Polymerization of bacteriophage phi 29 replication protein p1 into protofilament sheets.

Protein p1 (85 amino acids) of the Bacillus subtilis phage phi29 is a membrane-associated protein required for in vivo viral DNA replication. In the present study, we have constructed two fusion proteins, maltose-binding protein (MalE)-p1 and MalE-p1DeltaN33. By using both sedimentation assays and negative-stain electron microscopy analysis, we demonstrated that MalE-p1 molecules self-associated into long filamentous structures, which did not assemble further into larger arrays. These structures were constituted by a core of protein p1 surrounded by MalE subunits. After removal of the MalE component by cleavage with protease factor Xa, the resulting protein p1 filaments tended to associate, forming bundles. The MalE-p1DeltaN33 fusion protein, however, did not self-interact in solution. Nevertheless, after being separated from the MalE domain by factor Xa digestion, protein p1DeltaN33 assembled into long protofilaments that associated in a highly ordered, parallel array forming large two-dimensional sheets. These structures resemble eukaryotic tubulin and bacterial FtsZ polymers. In addition, we show that protein p1 influences the rate of in vivo phi29 DNA synthesis in a temperature-dependent manner. We propose that protein p1 is a component of a viral-encoded structure that associates with the bacterial membrane. This structure would provide an anchoring site for the viral DNA replication machinery.     

Compartmentalization of phage phi29 DNA replication: interaction between the primer terminal protein and the membrane-associated protein p1

The bacteriophage phi29 replication protein p1 (85 amino acids) is membrane associated in Bacillus subtilis-infected cells. The C-terminal 52 amino acid residues of p1 are sufficient for assembly into protofilament sheet structures. Using chemical cross-linking experiments, we demonstrate here that p1DeltaC43, a C-terminally truncated p1 protein that neither associates with membranes in vivo nor self-interacts in vitro, can interact with the primer terminal protein (TP) in vitro. Like protein p1, plasmid-encoded protein p1DeltaC43 reduces the rate of phi29 DNA replication in vivo in a dosage-dependent manner. We also show that truncated p1 proteins that retain the N-terminal 42 amino acids, when present in excess, interfere with the in vitro formation of the TP.dAMP initiation complex in a reaction that depends on the efficient formation of a primer TP-phi29 DNA polymerase heterodimer. This interference is suppressed by increasing the concentration of either primer TP or phi29 DNA polymerase. We propose a model for initiation of in vivo phi29 DNA replication in which the viral replisome attaches to a membrane-associated p1-based structure.     

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.     

The phage phi29 membrane protein p16.7, involved in DNA replication, is required for efficient ejection of the viral genome

It is becoming clear that in vivo phage DNA ejection is not a mere passive process. In most cases, both phage and host proteins seem to be involved in pulling at least part of the viral DNA inside the cell. The DNA ejection mechanism of Bacillus subtilis bacteriophage phi29 is a two-step process where the linear DNA penetrates the cell with a right-left polarity. In the first step approximately 65% of the DNA is pushed into the cell. In the second step, the remaining DNA is actively pulled into the cytoplasm. This step requires protein p17, which is encoded by the right-side early operon that is ejected during the first push step. The membrane protein p16.7, also encoded by the right-side early operon, is known to play an important role in membrane-associated phage DNA replication. In this work we show that, in addition, p16.7 is required for efficient execution of the second pull step of DNA ejection.     

A genetic approach to the identification of functional amino acids in protein p6 of Bacillus subtilis phage ø29

Protein p6 of the Bacillus subtilis phage ø29 is essential for in vivo viral DNA replication. This protein activates the initiation of ø29 DNA replication in vitro by forming a multimeric nucleoprotein complex at the replication origins. The N-terminal region of protein p6 is involved in DNA binding, as shown by in vitro studies with p6 proteins altered by deletions or missense mutations. We report on the development of an in vivo functional assay for protein p6. This assay is based on the ability of protein p6-producing B. subtilis non-suppressor (su ^?) cells to support growth of a ø29 sus6 mutant phage. We have used this trans-complementation assay to investigate the effect on in vivo viral DNA synthesis of missense mutations introduced into the protein p6 N-terminal region. The alteration of lysine to alanine at position 2 resulted in a partially functional protein, whereas the replacement of arginine by alanine at position 6 gave rise to an inactive protein. These results indicate that arginine at position 6 is critical for the in vivo activity of protein p6. Our complementation system provides a useful genetic approach for the identification of functionally important amino acids in protein p6.     

