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

DNA-Binding Proteins Essential for Protein-Primed Bacteriophage Φ29 DNA Replication

Bacillus subtilis phage Φ29 has a linear, double-stranded DNA 19 kb long with an inverted terminal repeat of 6 nucleotides and a protein covalently linked to the 5′ ends of the DNA. This protein, called terminal protein (TP), is the primer for the initiation of replication, a reaction catalyzed by the viral DNA polymerase at the two DNA ends. The DNA polymerase further elongates the nascent DNA chain in a processive manner, coupling strand displacement with elongation. The viral protein p5 is a single-stranded DNA binding protein (SSB) that binds to the single strands generated by strand displacement during the elongation process. Viral protein p6 is a double-stranded DNA binding protein (DBP) that preferentially binds to the origins of replication at the Φ29 DNA ends and is required for the initiation of replication. Both SSB and DBP are essential for Φ29 DNA amplification. This review focuses on the role of these phage DNA-binding proteins in Φ29 DNA replication both in vitro and in vivo, as well as on the implication of several B. subtilis DNA-binding proteins in different processes of the viral cycle. We will revise the enzymatic activities of the Φ29 DNA polymerase: TP-deoxynucleotidylation, processive DNA polymerization coupled to strand displacement, 3′–5′ exonucleolysis and pyrophosphorolysis. The resolution of the Φ29 DNA polymerase structure has shed light on the translocation mechanism and the determinants responsible for processivity and strand displacement. These two properties have made Φ29 DNA polymerase one of the main enzymes used in the current DNA amplification technologies. The determination of the structure of Φ29 TP revealed the existence of three domains: the priming domain, where the primer residue Ser232, as well as Phe230, involved in the determination of the initiating nucleotide, are located, the intermediate domain, involved in DNA polymerase binding, and the N-terminal domain, responsible for DNA binding and localization of the TP at the bacterial nucleoid, where viral DNA replication takes place. The biochemical properties of the Φ29 DBP and SSB and their function in the initiation and elongation of Φ29 DNA replication, respectively, will be described.

Dissecting the role of the ϕ29 terminal protein DNA binding residues in viral DNA replication

Phage ϕ29 DNA replication takes place by a protein-priming mechanism in which the viral DNA polymerase catalyses the covalent linkage of the initiating nucleotide to a specific serine residue of the terminal protein (TP). The N-terminal domain of the ϕ29 TP has been shown to bind to the host DNA in a sequence-independent manner and this binding is essential for the TP nucleoid localisation and for an efficient viral DNA replication in vivo. In the present work we have studied the involvement of the TP N-terminal domain residues responsible for DNA binding in the different stages of viral DNA replication by assaying the in vitro activity of purified TP N-terminal mutant proteins. The results show that mutation of TP residues involved in DNA binding affects the catalytic activity of the DNA polymerase in initiation, as the K_m for the initiating nucleotide is increased when these mutant proteins are used as primers. Importantly, this initiation defect was relieved by using the ϕ29 double-stranded DNA binding protein p6 in the reaction, which decreased the K_m of the DNA polymerase for dATP about 130–190 fold. Furthermore, the TP N-terminal domain was shown to be required both for a proper interaction with the DNA polymerase and for an efficient viral DNA amplification.

A Variant Protein from φ29 Replication Gene, Gene 1, Did Not Form Homo-Polymer Due to a Single Amino Acid Substitution Near the Carboxyl Terminus

For study of the self-association of the product of psi29 gene 1, one variant which has a substitution at the 71(st) amino acid was used. By glycerol gradient sedimentation, the product of wild-type gene 1 existed both as large aggregate and oligomer, whereas the variant was detected as a single peak of monomer size. According to experiments using His-tagged proteins and Ni-NTA magnetic beads, the variant made only a little self-associated complex. From these results, a site essential for self-association was suggested to exist close to the carboxyl terminus of the product of psi29 gene 1.

Functional linkages between replication proteins of genes 1, 3 and 5 of Bacillus subtilis phage φ29

Gene 1 product (gp1) of Bacillus subtilis phage φ29 has been shown to be involved in viral DNA replication in vivo, but the essential role is still unknown. As part of an ongoing effort to understand the role of gp1 in viral DNA replication, we investigated genetic interaction between gene 1 and other viral genes. Because φ29 mutants which do not produce functional gp1 show temperature-sensitive growth, we isolated temperature-resistant phages from the φ29 gene 1 mutants, and eventually, obtained nine extragenic suppressors. These suppressor mutations were located in two essential genes for φ29 DNA replication in vivo: gene 3 encoding terminal/primer protein (gp3) or gene 5 encoding viral single-stranded DNA binding protein (gp5). Most of these mutations resulted in single amino acid substitutions in the products. By trans-complementation assay, we confirmed that the absence of gp1 at non-permissive temperature can be compensated by the suppressors which have the single amino acid substitution in either gp5 or gp3. These results indicate that gp1 has functional relationship to gp5 and gp3. From the positions of amino acid substitutions in gp3, we propose its new regulatory subdomain at which other molecules including gp1 would interact with and regulate functions of gp3.

