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

Global Transcriptional Analysis of Virus-Host Interactions between Phage ϕ29 and Bacillus subtilis

The study of phage-host relationships is essential to understanding the dynamic of microbial systems. Here, we analyze genome-wide interactions of Bacillus subtilis and its lytic phage ϕ29 during the early stage of infection. Simultaneous high-resolution analysis of virus and host transcriptomes by deep RNA sequencing allowed us to identify differentially expressed bacterial genes. Phage ϕ29 induces significant transcriptional changes in about 0.9% (38/4,242) and 1.8% (76/4,242) of the host protein-coding genes after 8 and 16 min of infection, respectively. Gene ontology enrichment analysis clustered upregulated genes into several functional categories, such as nucleic acid metabolism (including DNA replication) and protein metabolism (including translation). Surprisingly, most of the transcriptional repressed genes were involved in the utilization of specific carbon sources such as ribose and inositol, and many contained promoter binding-sites for the catabolite control protein A (CcpA). Another interesting finding is the presence of previously uncharacterized antisense transcripts complementary to the well-known phage ϕ29 messenger RNAs that adds an additional layer to the viral transcriptome complexity.

IMPORTANCE

The specific virus-host interactions that allow phages to redirect cellular machineries and energy resources to support the viral progeny production are poorly understood. This study provides, for the first time, an insight into the genome-wide transcriptional response of the Gram-positive model Bacillus subtilis to phage ϕ29 infection.

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.

My life with bacteriophage phi29

This article is a survey of my scientific work over 52 years. During my postdoctoral stay in Severo Ochoa's laboratory, I determined the direction of reading of the genetic message, and I discovered two proteins that I showed to be involved in the initiation of protein synthesis. The work I have done in Spain with bacteriophage ϕ29 for 45 years has been very rewarding. I can say that I was lucky because I did not expect that ϕ29 would give so many interesting results, but I worked hard, with a lot of dedication and enthusiasm, and I was there when the luck arrived. I would like to emphasize our work on the control of ϕ29 DNA transcription and, in particular, the finding for the first time of a protein covalently linked to the 5'-ends of ϕ29 DNA that we later showed to be the primer for the initiation of phage DNA replication. Very relevant was the discovery of the ϕ29 DNA polymerase, with its properties of extremely high processivity and strand displacement capacity, together with its high fidelity. The ϕ29 DNA polymerase has become an ideal enzyme for DNA amplification, both rolling-circle and whole-genome linear amplification. I am also very proud of the many brilliant students and collaborators with whom I have worked over the years and who have become excellent scientists. This Reflections article is not intended to be the end of my scientific career. I expect to work for many years to come.

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.

Viral terminal protein directs early organization of phage DNA replication at the bacterial nucleoid

The mechanism leading to protein-primed DNA replication has been studied extensively in vitro. However, little is known about the in vivo organization of the proteins involved in this fundamental process. Here we show that the terminal proteins (TPs) of phages ϕ29 and PRD1, infecting the distantly related bacteria Bacillus subtilis and Escherichia coli, respectively, associate with the host bacterial nucleoid independently of other viral-encoded proteins. Analyses of phage ϕ29 revealed that the TP N-terminal domain (residues 1-73) possesses sequence-independent DNA-binding capacity and is responsible for its nucleoid association. Importantly, we show that in the absence of the TP N-terminal domain the efficiency of ϕ29 DNA replication is severely affected. Moreover, the TP recruits the phage DNA polymerase to the bacterial nucleoid, and both proteins later are redistributed to enlarged helix-like structures in an MreB cytoskeleton-dependent way. These data disclose a key function for the TP in vivo: organizing the early viral DNA replication machinery at the cell nucleoid.

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.

