Transcription activation by phage phi29 protein p4 is mediated by interaction with the alpha subunit of Bacillus subtilis RNA polymerase

Isolation and Characterisation of the Bundooravirus Genus and Phylogenetic Investigation of the Salasmaviridae Bacteriophages

Bacillus is a highly diverse genus containing over 200 species that can be problematic in both industrial and medical settings. This is mainly attributed to Bacillus sp. being intrinsically resistant to an array of antimicrobial compounds, hence alternative treatment options are needed. In this study, two bacteriophages, PumA1 and PumA2 were isolated and characterized. Genome nucleotide analysis identified the two phages as novel at the DNA sequence level but contained proteins similar to phi29 and other related phages. Whole genome phylogenetic investigation of 34 phi29-like phages resulted in the formation of seven clusters that aligned with recent ICTV classifications. PumA1 and PumA2 share high genetic mosaicism and form a genus with another phage named WhyPhy, more recently isolated from the United States of America. The three phages within this cluster are the only candidates to infect B. pumilus. Sequence analysis of B. pumilus phage resistant mutants revealed that PumA1 and PumA2 require polymerized and peptidoglycan bound wall teichoic acid (WTA) for their infection. Bacteriophage classification is continuously evolving with the increasing phages' sequences in public databases. Understanding phage evolution by utilizing a combination of phylogenetic approaches provides invaluable information as phages become legitimate alternatives in both human health and industrial processes.

The Role of α-CTD in the Genome-Wide Transcriptional Regulation of the Bacillus subtilis Cells

The amino acid sequence of the RNA polymerase (RNAP) α-subunit is well conserved throughout the Eubacteria. Its C-terminal domain (α-CTD) is important for the transcriptional regulation of specific promoters in both Escherichia coli and Bacillus subtilis, through interactions with transcription factors and/or a DNA element called the "UP element". However, there is only limited information regarding the α-CTD regulated genes in B. subtilis and the importance of this subunit in the transcriptional regulation of B. subtilis. Here, we established strains and the growth conditions in which the α-subunit of RNAP was replaced with a C-terminally truncated version. Transcriptomic and ChAP-chip analyses revealed that α-CTD deficiency reduced the transcription and RNAP binding of genes related to the utilization of secondary carbon sources, transition state responses, and ribosome synthesis. In E. coli, it is known that α-CTD also contributes to the expression of genes related to the utilization of secondary carbon sources and ribosome synthesis. Our results suggest that the biological importance of α-CTD is conserved in B. subtilis and E. coli, but that its specific roles have diversified between these two bacteria.

Different Modes of Transactivation of Bacteriophage Mu Late Promoters by Transcription Factor C

Transactivator protein C is required for the expression of bacteriophage Mu late genes from lys, I, P and mom promoters during lytic life cycle of the phage. The mechanism of transcription activation of mom gene by C protein is well understood. C activates transcription at Pmom by initial unwinding of the promoter DNA, thereby facilitating RNA polymerase (RNAP) recruitment. Subsequently, C interacts with the ß' subunit of RNAP to enhance promoter clearance. The mechanism by which C activates other late genes of the phage is not known. We carried out promoter-polymerase interaction studies with all the late gene promoters to determine the individual step of C mediated activation. Unlike at Pmom, at the other three promoters, RNAP recruitment and closed complex formation are not C dependent. Instead, the action of C at Plys, PI, and PP is during the isomerization from closed complex to open complex with no apparent effect at other steps of initiation pathway. The mechanism of transcription activation of mom and other late promoters by their common activator is different. This distinction in the mode of activation (promoter recruitment and escape versus isomerization) by the same activator at different promoters appears to be important for optimized expression of each of the late genes.

Helicobacter pylori RNA polymerase α-subunit C-terminal domain shows features unique to ɛ-proteobacteria and binds NikR/DNA complexes

Bacterial RNA polymerase is a large, multi-subunit enzyme responsible for transcription of genomic information. The C-terminal domain of the α subunit of RNA polymerase (αCTD) functions as a DNA and protein recognition element localizing the polymerase on certain promoter sequences and is essential in all bacteria. Although αCTD is part of RNA polymerase, it is thought to have once been a separate transcription factor, and its primary role is the recruitment of RNA polymerase to various promoters. Despite the conservation of the subunits of RNA polymerase among bacteria, the mechanisms of regulation of transcription vary significantly. We have determined the tertiary structure of Helicobacter pylori αCTD. It is larger than other structurally determined αCTDs due to an extra, highly amphipathic helix near the C-terminal end. Residues within this helix are highly conserved among ɛ-proteobacteria. The surface of the domain that binds A/T rich DNA sequences is conserved and showed binding to DNA similar to αCTDs of other bacteria. Using several NikR dependent promoter sequences, we observed cooperative binding of H. pylori αCTD to NikR:DNA complexes. We also produced αCTD lacking the 19 C-terminal residues, which showed greatly decreased stability, but maintained the core domain structure and binding affinity to NikR:DNA at low temperatures. The modeling of H. pylori αCTD into the context of transcriptional complexes suggests that the additional amphipathic helix mediates interactions with transcriptional regulators.