Phage 29 phi protein p1 promotes replication by associating with the FtsZ ring of the divisome in Bacillus subtilis

During evolution, viruses have optimized the interaction with host factors to increase the efficiency of fundamental processes such as DNA replication. Bacteriophage 29 protein p1 is a membrane-associated protein that forms large protofilament sheets that resemble eukaryotic tubulin and bacterial filamenting temperature-sensitive mutant Z protein (FtsZ) polymers. In the absence of protein p1, phage 29 DNA replication is impaired. Here we show that a functional fusion of protein p1 to YFP localizes at the medial region of Bacillus subtilis cells independently of other phage-encoded proteins. We also show that 29 protein p1 colocalizes with the B. subtilis cell division protein FtsZ and provide evidence that FtsZ and protein p1 are associated. Importantly, the midcell localization of YFP-p1 was disrupted in a strain that does not express FtsZ, and the fluorescent signal was distributed all over the cell. Depletion of penicillin-binding protein 2B (PBP2B) in B. subtilis cells did not affect the subcellular localization of YFP-p1, indicating that its distribution does not depend on septal wall synthesis. Interestingly, when 29 protein p1 was expressed, B. subtilis cells were about 1.5-fold longer than control cells, and the accumulation of 29 DNA was higher in mutant B. subtilis cells with increased length. We discuss the biological role of p1 and FtsZ in the 29 growth cycle.

Role of host factors in bacteriophage φ29 DNA replication

During the course of evolution, viruses have learned to take advantage of the natural resources of their hosts for their own benefit. Due to their small dimension and limited size of genomes, bacteriophages have optimized the exploitation of bacterial host factors to increase the efficiency of DNA replication and hence to produce vast progeny. The Bacillus subtilis phage φ29 genome consists of a linear double-stranded DNA molecule that is duplicated by means of a protein-primed mode of DNA replication. Its genome has been shown to be topologically constrained at the size of the bacterial nucleoid and, as to avoid generation of positive supercoiling ahead of the replication forks, the bacterial DNA gyrase is used by the phage. In addition, the B. subtilis actin-like MreB cytoskeleton plays a crucial role in the organization of φ29 DNA replication machinery in peripheral helix-like structures. Thus, in the absence of an intact MreB cytoskeleton, φ29 DNA replication is severely impaired. Importantly, MreB interacts directly with the phage membrane protein p16.7, responsible for attaching φ29 DNA at the cell membrane. Moreover, the φ29-encoded protein p56 inhibits host uracil-DNA glycosylase activity and has been proposed to be a defense mechanism developed by the phage to prevent the action of the base excision repair pathway if uracil residues arise in replicative intermediates. All of them constitute incoming examples on how viruses have profited from the cellular machinery of their hosts.

Bacteriophage tubulins: carrying their own cytoskeleton key

Cytoskeletal elements are well known to be widespread in eukaryotes and prokaryotes, providing important, diverse functions for cells large and small. Two new studies report that some bacteriophages encode their own tubulin homologs to facilitate phage reproduction within the host cell.

Bacteriophage protein-protein interactions

Bacteriophages T7, λ, P22, and P2/P4 (from Escherichia coli), as well as ϕ29 (from Bacillus subtilis), are among the best-studied bacterial viruses. This chapter summarizes published protein interaction data of intraviral protein interactions, as well as known phage-host protein interactions of these phages retrieved from the literature. We also review the published results of comprehensive protein interaction analyses of Pneumococcus phages Dp-1 and Cp-1, as well as coliphages λ and T7. For example, the ≈55 proteins encoded by the T7 genome are connected by ≈43 interactions with another ≈15 between the phage and its host. The chapter compiles published interactions for the well-studied phages λ (33 intra-phage/22 phage-host), P22 (38/9), P2/P4 (14/3), and ϕ29 (20/2). We discuss whether different interaction patterns reflect different phage lifestyles or whether they may be artifacts of sampling. Phages that infect the same host can interact with different host target proteins, as exemplified by E. coli phage λ and T7. Despite decades of intensive investigation, only a fraction of these phage interactomes are known. Technical limitations and a lack of depth in many studies explain the gaps in our knowledge. Strategies to complete current interactome maps are described. Although limited space precludes detailed overviews of phage molecular biology, this compilation will allow future studies to put interaction data into the context of phage biology.