Differential Spo0A-mediated effects on transcription and replication of the related Bacillus subtilis phages Nf and phi29 explain their different behaviours in vivo

Members of groups 1 (e.g. ϕ29) and 2 (e.g. Nf) of the ϕ29 family of phages infect the spore forming bacterium Bacillus subtilis. Although classified as lytic phages, the lytic cycle of ϕ29 can be suppressed and its genome can become entrapped into the B. subtilis spore. This constitutes an alternative infection strategy that depends on the presence of binding sites for the host-encoded protein Spo0A in the ϕ29 genome. Binding of Spo0A to these sites represses ϕ29 transcription and prevents initiation of DNA replication. Although the Nf genome can also become trapped into B. subtilis spores, in vivo studies showed that its lytic cycle is less susceptible to spo0A-mediated suppression than that of ϕ29. Here we have analysed the molecular mechanism underlying this difference showing that Spo0A differently affects transcription and replication initiation of the genomes of these phages. Thus, whereas Spo0A represses all three main early promoters of ϕ29, it only represses one out of the three equivalent early promoters of Nf. In addition, contrary to ϕ29, Spo0A does not prevent the in vitro initiation of Nf DNA replication. Altogether, the differences in Spo0A-mediated regulation of transcription and replication between ϕ29 and Nf explain their different behaviours in vivo.

Different responses to Spo0A-mediated suppression of the related Bacillus subtilis phages Nf and phi29

The phi29 family of phages is divided in three groups. Members of groups 1 and 2 infect the spore-forming bacterium Bacillus subtilis. Previous studies showed that group 1 phage phi29 adapts its infection strategy to the physiological state of the host. Thus, the lytic cycle of phi29 is suppressed when cells are infected during the early stages of sporulation and the infecting genome becomes trapped into the spore. A major element of this adaptive strategy is a very sensitive response to the host-encoded Spo0A protein, the key regulator for sporulation activation, which is directly responsible for suppression of phi29 development. Here we analysed if this adaptation is conserved in phage Nf belonging to group 2. The results obtained show that although Nf also possesses the alternative infection strategy, it is clearly less sensitive to Spo0A-mediated suppression than phi29. Sequence determination of the Nf genome revealed striking differences in the number of Spo0A binding site sequences. The results provide evidence that the life style of two highly related phages is distinctly tuned by differences in binding sites for a host-encoded regulatory protein, being a good example of how viruses have evolved to optimally exploit features of their host.

kinC/D-mediated heterogeneous expression of spo0A during logarithmical growth in Bacillus subtilis is responsible for partial suppression of phi 29 development

The host of the lytic bacteriophage phi 29 is the spore-forming bacterium Bacillus subtilis. When infection occurs during early stages of sporulation, however, phi 29 development is suppressed and the infecting phage genome becomes trapped into the developing spore. Recently, we have shown that Spo0A, the key transcriptional regulator for entry into sporulation, is directly responsible for suppression of the lytic phi 29 cycle in cells having initiated sporulation. Surprisingly, we found that phi 29 development is suppressed in a subpopulation of logarithmically growing culture and that spo0A is heterogeneously expressed during this growth stage. Furthermore, we showed that kinC and, to a minor extent, kinD, are responsible for heterogeneous expression levels of spo0A during logarithmical growth that are below the threshold to activate sporulation, but sufficient for suppression of the lytic cycle of phi 29. Whereas spo0A was known to be heterogeneously expressed during the early stages of sporulation, our findings show that this also occurs during logarithmical growth. These insights are likely to have important consequences, not only for the life cycle of phi 29, but also for B. subtilis developmental processes.