Functional specificity of a protein-DNA complex mediated by two arginines bound to the minor groove

A bacteriophage Ø29 transcriptional regulator, protein p4, interacts with its DNA target by employing two mechanisms: by direct readout of the chemical signatures of only one DNA base and by inducing local modification on the topology of short A tracts (indirect readout). p4 binds as a dimer to targets consisting of imperfect inverted repeats. Here we used molecular dynamic simulation to define interactions of a cluster of 12 positively charged amino acids of p4 with DNA and biochemical assays with modified DNA targets and mutated proteins to quantify the contribution of residues in the nucleoprotein complex. Our results show the implication of Arg54, with non-base-specific interaction in the central A tract, in p4 binding affinity. Despite being chemically equivalent and in identical protein monomers, the two Arg54 residues differed in their interactions with DNA. We discuss an indirect-readout mechanism for p4-DNA recognition mediated by dissimilar interaction of arginines penetrating the minor groove and the inherent properties of the A tract. Our findings extend the current understanding of protein-DNA recognition and contribute to the relevance of the sequence-dependent conformational malleability of the DNA, shedding light on the role of arginines in binding affinity. Characterization of mutant p4R54A shows that the residue is required for the activity of the protein as a transcriptional regulator.

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.

Real-time monitoring of a stepwise transcription reaction on a quartz-crystal microbalance

We monitored real-time DNA transcription by T7 RNAP using a 27-MHz DNA-immobilized quartz-crystal microbalance (QCM) in buffer solution to investigate the stepwise reaction of transcription. We designed a template double-stranded DNA that consisted of a T7 promoter, a stall position (15 bp downstream from the promoter), and a 73-bp transcription region. Based on the frequency (mass) changes of the template-immobilized QCM in response to the addition of T7 RNAP and monomers of NTP, we obtained the kinetic parameters of each step of the T7 RNAP reactions: the enzyme-binding rate (k(on)) to and the dissociation rate (k(off)) from the promoter, the proceeding rate (k(for)) from the promoter to the forward stall position, the polymerization rate (k(cat)) of RNA along DNA, and the release rate (k(r)) from the end of the template DNA. We found that k(cat) (120 s⁻¹) was extremely large compared with k(off) (0.014 s⁻¹), k(for) (0.062 s⁻¹), and k(r) (0.014 s⁻¹), revealing that the rate-limiting steps of T7 RNAP involve the binding to the promoter, the movement to the stall position, and the release from DNA. These kinetic parameters were compared with values for other DNA-binding enzymes.

RinA controls phage-mediated packaging and transfer of virulence genes in Gram-positive bacteria

Phage-mediated transfer of microbial genetic elements plays a crucial role in bacterial life style and evolution. In this study, we identify the RinA family of phage-encoded proteins as activators required for transcription of the late operon in a large group of temperate staphylococcal phages. RinA binds to a tightly regulated promoter region, situated upstream of the terS gene, that controls expression of the morphogenetic and lysis modules of the phage, activating their transcription. As expected, rinA deletion eliminated formation of functional phage particles and significantly decreased the transfer of phage and pathogenicity island encoded virulence factors. A genetic analysis of the late promoter region showed that a fragment of 272 bp contains both the promoter and the region necessary for activation by RinA. In addition, we demonstrated that RinA is the only phage-encoded protein required for the activation of this promoter region. This region was shown to be divergent among different phages. Consequently, phages with divergent promoter regions carried allelic variants of the RinA protein, which specifically recognize its own promoter sequence. Finally, most Gram-postive bacteria carry bacteriophages encoding RinA homologue proteins. Characterization of several of these proteins demonstrated that control by RinA of the phage-mediated packaging and transfer of virulence factor is a conserved mechanism regulating horizontal gene transfer.

Molecular interactions and protein-induced DNA hairpin in the transcriptional control of bacteriophage ø29 DNA

Studies on the regulation of phage Ø29 gene expression revealed a new mechanism to accomplish simultaneous activation and repression of transcription leading to orderly gene expression. Two phage-encoded early proteins, p4 and p6, bind synergistically to DNA, modifying the topology of the sequences encompassing early promoters A2c and A2b and late promoter A3 in a hairpin that allows the switch from early to late transcription. Protein p6 is a nucleoid-like protein that binds DNA in a non-sequence specific manner. Protein p4 is a sequence-specific DNA binding protein with multifaceted sequence-readout properties. The protein recognizes the chemical signature of only one DNA base on the inverted repeat of its target sequence through a direct-readout mechanism. In addition, p4 specific binding depends on the recognition of three A-tracts by indirect-readout mechanisms. The biological importance of those three A-tracts resides in their individual properties rather than in the global curvature that they may induce.

Design, construction and characterization of a set of insulated bacterial promoters

We have generated a series of variable-strength, constitutive, bacterial promoters that act predictably in different sequence contexts, span two orders of magnitude in strength and contain convenient sites for cloning and the introduction of downstream open-reading frames. Importantly, their design insulates these promoters from the stimulatory or repressive effects of many 5′- or 3′-sequence elements. We show that different promoters from our library produce constant relative levels of two different proteins in multiple genetic contexts. This set of promoters should be a useful resource for the synthetic-biology community.

DNA bending and looping in the transcriptional control of bacteriophage phi29

Recent studies on the regulation of phage phi29 gene expression reveal new ways to accomplish the processes required for the orderly gene expression in prokaryotic systems. These studies revealed a novel DNA-binding domain in the phage main transcriptional regulator and the nature and dynamics of the multimeric DNA-protein complex responsible for the switch from early to late gene expression. This review describes the features of the regulatory mechanism that leads to the simultaneous activation and repression of transcription, and discusses it in the context of the role of the topological modification of the DNA carried out by two phage-encoded proteins working synergistically with the DNA.