Involvement of phage phi29 DNA polymerase and terminal protein subdomains in conferring specificity during initiation of protein-primed DNA replication

To initiate ϕ29 DNA replication, the DNA polymerase has to form a complex with the homologous primer terminal protein (TP) that further recognizes the replication origins of the homologous TP-DNA placed at both ends of the linear genome. By means of chimerical proteins, constructed by swapping the priming domain of the related ϕ29 and GA-1 TPs, we show that DNA polymerase can form catalytically active heterodimers exclusively with that chimerical TP containing the N-terminal part of the homologous TP, suggesting that the interaction between the polymerase TPR-1 subdomain and the TP N-terminal part is the one mainly responsible for the specificity between both proteins. We also show that the TP N-terminal part assists the proper binding of the priming domain at the polymerase active site. Additionally, a chimerical ϕ29 DNA polymerase containing the GA-1 TPR-1 subdomain could use GA-1 TP, but only in the presence of ϕ29 TP-DNA as template, indicating that parental TP recognition is mainly accomplished by the DNA polymerase. The sequential events occurring during initiation of bacteriophage protein-primed DNA replication are proposed.

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.

Effects of single amino acid substitutions at the predicted coiled-coil or hydrophobic region on the self-assembly of phi29 replication protein, gp1

Gp1, the product of one of the essential genes of phi29 replication, is an RNA binding protein and self-associates to form large complexes. Furthermore, gp1 suppresses the synthesis of phi29 DNA polymerase and primer protein in the post-transcriptional process. In this report, we have employed seven variants with single amino acid substitutions to analyze the self-assembly of gp1. Using chemical cross-linking and sedimentation assays, amino acid substitutions within the predicted coiled-coil or hydrophobic region were shown to strongly affect the formation of large complexes, suggesting that these two regions were required for the self-assembly of gp1. The self-association of gp1 was suggested to be necessary for the efficient binding to RNA and the translational repression.

Compartmentalization of prokaryotic DNA replication

It becomes now apparent that prokaryotic DNA replication takes place at specific intracellular locations. Early studies indicated that chromosomal DNA replication, as well as plasmid and viral DNA replication, occurs in close association with the bacterial membrane. Moreover, over the last several years, it has been shown that some replication proteins and specific DNA sequences are localized to particular subcellular regions in bacteria, supporting the existence of replication compartments. Although the mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown, the docking of replication factors to large organizing structures may be important for the assembly of active replication complexes. In this article, we review the current state of this subject in two bacterial species, Escherichia coli and Bacillus subtilis, focusing our attention in both chromosomal and extrachromosomal DNA replication. A comparison with eukaryotic systems is also presented.

Isolation of a series of single missense mutants of a dna gene of phage .PHI.29, gene 1, utilizing their inhibitory effect on E. coli growth

Gene 1 product (gp1) of Bacillus subtilis phage psi29 is known to promote DNA replication of the phage. Although its role in the DNA replication is not clear, gp1 is reported to exhibit multiple characteristics, including RNA binding, cell membrane localization, and self-association. To investigate these characteristics, we undertook the isolation of a series of missense mutants of gene 1 bearing substitutions at various regions. During cloning of gene 1, we found that its expression severely inhibited the growth of its host Escherichia coli cells. In this study, we utilized this growth-inhibition phenomenon to screen a random library muta-genized by error-prone PCR, expecting that mutants which could not inhibit cell growth would be affected in the authentic functions of gp1. Using this approach, we obtained 31 different mutants bearing single amino acid substitutions at 26 positions along the entire length of gp1. As a preliminary analysis of these mutants, we compared the deduced amino acid sequences of gp1s from psi29 and its related phages PZA, B103 and M2. Alignment of these sequences revealed three conserved regions, i.e. a hydrophobic region near the carboxyl terminus (assumed to be involved in the membrane localization and self-association of gp1), coiled-coil motif (essential for self-association), and a region of unknown function near the amino terminus. Interestingly, many of the substitutions in the isolated mutants occurred at strongly conserved residues in these regions and affected characteristic features of the regions (e.g. hydrophobicity of the hydrophobic region). These substitutions are expected to affect authentic functions of gp1, and the mutants will be useful for studies of the structure and functions of gp1.

Phage phi29 proteins p1 and p17 are required for efficient binding of architectural protein p6 to viral DNA in vivo

Bacteriophage phi29 protein p6 is a viral architectural protein, which binds along the whole linear phi29 DNA in vivo and is involved in initiation of DNA replication and transcription control. Protein p1 is a membrane-associated viral protein, proposed to attach the viral genome to the cell membrane. Protein p17 is involved in pulling phi29 DNA into the cell during the injection process. We have used chromatin immunoprecipitation and real-time PCR to analyze in vivo p6 binding to DNA in cells infected with phi29 sus1 or sus17 mutants; in both cases p6 binding is significantly decreased all along phi29 DNA. phi29 DNA is topologically constrained in vivo, and p6 binding is highly increased in the presence of novobiocin, a gyrase inhibitor that produces a loss of DNA negative superhelicity. Here we show that, in cells infected with phi29 sus1 or sus17 mutants, the increase of p6 binding by novobiocin is even higher than in cells containing p1 and p17, alleviating the p6 binding deficiency. Therefore, proteins p1 and p17 could be required to restrain the proper topology of phi29 DNA, which would explain the impaired DNA replication observed in cells infected with sus1 or sus17 mutants.

