Subtilis Phage Research Articles

Structural and Functional Analysis of ϕ29 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.

Alanine Scanning and Fe-BABE Probing of the Bacteriophage ø29 Prohead RNA–Connector Interaction

The DNA packaging motor of the Bacillus subtilis bacteriophage ø29 prohead is comprised in part of an oligomeric ring of 174 base RNA molecules (pRNA) positioned near the N termini of subunits of the dodecameric head–tail connector. Deletion and alanine substitution mutants in the connector protein (gp10) N terminus were assembled into proheads in Escherichia coli and the particles tested for pRNA binding and DNA–gp3 packaging in vitro. The basic amino acid residues RKR at positions 3–5 of the gp10 N terminus were central to pRNA binding during assembly of an active DNA packaging motor. Conjugation of iron(S)-1-(p-bromoacetamidobenzyl) ethylenediaminetetraacetate (Fe-BABE) to residue S170C in the narrow end of the connector, near the N terminus, permitted hydroxyl radical probing of bound [32P]pRNA and identified two discrete sites proximal to this residue: the C-helix at the junction of the A, C and D helices, and the E helix and the CE loop/D loop of the intermolecular base pairing site.

Does Bacteriophage φ29 Pack Its DNA with a Twist?

You probably never tried to put toothpaste back into the tube, but if you did, you’d have a good idea of what the Bacillus subtilis bacteriophage ϕ29 experiences as it crams its DNA into a protein capsid shell following replication. Scientists have speculated that this bacteria-infecting “phage” accomplishes this energy-intensive task by rotating a connector complex at the opening that feeds the DNA into the capsid as it turns, and that this process is fueled by the breakdown of ATP by an associated ring of ATPases. But until now there has been no way to show whether that’s really what happens.

DNA segregation by the bacterial actin AlfA during Bacillus subtilis growth and development

We here identify a protein (AlfA; actin like filament) that defines a new family of actins that are only distantly related to MreB and ParM. AlfA is required for segregation of Bacillus subtilis plasmid pBET131 (a mini pLS32-derivative) during growth and sporulation. A 3-kb DNA fragment encoding alfA and a downstream gene (alfB) is necessary and sufficient for plasmid stability. AlfA-GFP assembles dynamic cytoskeletal filaments that rapidly turn over (t(1/2)< approximately 45 s) in fluorescence recovery after photobleaching experiments. A point mutation (alfA D168A) that completely inhibits AlfA subunit exchange in vivo is strongly defective for plasmid segregation, demonstrating that dynamic polymerization of AlfA is necessary for function. During sporulation, plasmid segregation occurs before septation and independently of the DNA translocase SpoIIIE and the chromosomal Par proteins Soj and Spo0J. The absence of the RacA chromosome anchoring protein reduces the efficiency of plasmid segregation (by about two-fold), suggesting that it might contribute to anchoring the plasmid at the pole during sporulation. Our results suggest that the dynamic polymerization of AlfA mediates plasmid separation during both growth and sporulation.

The minor capsid protein gp7 of bacteriophage SPP1 is required for efficient infection of Bacillus subtilis

Gp7 is a minor capsid protein of the Bacillus subtilis bacteriophage SPP1. Homologous proteins are found in numerous phages but their function remained unknown. Deletion of gene 7 from the SPP1 genome yielded a mutant phage (SPP1del7) with reduced burst-size. SPP1del7 infections led to normal assembly of virus particles whose morphology, DNA and protein composition was undistinguishable from wild-type virions. However, only approximately 25% of the viral particles that lack gp7 were infectious. SPP1del7 particles caused a reduced depolarization of the B. subtilis membrane in infection assays suggesting a defect in virus genome traffic to the host cell. A higher number of SPP1del7 DNA ejection events led to abortive release of DNA to the culture medium when compared with wild-type infections. DNA ejection in vitro showed that no detectable gp7 is co-ejected with the SPP1 genome and that its presence in the virion correlated with anchoring of released DNA to the phage particle. The release of DNA from wild-type phages was slower than that from SPP1del7 suggesting that gp7 controls DNA exit from the virion. This feature is proposed to play a central role in supporting correct routing of the phage genome from the virion to the cell cytoplasm.