Bacillus subtilis RNA Polymerase Recruits the Transcription Factor Spo0A∼P to Stabilize a Closed Complex during Transcription Initiation

The Bacillus subtilis response regulator Spo0A approximately P activates transcription from the spoIIG promoter by stimulating a rate-limiting transition between the initial interaction of RNA polymerase with the promoter and initiation of RNA synthesis. Previous work showed that Spo0A exerts its effect on RNA polymerase prior to the formation of an open complex in which the DNA strands at the initiation site have been separated. To isolate the effect of Spo0A approximately P on events prior to DNA strand separation at spoIIG we studied RNA polymerase binding to DNA fragments that were truncated to contain only promoter sequences 5' to the -10 element by electrophoretic mobility shift assays. RNA polymerase bound to these fragments readily though highly reversibly, and polymerase-promoter complexes recruited Spo0A approximately P. Sequence-independent interactions between the RNA polymerase and the DNA upstream of the core promoter were important for RNA polymerase binding and essential for Spo0A approximately P recruitment, while sequence-specific Spo0A approximately P-DNA interactions positioned and stabilized RNA polymerase binding to the DNA. Spo0A approximately P decreased the dissociation rate of the complexes formed with truncated promoter templates which could contribute to the means by which Spo0A approximately P stimulates spoIIG expression.

The structure of phage phi29 transcription regulator p4-DNA complex reveals an N-hook motif for DNA

Protein p4 affects the transcriptional switch that divides bacteriophage phi29 infection in early and late phases. The synthesis of DNA replication proteins and p4 takes place in the early phase, while structural, morphogenesis, and lysis proteins are synthesized in the late phase. Transcriptional switch by p4 is achieved by activating the late promoter A3 and repressing the early promoters A2b and A2c. The crystal structure of p4 alone and in complex with a 41 bp DNA, including the A3 promoter binding site, helps us to understand how the phage cycle is controlled. Protein p4 has a unique alpha/beta fold that includes a DNA recognition motif consisting of two N-terminal beta turn substructures, or N-hooks, located at the tips of an elongated protein homodimer. The two N-hooks enter the major groove of the double helix, establishing base-specific contacts. A high DNA curvature allows p4 N-hooks to reach two major groove areas three helical turns apart, like a bow and its string.

Molecular basis for the exploitation of spore formation as survival mechanism by virulent phage phi29

Phage phi29 is a virulent phage of Bacillus subtilis with no known lysogenic cycle. Indeed, lysis occurs rapidly following infection of vegetative cells. Here, we show that phi29 possesses a powerful strategy that enables it to adapt its infection strategy to the physiological conditions of the infected host to optimize its survival and proliferation. Thus, the lytic cycle is suppressed when the infected cell has initiated the process of sporulation and the infecting phage genome is directed into the highly resistant spore to remain dormant until germination of the spore. We have also identified two host-encoded factors that are key players in this adaptive infection strategy. We present evidence that chromosome segregation protein Spo0J is involved in spore entrapment of the infected phi29 genome. In addition, we demonstrate that Spo0A, the master regulator for initiation of sporulation, suppresses phi29 development by repressing the main early phi29 promoters via different and novel mechanisms and also by preventing activation of the single late phi29 promoter.

Homologies and divergences in the transcription regulatory system of two related Bacillus subtilis phages

Transcription regulation relies on the molecular interplay between the RNA polymerase and regulatory factors. Phages of the phi29-like genus encode two regulatory proteins, p4 and p6. In phi29, the switch from early to late transcription is based on the synergistic binding of proteins p4 and p6 to the promoter sequence, resulting in a nucleosome-like structure able to synergize or antagonize the binding of RNAP. We show that a nucleosome-like structure of p4 and p6 is also formed in the related phage Nf and that this structure is responsible for the coordinated control of the early and late promoters. However, in spite of their homologies, the transcriptional regulators are not interchangeable, and only when all of the components of the Nf regulatory system are present is fully active transcriptional regulation of the Nf promoters achieved.

A precise DNA bend angle is essential for the function of the phage phi29 transcriptional regulator

Bacteriophage φ29 protein p4 is essential for the regulation of the switch from early to late phage transcription. The protein binds to two regions of the phage genome located between the regulated promoters. Each region contains two inverted repeats separated by 1 bp. We used circular permutation assays to study the topology of the DNA upon binding of the protein and found that p4 induced the same extent of bending independent of the topology of the binding region. In addition, the results revealed that the p4-induced bending is not dependent on the affinity to the binding site but is intrinsic to p4 binding. Independent binding sites were identified through the characterization of the minimal sequence required for p4 binding. The protein has different affinity for each of its binding sites, with those overlapping the A2c and A2b promoter cores (sites 1 and 3), having the highest affinity. The functionality of the p4 binding sites and the contribution of p4-mediated promoter restructuring in transcription regulation is discussed.

Mechanism of transcription activation at the comG promoter by the competence transcription factor ComK of Bacillus subtilis

The development of genetic competence in Bacillus subtilis is regulated by a complex signal transduction cascade, which results in the synthesis of the competence transcription factor, encoded by comK. ComK is required for the transcription of the late competence genes that encode the DNA binding and uptake machinery and of genes required for homologous recombination. In vivo and in vitro experiments have shown that ComK is responsible for transcription activation at the comG promoter. In this study, we investigated the mechanism of this transcription activation. The intrinsic binding characteristics of RNA polymerase with and without ComK at the comG promoter were determined, demonstrating that ComK stabilizes the binding of RNA polymerase to the comG promoter. This stabilization probably occurs through interactions with the upstream DNA, since a deletion of the upstream DNA resulted in an almost complete abolishment of stabilization of RNA polymerase binding. Furthermore, a strong requirement for the presence of an extra AT box in addition to the common ComK-binding site was shown. In vitro transcription with B. subtilis RNA polymerase reconstituted with wild-type alpha-subunits and with C-terminal deletion mutants of the alpha-subunits was performed, demonstrating that these deletions do not abolish transcription activation by ComK. This indicates that ComK is not a type I activator. We also show that ComK is not required for open complex formation. A possible mechanism for transcription activation is proposed, implying that the major stimulatory effect of ComK is on binding of RNA polymerase.