In vivo DNA binding of bacteriophage GA-1 protein p6

Bacteriophage GA-1 infects Bacillus sp. strain G1R and has a linear double-stranded DNA genome with a terminal protein covalently linked to its 5' ends. GA-1 protein p6 is very abundant in infected cells and binds DNA with no sequence specificity. We show here that it binds in vivo to the whole viral genome, as detected by cross-linking, chromatin immunoprecipitation, and real-time PCR analyses, and has the characteristics of a histone-like protein. Binding to DNA of GA-1 protein p6 shows little supercoiling dependency, in contrast to the ortholog protein of the evolutionary related Bacillus subtilis phage phi29. This feature is a property of the protein rather than the DNA or the cellular background, since phi29 protein p6 shows supercoiling-dependent binding to GA-1 DNA in Bacillus sp. strain G1R. GA-1 DNA replication is impaired in the presence of the gyrase inhibitors novobiocin and nalidixic acid, which indicates that, although noncovalently closed, the viral genome is topologically constrained in vivo. GA-1 protein p6 is also able to bind phi29 DNA in B. subtilis cells; however, as expected, the binding is less supercoiling dependent than the one observed with the phi29 protein p6. In addition, the nucleoprotein complex formed is not functional, since it is not able to transcomplement the DNA replication deficiency of a phi29 sus6 mutant. Furthermore, we took advantage of phi29 protein p6 binding to GA-1 DNA to find that the viral DNA ejection mechanism seems to take place, as in the case of phi29, with a right to left polarity in a two-step, push-pull process.

40 Years with Bacteriophage ø29

I have dedicated the past 46 years of my life to science and I expect to be active in research for many more years. I have been lucky in my professional life. During my postdoctoral years I discovered two proteins that I showed to be involved in the initiation of protein synthesis. Working with bacteriophage ø29 for the past 40 years, we have made many interesting findings. Among them is the discovery of a protein covalently linked to the 5′ ends of ø29 DNA that we later showed to be the primer for the initiation of ø29 DNA replication. Also, the finding of the ø29 DNA polymerase with its properties of high processivity, strand displacement, and high fidelity has been very rewarding. The ø29 DNA polymerase has become the ideal enzyme for DNA amplification, both rolling circle and whole-genome amplification. I also am happy because I have worked with many brilliant students and collaborators over the years, most of whom have become excellent scientists.

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.

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.

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.

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.

Binding of phage Phi29 architectural protein p6 to the viral genome: evidence for topological restriction of the phage linear DNA

Bacillus subtilis phage Phi29 protein p6 is required for DNA replication and promotes the switch from early to late transcription. In vivo it binds all along the viral linear DNA, which suggests a global role as an architectural protein; in contrast, binding to bacterial DNA is negligible. This specificity could be due to the p6 binding preference for less negatively supercoiled DNA, as is presumably the case with viral (with respect to bacterial) DNA. Here we demonstrate that p6 binding to Phi29 DNA is greatly increased when negative supercoiling is decreased by novobiocin; in addition, gyrase is required for DNA replication. This indicates that, although non-covalently closed, the viral genome is topologically constrained in vivo. We also show that the p6 binding to different Phi29 DNA regions is modulated by the structural properties of their nucleotide sequences. The higher affinity for DNA ends is possibly related to the presence of sequences in which their bendability properties favor the formation of the p6-DNA complex, whereas the lower affinity for the transcription control region is most probably due to the presence of a rigid intrinsic DNA curvature.

Spore-specific modification of DNA-dependent RNA polymerase alpha subunit in streptomycetes--a new model of transcription regulation

At the very beginning of spore germination in streptomycetes the full-length alpha subunit of DNA-dependent RNA polymerase is shortened from its C-terminus. The C-terminal domain of the protein is required for binding of DNA and transcription regulators but its regulatory role in streptomycetes was not extensively studied. Comparison of the sequences of E. coli and S. coelicolor RNA polymerase alpha subunit (RNAP alpha) C-terminal domains reveals that the majority of amino acid residues responsible for the interaction with transcription regulators is conserved in both microorganisms. The spore specific modification of streptomycete RNAP alpha could thus have its regulatory role. The nature of the proteolytic enzyme, responsible for the RNAP alpha cleavage is 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 Bacillus subtilis phage phi 29 protein p16.7, involved in phi 29 DNA replication, is a membrane-localized single-stranded DNA-binding protein

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

Analysis of early promoters of the Bacillus bacteriophage GA-1

Bacteriophage GA-1, which infects Bacillus sp. strain G1R, is evolutionarily related to phage phi29, which infects Bacillus subtilis. We report the characterization of several GA-1 promoters located at either end of its linear genome. Some of them are unique for GA-1 and drive the expression of open reading frames that have no counterparts in the genome of phi29 or related phages. These unique promoters are active at early infection times and are repressed at late times. In vitro transcription reactions revealed that the purified GA-1-encoded protein p6 represses the activity of these promoters, although the amount of p6 required to repress transcription was different for each promoter. The level of protein p6 produced in vivo increases rapidly during the first stage of the infection cycle. The protein p6 concentration may serve to modulate the expression of these early promoters as infection proceeds.