Spo0A, the key transcriptional regulator for entrance into sporulation, is an inhibitor of DNA replication

The transcription factor Spo0A is a master regulator for entry into sporulation in Bacillus subtilis and also regulates expression of the virulent B. subtilis phage phi29. Here, we describe a novel function for Spo0A, being an inhibitor of DNA replication of both, the phi29 genome and the B. subtilis chromosome. Binding of Spo0A near the phi29 DNA ends, constituting the two origins of replication of the linear phi29 genome, prevents formation of phi29 protein p6-nucleoprotein initiation complex resulting in inhibition of phi29 DNA replication. At the B. subtilis oriC, binding of Spo0A to specific sequences, which mostly coincide with DnaA-binding sites, prevents open complex formation. Thus, by binding to the origins of replication, Spo0A prevents the initiation step of DNA replication of either genome. The implications of this novel role of Spo0A for phage phi29 development and the bacterial chromosome replication during the onset of sporulation are discussed.

Modulation of the Viral ATPase Activity by the Portal Protein Correlates with DNA Packaging Efficiency

DNA packaging in tailed bacteriophages and herpesviruses requires assembly of a complex molecular machine at a specific vertex of a preformed procapsid. As in all these viruses, the DNA translocation motor of bacteriophage SPP1 is composed of the portal protein (gp6) that provides a tunnel for DNA entry into the procapsid and of the viral ATPase (gp1-gp2 complex) that fuels DNA translocation. Here we studied the cross-talk between the components of the motor to control its ATP consumption and DNA encapsidation. We showed that gp6 embedded in the procapsid structure stimulated more than 10-fold the gp2 ATPase activity. This stimulation, which was significantly higher than the one conferred by isolated gp6, depended on the presence of gp1. Mutations in different regions of gp6 abolished or decreased the gp6-induced stimulation of the ATPase. This effect on gp2 activity was observed both in the presence and in the absence of DNA and showed a strict correlation with the efficiency of DNA packaging into procapsids containing the mutant portals. Our results demonstrated that the portal protein has an active control over the viral ATPase activity that correlates with the performance of the DNA packaging motor.

Quaternary Polymorphism of Replicative Helicase G 40P: Structural Mapping and Domain Rearrangement

Quaternary polymorphism is a distinctive structural feature of the DnaB family of replicative DNA hexameric helicases. The Bacillus subtilis bacteriophage SPP1 gene 40 product (G40P) belongs to this family. Three different quaternary states have been described for G40P homohexamers, two of them with C(3) symmetry, and the other with C(6) symmetry. We present three-dimensional reconstructions of the different architectures of G40P hexamers and a variant lacking the N-terminal domain. Comparison of the G40P and the deletion mutant structures sheds new light on the functional roles of the N and C-terminal domains, at the same time that it allows the direct structural mapping of these domains. Based on this new information, hybrid EM/X-ray models are presented for all the different symmetries. These results suggest that quaternary polymorphism of hexameric helicases may be implicated in the translocation along the DNA.

Structural Basis for Membrane Anchorage of Viral ϕ29 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.

Mechanism of Force Generation of a Viral DNA Packaging Motor

A large family of multimeric ATPases are involved in such diverse tasks as cell division, chromosome segregation, DNA recombination, strand separation, conjugation, and viral genome packaging. One such system is the Bacillus subtilis phage phi 29 DNA packaging motor, which generates large forces to compact its genome into a small protein capsid. Here we use optical tweezers to study, at the single-molecule level, the mechanism of force generation in this motor. We determine the kinetic parameters of the packaging motor and their dependence on external load to show that DNA translocation does not occur during ATP binding but is likely triggered by phosphate release. We also show that the motor subunits act in a coordinated, successive fashion with high processivity. Finally, we propose a minimal mechanochemical cycle of this DNA-translocating ATPase that rationalizes all of our findings.

Structure of the Functional Domain of φ29 Replication Organizer: INSIGHTS INTO OLIGOMERIZATION AND DNA BINDING

The Bacillus subtilis phage phi29-encoded membrane protein p16.7 is one of the few proteins involved in prokaryotic membrane-associated DNA replication that has been characterized at a functional and biochemical level. In this work we have determined both the solution and crystal structures of its dimeric functional domain, p16.7C. Although the secondary structure of p16.7C is remarkably similar to that of the DNA binding homeodomain, present in proteins belonging to a large family of eukaryotic transcription factors, the tertiary structures of p16.7C and homeodomains are fundamentally different. In fact, p16.7C defines a novel dimeric six-helical fold. We also show that p16.7C can form multimers in solution and that this feature is a key factor for efficient DNA binding. Moreover, a combination of NMR and x-ray approaches, combined with functional analyses of mutants, revealed that multimerization of p16.7C dimers is mediated by a large protein surface that is characterized by a striking self-complementarity. Finally, the structural analyses of the p16.7C dimer and oligomers provide important clues about how protein multimerization and DNA binding are coupled.