Relevance of UP elements for three strong Bacillus subtilis phage phi29 promoters

Various Escherichia coli promoters contain, in addition to the classical -35 and -10 hexamers, a third recognition element, named the UP element. Located upstream of the -35 box, UP elements stimulate promoter activity by forming a docking site for the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). Accumulating genetic, biochemical and structural information has provided a detailed picture on the molecular mechanism underlying UP element-dependent promoter stimulation in E.coli. However, far less is known about functional UP elements of Bacillus subtilis promoters. Here we analyse the strong early sigma(A)-RNA polymerase-dependent promoters C2, A2c and A2b of the lytic B.subtilis phage phi29. We demonstrate that the phage promoters contain functional UP elements although their contribution to promoter strength is very different. Moreover, we show that the UP element of the A2b promoter, being critical for its activity, is located further upstream of the -35 box than most E.coli UP elements. The importance of the UP elements for the phage promoters and how they relate to other UP elements are discussed.

Molecular Interplay Between RNA Polymerase and Two Transcriptional Regulators in Promoter Switch

Transcription regulation relies in the molecular interplay between the RNA polymerase (RNAP) and regulatory factors. Phage phi29 promoters A2c, A2b and A3 are coordinately regulated by the transcriptional regulator protein p4 and the histone-like protein p6. This study shows that protein p4 binds simultaneously to four sites: sites 1 and 2 located between promoters A2c and A2b and sites 3 and 4 between promoters A2b and A3, placed in such a way that bound p4 is equidistant from promoters A2c and A2b and one helix turn further upstream from promoter A3. The p4 molecules bound to sites 1 and 3 reorganise the binding of protein p6, giving rise to the nucleoprotein complex responsible for the switch from early to late transcription. We identify the positioning of the alphaCTD-RNAP domain at these promoters, and demonstrate that the domains are crucial for promoter A2b recognition and required for full activity of promoter A2c. Since binding of RNAP overlaps with p4 and p6 binding, repression of the early transcription relies on the synergy of the regulators able to antagonize the stable binding of the RNAP through competition for the same target, while activation of late transcription is carried out through the stabilization of the RNAP by the p4/p6 nucleoprotein complex. The control of promoters A2c and A2b by feed-back regulation is discussed.

The phi29 transcriptional regulator contacts the nucleoid protein p6 to organize a repression complex

The nucleoid protein p6 of Bacillus subtilis phage phi29 binds to DNA, recognizing a structural feature rather than a specific sequence. Upon binding to the viral DNA ends, p6 generates an extended nucleoprotein complex that activates the initiation of phi29 DNA replication. Protein p6 also participates in transcription regulation, repressing the early C2 promoter and assisting the viral regulatory protein p4 in controlling the switch from early to late transcription. Proteins p6 and p4 bind cooperatively to an approximately 200 bp DNA region located between the late A3 and the early A2c promoters, generating an extended nucleoprotein complex that helps to repress the early A2c promoter and to activate the late A3 promoter. We show that stable assembly of this complex requires interaction between protein p6 and the C-terminus of protein p4. Therefore, at this DNA region, stable polymerization of protein p6 relies on p4-specified signals in addition to the structural features of the DNA. Protein p4 would define the phase and boundaries of the p6-DNA complex.

The RNA polymerase alpha subunit from Sinorhizobium meliloti can assemble with RNA polymerase subunits from Escherichia coli and function in basal and activated transcription both in vivo and in vitro

Sinorhizobium meliloti, a gram-negative soil bacterium, forms a nitrogen-fixing symbiotic relationship with members of the legume family. To facilitate our studies of transcription in S. meliloti, we cloned and characterized the gene for the alpha subunit of RNA polymerase (RNAP). S. meliloti rpoA encodes a 336-amino-acid, 37-kDa protein. Sequence analysis of the region surrounding rpoA identified six open reading frames that are found in the conserved gene order secY (SecY)-adk (Adk)-rpsM (S13)-rpsK (S11)-rpoA (alpha)-rplQ (L17) found in the alpha-proteobacteria. In vivo, S. meliloti rpoA expressed in Escherichia coli complemented a temperature sensitive mutation in E. coli rpoA, demonstrating that S. meliloti alpha supports RNAP assembly, sequence-specific DNA binding, and interaction with transcriptional activators in the context of E. coli. In vitro, we reconstituted RNAP holoenzyme from S. meliloti alpha and E. coli beta, beta', and sigma subunits. Similar to E. coli RNAP, the hybrid RNAP supported transcription from an E. coli core promoter and responded to both upstream (UP) element- and Fis-dependent transcription activation. We obtained similar results using purified RNAP from S. meliloti. Our results demonstrate that S. meliloti alpha functions are conserved in heterologous host E. coli even though the two alpha subunits are only 51% identical. The ability to utilize E. coli as a heterologous system in which to study the regulation of S. meliloti genes could provide an important tool for our understanding and manipulation of these processes.

Rhodobacter sphaeroides LexA has dual activity: optimising and repressing recA gene transcription

Transcription of the Rhodobacter sphaeroides recA promoter (P(recA)) is induced upon DNA damage in a lexA-dependent manner. In vivo experiments demonstrate that LexA protein represses and might also activate transcription of P(recA). Purified R.sphaeroides LexA protein specifically binds the SOS boxes located within the P(recA) region. In vitro transcription analysis, using Escherichia coli RNA polymerase (RNAP), indicated that the presence of LexA may stimulate and repress transcription of P(recA). EMSA and DNase I footprinting experiments show that LexA and RNAP can bind simultaneously to P(recA). At low LexA concentrations it enhances RNAP binding to P(recA), stimulates open complex formation and strand separation beyond the transcription start site. At high LexA concentrations, however, RNAP-promoted strand separation is not observed beyond the +5 region. LexA might repress transcription by interfering with the clearance process instead of blocking the access of RNAP to the promoter region. Based on these findings we propose that the R.sphaeroides LexA protein performs fine tuning of the SOS response, which might provide a physiological advantage by enhancing transcription of SOS genes and delaying full activation of the response.