A genetic approach to the identification of functional amino acids in protein p6 of Bacillus subtilis phage ?29

Protein p6 of the Bacillus subtilis phage ø29 is essential for in vivo viral DNA replication. This protein activates the initiation of ø29 DNA replication in vitro by forming a multimeric nucleoprotein complex at the replication origins. The N-terminal region of protein p6 is involved in DNA binding, as shown by in vitro studies with p6 proteins altered by deletions or missense mutations. We report on the development of an in vivo functional assay for protein p6. This assay is based on the ability of protein p6-producing B. subtilis non-suppressor (su ^–) cells to support growth of a ø29 sus6 mutant phage. We have used this trans-complementation assay to investigate the effect on in vivo viral DNA synthesis of missense mutations introduced into the protein p6 N-terminal region. The alteration of lysine to alanine at position 2 resulted in a partially functional protein, whereas the replacement of arginine by alanine at position 6 gave rise to an inactive protein. These results indicate that arginine at position 6 is critical for the in vivo activity of protein p6. Our complementation system provides a useful genetic approach for the identification of functionally important amino acids in protein p6.     

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.     

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.     

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.     

A uracil-DNA glycosylase inhibitor encoded by a non-uracil containing viral DNA

Uracil-DNA glycosylase (UDG) is an enzyme involved in the base excision repair pathway. It specifically removes uracil from both single-stranded and double-stranded DNA. The genome of the Bacillus subtilis phage 29 is a linear double-stranded DNA with a terminal protein covalently linked at each 5'-end. Replication of 29 DNA starts by a protein-priming mechanism and generates intermediates that have long stretches of single-stranded DNA. By using in vivo chemical cross-linking and affinity chromatography techniques, we found that UDG is a cellular target for the early viral protein p56. Addition of purified protein p56 to B. subtilis extracts inhibited the endogenous UDG activity. Moreover, extracts from 29-infected cells were deficient in UDG activity. We suggested that inhibition of the cellular UDG is a defense mechanism developed by 29 to prevent the action of the base excision repair pathway if uracil residues arise in their replicative intermediates. Protein p56 is the first example of a UDG inhibitor encoded by a non-uracil-containing viral DNA.     

Mechanism of stimulation of DNA replication by bacteriophage phi 29 single-stranded DNA-binding protein p5

Protein p5 is a Bacillus subtilis phage phi 29-encoded protein required for phi 29 DNA replication in vivo. Protein p5 has single-stranded DNA binding (SSB) capacity and stimulates in vitro DNA replication severalfold when phi 29 DNA polymerase is used to replicate either the natural phi 29 DNA template or primed M13 single-stranded DNA (ssDNA). Furthermore, other SSB proteins, including Escherichia coli SSB, T4 gp32, adenovirus DNA-binding protein, and human replication factor A, can functionally substitute for protein p5. The stimulatory effect of phi 29 protein p5 is not due to an increase of the DNA replication rate. When both phi 29 DNA template and M13 competitor ssDNA are added simultaneously to the replication reaction, phi 29 DNA replication is strongly inhibited. This inhibition is fully overcome by adding protein p5, suggesting that protein p5-coated M13 ssDNA is no longer able to compete for replication factors, probably phi 29 DNA polymerase, which has a strong affinity for ssDNA. Electron microscopy demonstrates that protein p5 binds to M13 ssDNA forming saturated complexes with a smoothly contoured appearance and producing a 2-fold reduction of the DNA length. Protein p5 also binds to ssDNA in the phi 29 replicative intermediates produced in vitro, which are similar in structure to those observed in vivo. Our results strongly suggest that phi 29 protein p5 is the phi 29 SSB protein active during phi 29 DNA replication.     

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.