Crystallization and initial X-ray diffraction studies of scaffolding protein (gp7) of bacteriophage phi29.

The Bacillus subtilis bacteriophage phi29 scaffolding protein (gp7) has been crystallized by the hanging-drop vapour-diffusion method at 293 K. Two new distinct crystal forms that both differed from a previously crystallized and solved scaffolding protein were grown under the same conditions. Form I belongs to the primitive tetragonal space group P4(1)2(1)2, with unit-cell parameters a = b = 77.13, c = 37.12 A. Form II crystals exhibit an orthorhombic crystal form, with space group C222 and unit-cell parameters a = 107.50, b = 107. 80, c = 37.34 A. Complete data sets have been collected to 1.78 and 1.80 A for forms I and II, respectively, at 100 K using Cu Kalpha X-rays from a rotating-anode generator. Calculation of a VM value of 2.46 A3 Da(-1) for form I suggests the presence of one molecule in the asymmetric unit, corresponding to a solvent content of 50.90%, whereas form II has a VM of 4.80 A3 Da(-1) with a solvent content of 48.76% and two molecules in the asymmetric unit. The structures of both crystal forms are being determined by the molecular-replacement method using the coordinates of the published crystal structure of gp7.

Purification, properties and assembly of the neck-appendage protein of the Bacillus subtilis phage phi 29.

The purification of the neck appendage protein of phi 29, p12*, which is involved in the adsorption of the phage to Bacillus subtilis, is described. The purified native protein is in a dimeric form and can be assembled, in vitro, onto purified 12- particles that lack the neck appendages, suggesting that the incorporation of p12* to the rest of the phage structure is a self-assembly process. The assembly of protein p12* in vitro follows cooperative kinetics and it occurs with an efficiency of about 4%.

Phage φ29 DNA Replication Organizer Membrane Protein p16.7 Contains a Coiled Coil and a Dimeric, Homeodomain-related, Functional Domain

The Bacillus subtilis phage varphi29-encoded membrane protein p16.7 is one of the few proteins known to be involved in prokaryotic membrane-associated DNA replication. Protein p16.7 contains an N-terminal transmembrane domain responsible for membrane localization. A soluble variant lacking the N-terminal membrane anchor, p16.7A, forms dimers in solution, binds to DNA, and has affinity for the varphi29 terminal protein. Here we show that the soluble N-terminal half of p16.7A can form a dimeric coiled coil. However, a second domain, located in the C-terminal half of the protein, has been characterized as being the main domain responsible for p16.7 dimerization. This 70-residue C-terminal domain, named p16.7C, also constitutes the functional part of the protein as it binds to DNA and terminal protein. Sequence alignments, secondary structure predictions, and spectroscopic analyses suggest that p16.7C is evolutionarily related to DNA binding homeodomains, present in many eukaryotic transcriptional regulator proteins. Based on the results, a structural model of p16.7 is presented.

Bacteriophage Ø29 protein p6: an architectural protein involved in genome organization, replication and control of transcription.

Protein p6 of B. subtilis bacteriophage Ø29 binds to DNA forming a nucleoprotein complex in which the DNA wraps a protein core forming a right-handed superhelix, therefore restraining positive supercoiling and compacting the DNA. The protein does not specifically recognize a nucleotide sequence but rather a structural feature and it binds as a dimer through the minor groove. Protein p6 is in a monomer-dimer equilibrium that shifts to higher-order structures at a concentration of about 1 mM. These structures are probably present in vivo as the intracellular concentration of p6 is estimated to be in this range, and in fact the effective concentration should be still higher due to the macromolecular crowding. The p6 oligomers show an elongated shape compatible with a helical structure reminiscent of the superhelical DNA of the nucleoprotein complex, therefore it was proposed that protein p6 forms a scaffold on which the DNA folds. Since protein p6 is very abundant in infected cells, enough to bind the entire viral progeny, it was proposed to have an architectural role organizing and compacting the viral genome. It has been demonstrated that protein p6 binds in vivo to most, if not all, the Ø29 genome, although with different affinity, the highest one corresponding to the genome ends. Binding to plasmidic DNA was much lower, although it increased dramatically when the negative superhelicity was decreased. Hence, protein p6 binding specificity for Ø29 DNA is based on supercoiling, providing that the Ø29 genome, although topologically constrained, has a negative superhelicity lower than that of plasmid DNA. The formation of the nucleoprotein complex has functional implications in DNA replication and the control of transcription. It activates the initiation of replication that occurs at the genome ends for which the binding affinity is highest. It represses early transcription from promoter C2, and, together with protein p4, it represses transcription from promoters A2b and A2c and activates late transcription from promoter A3; therefore, protein p6 is involved in the early to late transcription switch.