Mechanism for the switch of phi29 DNA early to late transcription by regulatory protein p4 and histone-like protein p6

Bacteriophage phi29 gene expression takes place from four major promoters, three of them (A2b, A2c and A3) clustered within 219 bp at a central region of the genome. Transcription regulation of these promoters involves both a highly specific DNA-binding protein (p4) and a low specificity DNA-binding protein (p6) functionally related to prokaryotic histone-like proteins. Protein p6 forms extended oligomeric arrays along the phage DNA. In contrast, protein p4 binds specifically upstream of late promoter A3 and early promoter A2c. We have analysed the concomitant binding of p6 and p4 and found that the proteins cooperate with each other in the binding to the central region of the genome, resulting in a ternary p4-p6-DNA complex that affects local DNA topology. Through this complex, protein p6 exerts a direct role in the repression of promoter A2c, impeding unwinding of the DNA strands needed for open complex formation. In contrast, protein p6 functions by reinforcing the positioning of protein p4 in the repression of promoter A2b and activation of promoter A3, thereby facilitating p4-mediated transcription regulation.

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.

Mechanisms of transcriptional repression

Transcriptional repressors are usually viewed as proteins that bind to promoters in a way that impedes subsequent binding of RNA polymerase. Although this repression mechanism is found at several promoters, there is a growing list of repressors that inhibit transcription initiation in other ways. For example, several repressors allow the simultaneous binding of RNA polymerase to the promoter, but interfere with subsequent events of the initiation process, eventually inhibiting transcription initiation. The recent increase in the number of repressors for which the repression mechanism has been characterized in detail has shown an amazing variety of strategies to repress transcription initiation. It is not surprising to find that the repression mechanism used is usually exquisitely adapted to the characteristics of the promoter and of the repressor involved.

A Mutation in the C-terminal domain of the RNA polymerase alpha subunit that destabilizes the open complexes formed at the phage phi 29 late A3 promoter

Regulatory protein p4 from Bacillus subtilis phage phi29 activates the viral late A3 promoter mainly by stabilizing the binding of RNA polymerase (RNAP) to it as a closed complex. This requires an interaction between protein p4 residue Arg120 and the C-terminal domain (CTD) of the RNAP alpha subunit. Several acidic residues of the alpha-CTD, considered as plausible targets for p4 residue Arg120, were individually changed into alanine. In addition, a truncated alpha subunit lacking the last four residues, two of which are acidic, was obtained. The modified alpha subunits were purified and reconstituted into RNAP holoenzyme in vitro. Protein p4 was found to be unable to activate the late A3 promoter when residue Glu297 of the alpha subunit was changed to Ala, a modification that did not impair transcription from several other promoters. Interestingly, protein p4 could stabilize the modified RNAP at the A3 promoter as a closed complex, although the open complexes formed were unstable and did not proceed to elongation complexes. Our results indicate that the change of the alpha residue Glu297 into Ala destabilizes the open complexes formed at this promoter, but not at other promoters. Considered in the context of earlier findings indicating that the RNAP alpha-CTD may participate in the transition from closed to intermediate complexes at some other promoters, the new results expand and clarify our view of its role in transcription initiation.

Functional interactions between a phage histone-like protein and a transcriptional factor in regulation of phi29 early-late transcriptional switch

Protein p6 is a nonspecific DNA-binding protein occurring in high abundance in phage phi29-infected cells. Here, we demonstrate a novel role for this versatile histone-like protein: its involvement in regulating the viral switch between early and late transcription. p6 performs this role by exhibiting a reciprocal functional interaction with the regulatory protein p4, also phage encoded, which is required for repression of the early A2b and A2c promoters and activation of the late A3 promoter. On the one hand, p6 promotes p4-mediated repression of the A2b promoter and activation of the A3 promoter by enhancing binding of p4 to its recognition site at PA3; on the other, p4 promotes p6-mediated repression of the A2c promoter by favoring the formation of a stable p6-nucleoprotein complex that interferes with RNA polymerase binding to PA2c. We propose that the observed interplay between proteins p6 and p4 is based on their DNA architectural properties.

Characterization of a single-strand origin, ssoU, required for broad host range replication of rolling-circle plasmids

Single-stranded DNA (ssDNA) promoters are the key components of the single-strand origins (ssos) of replication of rolling-circle (RC) replicating plasmids. The recognition of this origin by the host RNA polymerase and the synthesis of a short primer RNA are critical for initiation of lagging-strand synthesis. This step is thought to be a limiting factor for the establishment of RC plasmids in a broad range of bacteria, because most of the ssos described are fully active only in their natural hosts. A special type of sso, the ssoU, is unique in the sense that it can be efficiently recognized in a number of different Gram-positive hosts. We have experimentally deduced the folded structure and characterized the ssDNA promoter present within the ssoU using P1 nuclease digestion and DNase I protection assays with the Bacillus subtilis and Staphylococcus aureus RNA polymerases. We have also identified the RNA products synthesized from this ssDNA promoter and mapped the initiation points of lagging-strand synthesis in vivo from ssoU-containing plasmids. Through gel mobility shift experiments, we have found that ssDNA containing the ssoU sequence can efficiently interact with the RNA polymerase from two different Gram-positive bacteria, S. aureus and B. subtilis. We have also realigned the narrow and broad host range sso sequences of RC plasmids, and found that they contain significant homology. Our data support the notion that the strength of the RNA polymerase-ssoU interaction may be the critical factor that confers the ability on the ssoU to be fully functional in a broad range of bacteria.

