it is critical for both oligomerization and DNA binding, providing further evidence that DNA binding and oligomerization of p16.7C are coupled processes.     

Dynamic relocalization of phage phi 29 DNA during replication and the role of the viral protein p16.7

We have examined the localization of DNA replication of the Bacillus subtilis phage phi 29 by immunofluorescence. To determine where phage replication was localized within infected cells, we examined the distribution of phage replication proteins and the sites of incorporation of nucleotide analogues into phage DNA. On initiation of replication, the phage DNA localized to a single focus within the cell, nearly always towards one end of the host cell nucleoid. At later stages of the infection cycle, phage replication was found to have redistributed to multiple sites around the periphery of the nucleoid, just under the cell membrane. Towards the end of the cycle, phage DNA was once again redistributed to become located within the bulk of the nucleoid. Efficient redistribution of replicating phage DNA from the initial replication site to various sites surrounding the nucleoid was found to be dependent on the phage protein p16.7.     

Roles of cell surface components of Escherichia coli K-12 in bacteriophage T4 infection: interaction of tail core with phospholipids.

The cell surface of Escherichia coli K-12, reconstituted from the OmpC protein, lipopolysaccharide, and the peptidoglycan layer, was active as a receptor for phage T4, resulting in the contraction of the tail sheath and the penetration of the core through the cell surface (Furukawa et al., J. Bacteriol. 140:1071--1080, 1979). In the present work the process of DNA ejection from the contracted T4 phage particle was studied. Contracted phage particles were adsorbed to phospholipid liposomes by the core tip. This adsorption resulted in ejection of phage DNA. Either phosphatidylglycerol or cardiolipin was active for the DNA ejection. A proton motive force across the liposome membrane was not required for these processes. The process of DNA ejection, however, was temperature dependent, whereas the adsorption of the core tip to liposomes took place at 4 degrees C. Based on these observations together with those in the previous paper, the process of T4 infection of E. coli K-12 cells is discussed with special reference to the roles of cell surface components.     

Identification of a replication protein and repeats essential for DNA replication of the temperate lactococcal bacteriophage TP901-1

DNA replication of the temperate lactococcal bacteriophage TP901-1 was shown to involve the gene product encoded by orf13 and the repeats located within the gene. Sequence analysis of 1,500 bp of the early transcribed region of the phage genome revealed a single-stranded DNA binding protein analogue (ORF12) and the putative replication protein (ORF13). The putative origin of replication was identified as series of repeats within orf13 and was shown to confer a TP901-1 resistance phenotype when present in trans. Site-specific mutations were introduced into the replication protein and into the repeats. The mutations were introduced into the TP901-1 prophage by homologous recombination by using a vector with a temperature-sensitive replicon. Subsequent analysis of induced phages showed that the protein encoded by orf13 and the repeats within orf13 were essential for phage TP901-1 amplification. In addition, analyses of internal phage DNA replication showed that the ORF13 protein and the repeats are essential for phage TP901-1 DNA replication in vivo. These results show that orf13 encodes a replication protein and that the repeats within the gene are the origin of replication.     

Bacteriophage DNA reptation]

The kinetics of reptation process of dsDNA leaving the phage head is analysed theoretically. It is assumed that the process is caused by DNA free energy decrease when it is leaving the head (DNA has to be in a globular state) for its surroundings where it is transformed into a coil state. For the analysis we have used the results of previous paper on equilibrium theory of DNA intraphage globule. Three possible cases for the ejection process friction are considered: friction in the tail-part channel, that of DNA segments with each other in the whole globule volume (it is essential for the collective way of the globule decondensation with simultaneous movement of all the loops--the first type way), the globule friction with internal capsid surface (it is most essential for the decondensation by the way of the globule rotation as a whole "spool"--the second type way). The first way would correspond to the greatest ejection time. The known experimental data on distinguishing ejection kinetics for phages with short and long tail-parts allow us to formulate arguments in favor of realization of the second way in nature.     

Gene 19 of plasmid R1 is required for both efficient conjugative DNA transfer and bacteriophage R17 infection.

F-like plasmids require a number of genes for conjugation, including tra operon genes and genes traM and traJ, which lie outside the tra operon. We now establish that a gene in the "leading region," gene 19, provides an important function during conjugation and RNA phage infection. Mutational inactivation of gene 19 on plasmid R1-16 by introduction of two nonpolar stop codons results in a 10-fold decrease in the conjugation frequency. Furthermore, infection studies with the male-specific bacteriophage R17 revealed that the phage is not able to form clear plaques in Escherichia coli cells carrying an R1-16 plasmid with the defective copy of gene 19. The total number of cells infected by phage R17 is reduced by a factor of 10. Both the conjugation- and infection-attenuated phenotypes caused by the defective gene 19 can be complemented in trans by introducing gene 19 alleles encoding the wild-type protein. Restoration of the normal phenotypes is also possible by introduction of the pilT gene encoded by the unrelated IncI plasmid R64. Our functional studies and similarities of protein 19 to proteins encoded by other DNA transfer systems, as well as the presence of a conserved motif in all of these proteins (indicative for a putative muramidase activity) suggest that protein 19 of plasmid R1 facilitates the passage of DNA during conjugation and entry of RNA during phage infection.     

Host genetic requirements for DNA release of lactococcal phage TP901-1

The first step in phage infection is the recognition of, and adsorption to, a receptor located on the host cell surface. This reversible host adsorption step is commonly followed by an irreversible event, which involves phage DNA delivery or release into the bacterial cytoplasm. The molecular components that trigger this latter event are unknown for most phages of Gram-positive bacteria. In the current study, we present a comparative genome analysis of three mutants of Lactococcus cremoris 3107, which are resistant to the P335 group phage TP901-1 due to mutations that affect TP901-1 DNA release. Through genetic complementation and phage infection assays, a predicted lactococcal three-component glycosylation system (TGS) was shown to be required for TP901-1 infection. Major cell wall saccharidic components were analysed, but no differences were found. However, heterologous gene expression experiments indicate that this TGS is involved in the glucosylation of a cell envelope-associated component that triggers TP901-1 DNA release. To date, a saccharide modification has not been implicated in the DNA delivery process of a Gram-positive infecting phage.     

Pressure built by DNA packing inside virions: enough to drive DNA ejection in vitro, largely insufficient for delivery into the bacterial cytoplasm

Tailed bacteriophage particles carry DNA highly pressurized inside the capsid. Challenge with their receptor promotes release of viral DNA. We show that addition of the osmolyte polyethylene glycol (PEG) has two distinct effects in bacteriophage SPP1 DNA ejection. One effect is to inhibit the trigger for DNA ejection. The other effect is to exert an osmotic pressure that controls the extent of DNA released in phages that initiate ejection. We carried out independent measurements of each effect, which is an essential requirement for their quantitative study. The fraction of phages that do not eject increased linearly with the external osmotic pressure. In the remaining phage particles ejection stopped after a defined amount of DNA was reached inside the capsid. Direct measurement of the size of non-ejected DNA by gel electrophoresis at different PEG concentrations in the latter sub-population allowed determination of the external osmotic pressure that balances the force powering DNA exit (47 atm for SPP1 wild-type). DNA exit stops when the ejection force mainly due to repulsion between DNA strands inside the SPP1 capsid equalizes the force resisting DNA insertion into the PEG solution. Considering the turgor pressure in the Bacillus subtilis cytoplasm the energy stored in the tight phage DNA packing is only sufficient to power entry of the first 17% of the SPP1 chromosome into the cell, the remaining 83% requiring application of additional force for internalization.