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.

A single amino acid substitution within a coiled-coil motif changes the assembly of a 53-amino acid protein from two-dimensional sheets to filamentous structures

The bacteriophage phi29 replication protein p1 self-interacts in vitro, generating highly ordered structures. Specifically, the 53-amino acid protein p1DeltaN33, which retains the sequence of p1 spanning amino acids Met(34) to Lys(85), assembles into two-dimensional protofilament sheets. The region of protein p1 located between residues Glu(38) and Asn(65) presumably forms an alpha-helical coiled-coil structure. Here we have examined the role of this coiled-coil sequence in the formation of protofilament sheets. Using sedimentation assays and negative-stain electron microscopy analysis, we demonstrate that residues Leu(46), Met(53), and Leu(60), but not Leu(39), are essential for p1DeltaN33 assembly into sheets. Remarkably, replacement of Leu(46) by Val shifts the pathway of molecular assembly, leading to the formation of filamentous polymers approximately 10 nm in diameter. These results show, for the first time, that a short coiled-coil motif can mediate protein assembly into protofilament sheet structures.

Phi29 family of phages

Continuous research spanning more than three decades has made the Bacillus bacteriophage phi29 a paradigm for several molecular mechanisms of general biological processes, such as DNA replication, regulation of transcription, phage morphogenesis, and phage DNA packaging. The genome of bacteriophage phi29 consists of a linear double-stranded DNA (dsDNA), which has a terminal protein (TP) covalently linked to its 5' ends. Initiation of DNA replication, carried out by a protein-primed mechanism, has been studied in detail and is considered to be a model system for the protein-primed DNA replication that is also used by most other linear genomes with a TP linked to their DNA ends, such as other phages, linear plasmids, and adenoviruses. In addition to a continuing progress in unraveling the initiation of DNA replication mechanism and the role of various proteins involved in this process, major advances have been made during the last few years, especially in our understanding of transcription regulation, the head-tail connector protein, and DNA packaging. Recent progress in all these topics is reviewed. In addition to phi29, the genomes of several other Bacillus phages consist of a linear dsDNA with a TP molecule attached to their 5' ends. These phi29-like phages can be divided into three groups. The first group includes, in addition to phi29, phages PZA, phi15, and BS32. The second group comprises B103, Nf, and M2Y, and the third group contains GA-1 as its sole member. Whereas the DNA sequences of the complete genomes of phi29 (group I) and B103 (group II) are known, only parts of the genome of GA-1 (group III) were sequenced. We have determined the complete DNA sequence of the GA-1 genome, which allowed analysis of differences and homologies between the three groups of phi29-like phages, which is included in this review.

Phi29 family of phages

Continuous research spanning more than three decades has made the Bacillus bacteriophage phi29 a paradigm for several molecular mechanisms of general biological processes, such as DNA replication, regulation of transcription, phage morphogenesis, and phage DNA packaging. The genome of bacteriophage phi29 consists of a linear double-stranded DNA (dsDNA), which has a terminal protein (TP) covalently linked to its 5' ends. Initiation of DNA replication, carried out by a protein-primed mechanism, has been studied in detail and is considered to be a model system for the protein-primed DNA replication that is also used by most other linear genomes with a TP linked to their DNA ends, such as other phages, linear plasmids, and adenoviruses. In addition to a continuing progress in unraveling the initiation of DNA replication mechanism and the role of various proteins involved in this process, major advances have been made during the last few years, especially in our understanding of transcription regulation, the head-tail connector protein, and DNA packaging. Recent progress in all these topics is reviewed. In addition to phi29, the genomes of several other Bacillus phages consist of a linear dsDNA with a TP molecule attached to their 5' ends. These phi29-like phages can be divided into three groups. The first group includes, in addition to phi29, phages PZA, phi15, and BS32. The second group comprises B103, Nf, and M2Y, and the third group contains GA-1 as its sole member. Whereas the DNA sequences of the complete genomes of phi29 (group I) and B103 (group II) are known, only parts of the genome of GA-1 (group III) were sequenced. We have determined the complete DNA sequence of the GA-1 genome, which allowed analysis of differences and homologies between the three groups of phi29-like phages, which is included in this review.