The switch from early to late transcription in phage GA-1: characterization of the regulatory protein p4G

The transcription program of the Bacillus phage GA-1, a distant relative of phage Phi29, has been studied. Transcription of the GA-1 genome occurred in two stages, early and late. Early genes were expressed from two promoters equivalent to the Phi29 A2b and A2c promoters, whereas late transcription started at a site equivalent to the Phi29 late A3 promoter. The activity of the GA-1 early A2b and A2c promoters diminished 10 minutes after infection, a time at which expression of the late promoter increased significantly. The switch from early to late transcription required protein synthesis, suggesting the need for viral protein(s). An open reading frame was found in the GA-1 genome coding for a protein showing a 53 % similarity to Phi29 regulatory protein p4, and was named p4G. In Phi29, protein p4 represses the early A2b and A2c promoters and activates the late A3 promoter by recruiting RNA polymerase to it. A binding site for protein p4Gwas localized upstream from the GA-1 late A3 promoter, overlapping with the early A2b promoter. In vitro, protein p4Gprevented the binding of RNA polymerase to the GA-1 early A2b promoter but, unlike in Phi29, had no effect on the expression of the late A3 promoter: RNA polymerase could efficiently bind and initiate transcription from the A3 promoter in the absence of protein p4G. Therefore, activation of late transcription occurs differently in GA-1 and Phi29. We propose that protein p4Gis an anti-repressor which inhibits the binding to the late promoter of an unknown repressor factor present in the host strain.

A region of sigmaK involved in promoter activation by GerE in Bacillus subtilis

During endospore formation in Bacillus subtilis, the DNA binding protein GerE stimulates transcription from several promoters that are used by RNA polymerase containing sigmaK. GerE binds to a site on one of these promoters, cotX, that overlaps its -35 region. We tested the model that GerE interacts with sigmaK at the cotX promoter by seeking amino acid substitutions in sigmaK that interfered with GerE-dependent activation of the cotX promoter but which did not affect utilization of the sigmaK-dependent, GerE-independent promoter gerE. We identified two amino acid substitutions in sigmaK, E216K and H225Y, that decrease cotX promoter utilization but do not affect gerE promoter activity. Alanine substitutions at these positions had similar effects. We also examined the effects of the E216A and H225Y substitutions in sigmaK on transcription in vitro. We found that these substitutions specifically reduced utilization of the cotX promoter. These and other results suggest that the amino acid residues at positions 216 and 225 are required for GerE-dependent cotX promoter activity, that the histidine at position 225 of sigmaK may interact with GerE at the cotX promoter, and that this interaction may facilitate the initial binding of sigmaK RNA polymerase to the cotX promoter. We also found that the alanine substitutions at positions 216 and 225 of sigmaK had no effect on utilization of the GerE-dependent promoter cotD, which contains GerE binding sites that do not overlap with its -35 region.

Bacillus subtilis sequence-independent DNA-binding and DNA-bending protein Hbsu negatively controls its own synthesis

Transcription of the hbs gene under vegetative growth condition is subject to repression when cells enter in late exponential phase. We have determined the sites at which transcription of the hbs gene initiates in vitro. On a supercoiled template, transcription of the hbs gene is initiated by sigmaARNAP at two overlapping hbs promoters (P1 and P3). We have demonstrated that highly purified Hbsu protein acts as a repressor of its own synthesis. The binding of the sequence-independent DNA-binding and DNA-bending Hbsu protein does not seem to exclude sigmaARNAP from the promoters. In this report we show that Hbsu, in vitro, does not repress transcription by a mere steric hindrance on sigmaARNAP binding.

Effect of mutations in the "extended -10" motif of three Bacillus subtilis sigmaA-RNA polymerase-dependent promoters

The "extended -10" motif described originally in Escherichia coli promoters occurs frequently in other bacterial promoters. Most Bacillus subtilis bacteriophage o29 promoters contain this motif. To analyse the influence of the motif on sigmaA-RNA polymerase transcription, the 5'-TG-3' dinucleotide was changed to 5'-AC-3' in three o29 promoters. This change impaired RNA polymerase binding to the promoters; the yields of closed and open complexes were reduced independently of other differences inherent to each promoter. The mutation abolished transcription in vitro from a promoter lacking the consensus sequence at the -35 hexamer. In contrast, at other promoters with a -35 consensus sequence, the yield of run off transcription was not reduced by the mutation. Indeed an apparent interference phenomenon at high polymerase/DNA ratios was relieved. These results indicate that the extended -10 motif provides contact points for sigmaA-RNA polymerase with a role restricted to the first steps of transcription.

Activator-sigma interaction: A hydrophobic segment mediates the interaction of a sigma family promoter recognition protein with a sliding clamp transcription activator

Activation of transcription at bacteriophage T4 late promoters and coupling of late transcription to concurrent replication requires a peculiar transcriptional activator, the gp45 sliding clamp of the T4 DNA polymerase. In order to activate transcription, the topologically DNA-linked trimeric gp45 must interact with two T4-encoded RNA polymerase-binding proteins, the gp33 co-activator, and the gp55 late sigma factor. The carboxy termini of gp55 and gp33 share a similar sequence, which has been shown to be required for response of late transcription to activation by gp45. Alanine-scanning mutagenesis of the C terminus of gp55 shows that residues within the short hydrophobic sequence L(D/A)FLYE, are necessary for gp55 to bind to gp45, and to respond maximally to transcriptional activation by gp45. When fused to GST, the peptide SLDFLYE suffices for specific gp45 binding. Thus, it constitutes the main gp55 epitope for gp45 interaction.