In Vivo Assembly of Phage ϕ29 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.

The nicking homing endonuclease I-BasI is encoded by a group I intron in the DNA polymerase gene of the Bacillus thuringiensis phage Bastille.

Here we describe the discovery of a group I intron in the DNA polymerase gene of Bacillus thuringiensis phage Bastille. Although the intron insertion site is identical to that of the Bacillus subtilis phages SPO1 and SP82 introns, the Bastille intron differs from them substantially in primary and secondary structure. Like the SPO1 and SP82 introns, the Bastille intron encodes a nicking DNA endonuclease of the H-N-H family, I-BasI, with a cleavage site identical to that of the SPO1-encoded enzyme I-HmuI. Unlike I-HmuI, which nicks both intron-minus and intron-plus DNA, I-BasI cleaves only intron-minus alleles, which is a characteristic of typical homing endonucleases. Interestingly, the C-terminal portions of these H-N-H phage endonucleases contain a conserved sequence motif, the intron-encoded endonuclease repeat motif (IENR1) that also has been found in endonucleases of the GIY-YIG family, and which likely comprises a small DNA-binding module with a globular betabetaalphaalphabeta fold, suggestive of module shuffling between different homing endonuclease families.

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.

Bacteriophage Φ29 Early Protein p17: SELF-ASSOCIATION AND HETERO-ASSOCIATION WITH THE VIRAL HISTONE-LIKE PROTEIN p6

Gene 17 of the Bacillus subtilis phage Phi29 is expressed early after infection, and it has been shown to be required at the very beginning of phage replication under conditions of low but not high multiplicity of infection. It has been proposed that, at the beginning of the infection, protein p17 could be recruiting limiting amounts of initiation factors at the viral origins. Once the infection process is established and the replication proteins reach optimal concentration, protein p17 becomes dispensable. In this paper we focused, on the one hand, on the study of protein p17 dimerization and the role of a putative coiled-coil region. On the other hand, we focused on its interaction with the viral origin-binding protein p6. Based on our results we propose that protein p17 function is to optimize binding of protein p6 at the viral DNA ends, thus favoring the initiation of replication and negatively modulating its own transcription.

The role of surface-exposed lysines in wrapping DNA about the bacterial histone-like protein HU.

Several basic proteins, including the ubiquitous HU proteins, serve histone-like functions in prokaryotes. Significant sequence conservation exists between HU homologues; yet binding sites varying from 9 to 37 bp have been reported. TF1, an HU homologue with a 37 bp binding site that is encoded by the Bacillus subtilis bacteriophage SPO1, binds with nM affinity to DNA that contains 5-hydroxymethyluracil (hmU) in place of thymine and to T-containing DNA with loops. We evaluated the contribution of three conserved lysines to specifying the length of the binding site and show that Lys3 is critical for maintaining a long binding site in T-containing DNA: A mutant protein in which Lys3 is replaced with Gln(TF1-K3Q) is completely deficient in forming a stable complex. The affinity for 37 bp hmU-containing DNA is also reduced, from approximately 3 nM for wild-type TF1 to approximately 90 nM for TF1-K3Q. The decrease in affinity of TF1-K3Q for hmU-containing DNA > or = 25 bp suggests that Lys3 contacts DNA 8-9 bp distal to the sites of kinking. We propose that Lys3 forms an internal saltbridge to Asp26 in HU homologues characterized by shorter binding sites and that its surface exposure, and hence a longer binding site, may correlate with absence of this aspartate.