Transcriptional activation of the Bacillus subtilis ackA gene requires sequences upstream of the promoter

Transcriptional activation of the Bacillus subtilis ackA gene, encoding acetate kinase, was previously shown to require catabolite control protein A (CcpA) and sequences upstream of the ackA promoter. CcpA, which is responsible for catabolite repression of a number of secondary carbon source utilization genes in B. subtilis and other gram-positive bacteria, recognizes a cis-acting consensus sequence, designated cre (catabolite response element), generally located within or downstream of the promoter of the repressed gene. Two sites resembling this sequence are centered at positions -116.5 and -56.5 of the ackA promoter and have been termed cre1 and cre2, respectively. Synthesis of acetate kinase, which is involved in the conversion of acetyl coenzyme A to acetate, is induced when cells are grown in the presence of an easily metabolized carbon source such as glucose. In this study, cre2, the site closer to the promoter, and the region upstream of cre2 were shown to be indispensable for CcpA-dependent transcriptional activation of ackA, whereas cre1 was not required. In addition, insertion of 5 bp between cre2 and the promoter disrupted activation, while 10 bp was tolerated, suggesting face-of-the-helix dependence of the position of cre2 and/or upstream sequences. DNase footprinting experiments demonstrated binding of CcpA in vitro to cre2 but not cre1, consistent with the genetic data. Activation of ackA transcription was blocked in a ptsH1/crh double mutant, suggesting involvement of this pathway in CcpA-mediated transcriptional activation.

Binding of phage phi29 protein p4 to the early A2c promoter: recruitment of a repressor by the RNA polymerase

Regulatory protein p4 from Bacillus subtilis phage Phi29 represses the early A2c promoter by binding upstream from RNA polymerase and interacting with the C-terminal domain of the RNA polymerase alpha subunit. This interaction stabilizes the RNA polymerase at the promoter in such a way that promoter clearance is prevented. Here, the binding of protein p4 to the A2c promoter has been studied. In the absence of RNA polymerase, protein p4 was found to bind with low affinity to a site centered at position -39 relative to the transcription start site. When RNA polymerase was present, protein p4 was displaced from this site and bound instead to a different target centered at position -71. Stable binding to this site requires the interaction of protein p4 with the C-terminal domain of the RNA polymerase alpha-subunit. Both sites contain sequences resembling the well-characterized p4 binding site present at the late A3 promoter, to which p4 binds with high affinity. A mutational analysis revealed that the site at -71 is critical for a stable interaction between protein p4 and RNA polymerase, and for efficient repression, whereas mutation of the site at -39 had only a small effect on repression efficiency. Therefore, RNA polymerase plays an active role in the repression mechanism by stabilizing the repressor at the promoter, generating a nucleoprotein complex that is too stable to allow promoter clearance.

Transcriptional activation of the Bacillus subtilis spoIIG promoter by the response regulator Spo0A is independent of the C-terminal domain of the RNA polymerase alpha subunit

In vitro transcription from the spoIIG promoter by Bacillus subtilis RNA polymerase reconstituted with wild-type alpha subunits and with C-terminal deletion mutants of the alpha subunit was equally stimulated by the response regulator Spo0A. Some differences in the structure of open complexes formed by RNA polymerase containing alpha subunit mutants were noted, although the wild-type and mutant polymerases appeared to use the same initiation mechanism.

Lagging strand replication of rolling-circle plasmids: specific recognition of the ssoA-type origins in different gram-positive bacteria

Many bacterial plasmids replicate by a rolling-circle mechanism that involves the generation of single-stranded DNA (ssDNA) intermediates. Replication of the lagging strand of such plasmids initiates from their single strand origin (sso). Many different types of ssos have been identified. One group of ssos, termed ssoA, which have conserved sequence and structural features, function efficiently only in their natural hosts in vivo. To study the host specificity of sso sequences, we have analyzed the functions of two closely related ssoAs belonging to the staphylococcal plasmid pE194 and the streptococcal plasmid pLS1 in Staphylococcus aureus. The pLS1 ssoA functioned poorly in vivo in S. aureus as evidenced by accumulation of high levels of ssDNA but supported efficient replication in vitro in staphylococcal extracts. These results suggest that one or more host factors that are present in sufficient quantities in S. aureus cell-free extracts may be limiting in vivo. Mapping of the initiation points of lagging strand synthesis in vivo and in vitro showed that DNA synthesis initiates from specific sites within the pLS1 ssoA. These results demonstrate that specific initiation of replication can occur from the pLS1 ssoA in S. aureus although it plays a minimal role in lagging strand synthesis in vivo. Therefore, the poor functionality of the pLS1 in vivo in a nonnative host is caused by the low efficiency rather than a lack of specificity of the initiation process. We also have identified ssDNA promoters and mapped the primer RNAs synthesized by the S. aureus and Bacillus subtilis RNA polymerases from the pE194 and pLS1 ssoAs. The S. aureus RNA polymerase bound more efficiently to the native pE194 ssoA as compared with the pLS1 ssoA, suggesting that the strength of RNA polymerase-ssoA interaction may play a major role in the functionality of the ssoA sequences in Gram-positive bacteria.

The Bacillus stearothermophilus argCJBD operon harbours a strong promoter as evaluated in Escherichia coli cells

We have shown that the B. stearothermophilus argCJBD genes form a single operon. In B. stearothermophilus, a specific repressor governs operon expression by binding to the argCo operator site overlapping the Parg promoter sequence (Dion et al., 1997). Therefore, the enzymatic and transcriptional analyses performed in this work did not reflect the potential strength of Parg in the native host. For evaluation of the Parg promoter strength, E. coli was used as a host since its own ArgR repressor does not interact with the B. stearothermophilus heterologous operator. Parg-promoted argC gene expression dramatically increased, reaching up to 38% of the total protein in E. coli cells. An AT-rich sequence upstream of a -35 site of Parg was found to be indispensable for the promoter strength. Plasmids carrying the B. stearothermophilus argCJBD operon linked with its Parg/argCo region were unstable in E. coli. Stabilization of plasmids was achieved by repression of B. stearothermophilus arg genes through the action of the B. subtilis AhrC repressor.

Transcription activation and repression by interaction of a regulator with the alpha subunit of RNA polymerase: the model of phage phi 29 protein p4

Regulatory protein p4, encoded by Bacillus subtilis phage phi 29, has proved to be a very useful model to analyze the molecular mechanisms of transcription regulation. Protein p4 modulates the transcription of phage phi 29 genome by activating the late A3 promoter (PA3) and simultaneously repressing the two main early promoters, A2b and A2c (or PA2b and PA2c). This review describes in detail the regulatory mechanism leading to activation or repression, and discusses them in the context of the recent findings on the role of the RNA polymerase alpha subunit in transcription regulation. Activation of PA3 implies the p4-mediated stabilization of RNA polymerase at the promoter as a closed complex. Repression of the early A2b promoter occurs by binding of protein p4 to a site that partially overlaps the -35 consensus region of the promoter, therefore preventing the binding of RNA polymerase to the promoter. Repression of the A2c promoter, located 96 bp downstream from PA2b, occurs by a different mechanism that implies the simultaneous binding of protein p4 and RNA polymerase to the promoter in such a way that promoter clearance is inhibited. Interestingly, activation of PA3 and repression of PA2c require an interaction between protein p4 and RNA polymerase, and in both cases this interaction occurs between the same surface of protein p4 and the C-terminal domain of the alpha subunit of RNA polymerase, which provides new insights into how a protein can activate or repress transcription by subtle variations in the protein-DNA complexes formed at promoters.

Substitution of the C-terminal domain of the Escherichia coli RNA polymerase alpha subunit by that from Bacillus subtilis makes the enzyme responsive to a Bacillus subtilis transcriptional activator

Regulatory protein p4 of Bacillus subtilis phage phi 29 activates transcription from the viral late A3 promoter by interacting with the C-terminal domain (CTD) of the B. subtilis RNA polymerase alpha subunit, thereby stabilizing the holoenzyme at the promoter. Protein p4 does not interact with the Escherichia coli RNA polymerase and cannot activate transcription with this enzyme. We have constructed a chimerical alpha subunit containing the N-terminal domain of the E. coli alpha subunit and the CTD of the B. subtilis alpha subunit. Reconstitution of RNA polymerases containing this chimerical alpha subunit, the E. coli beta and beta' subunits, and the vegetative sigma factor from either E. coli (sigma 70) or B. subtilis (sigma A), generated hybrid enzymes that were responsive to protein p4 and efficiently supported activation at the A3 promoter. Protein p4 activated transcription with the chimerical enzymes through the same activation surface used with B. subtilis RNA polymerase. Therefore, the B. subtilis alpha-CTD allowed activation by p4 even when the rest of the RNA polymerase subunits belonged to E. coli, a distantly related bacterium. These results strongly suggest that protein p4 works essentially by serving as an anchor that stabilizes RNA polymerase at the promoter.

Transcription activation or repression by phage psi 29 protein p4 depends on the strength of the RNA polymerase-promoter interactions

Phage psi 29 protein p4 activates the late A3 promoter and represses the early A2c promoter, in both cases by binding upstream from RNA polymerase (RNAP) and interacting with the C-terminal domain of the RNAP alpha subunit. To investigate how this interaction leads to activation at PA3 and to repression at PA2c, mutant promoters were constructed. We show that the position of protein p4 relative to that of RNAP, which is different at each promoter, does not dictate the outcome of the interaction. Rather, in the absence of a-35 consensus box for sigma A-RNAP activation was observed, while in its presence repression occurred. The results support the view that stabilization of RNAP at the promoter over a threshold level leads to repression.

Plasmid rolling circle replication: identification of the RNA polymerase-directed primer RNA and requirement for DNA polymerase I for lagging strand synthesis

Plasmid rolling circle replication involves generation of single-stranded DNA (ssDNA) intermediates. ssDNA released after leading strand synthesis is converted to a double-stranded form using solely host proteins. Most plasmids that replicate by the rolling circle mode contain palindromic sequences that act as the single strand origin, sso. We have investigated the host requirements for the functionality of one such sequence, ssoA, from the streptococcal plasmid pLS1. We used a new cell-free replication system from Streptococcus pneumoniae to investigate whether host DNA polymerase I was required for lagging strand synthesis. Extracts from DNA polymerase I-deficient cells failed to replicate, but this was corrected by adding purified DNA polymerase I. Efficient DNA synthesis from the pLS1-ssoA required the entire DNA polymerase I (polymerase and 5'-3' exonuclease activities). ssDNA containing the pLS1-ssoA was a substrate for specific RNA polymerase binding and a template for RNA polymerase-directed synthesis of a 20 nucleotide RNA primer. We constructed mutations in two highly conserved regions within the ssoA: a six nucleotide conserved sequence and the recombination site B. Our results show that the former seemed to function as a terminator for primer RNA synthesis, while the latter may be a binding site for RNA polymerase.