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.

Repression of bacteriophage phi 29 early promoter C2 by viral protein p6 is due to impairment of closed complex

Bacillus subtilis phage phi 29 encodes a very abundant protein, p6, which is a non sequence-specific DNA-binding protein. Protein p6 has the potential to bind cooperatively to the phage genome, forming a nucleoprotein complex in which the DNA adopts a right-handed toroidal conformation winding around a protein core. The formation of this complex at the right end of the phage genome where the early promoter C2 is located affects local topology, which may contribute to the promoter repression, although the underlying molecular mechanism of this repression is not presently known. In this study, we analyzed the effect of the p6 nucleoprotein complex on the formation of transcription complexes at the C2 promoter. The results obtained indicate that the nucleoprotein complex does not occlude promoter C2 to RNA polymerase because both proteins can bind to the same DNA molecule. Protein p6 binds along the fragment including the sequence adjacent to the bound polymerase, altering the structure of the transcriptional complex and affecting specifically the stability of the closed complex. The findings presented might help to answer some of the open questions about the concerted molecular mechanisms of histone-like proteins as transcriptional silencers.

Repression of transcription initiation at 434 P(R) by 434 repressor: effects on transition of a closed to an open promoter complex

The lambdoid bacteriophage repressors function both as transcription activators and repressors. Regulation of transcription at the adjacent, but divergent promoters, P(RM) and P(R), determines the phage's choice between the lytic and lysogenic development pathways. Here, we demonstrate that 434 repressor bound at 434 O(R)1 alone is not sufficient to repress transcription from 434 P(R,) but that 434 repressor bound at 434 O(R)2 alone is necessary and sufficient to repress P(R )transcription. This is different from what occurs in the related bacteriophage lambda, in which binding of lambda repressor to either lambdaO(R)1 or lambdaO(R)2 represses transcription from lambdaP(R). The combined results of gel mobility shift and KMnO(4) footprinting assays show that while 434 repressor binding to 434 O(R)2 does not preclude RNA polymerase binding at the P(R) promoter, it does prevent it from forming open complexes at this promoter. The RNA polymerase-P(R) complexes that form in the presence of repressor are heparin-resistant and the DNA is not melted. This observation indicates that 434 repressor bound at 434 O(R)2 inhibits transcription initiation at the P(R) promoter by "locking" the RNA polymerase-P(R) complex into an inactive state instead of "blocking" the access of RNA polymerase to promoter DNA.

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.

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

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

Pleiotropic effect of protein P6 on the viral cycle of bacteriophage phi29

The product of bacteriophage phi29 early gene 6, protein p6, is a double-stranded-DNA binding protein and one of the more abundant proteins during viral infection. We have studied the role of protein p6 in vivo through the infection of suppressor and nonsuppressor Bacillus subtilis strains with a phage carrying a nonsense mutation in gene 6, sus6(626). In the absence of functional protein p6, the two major processes of the viral cycle, transcription and DNA replication, were affected. Viral DNA synthesis was practically abolished, and early transcription was remarkably delayed and, in addition, underregulated at late times of the infection. The amount of protein p6 synthesized after infection with mutant phage sus6(626) under suppressor conditions was sixfold lower than that produced after wild-type infection. Nonetheless, phage production was as high as that obtained after wild-type infection. These results indicate that p6 is synthesized in amounts higher than those needed for most of its functions. However, the concentration of protein p6 appeared to be important for repression of the early promoter C2.

Identification and characterization of a novel transcriptional regulator, MatR, for malonate metabolism in Rhizobium leguminosarum bv. trifolii

A novel gene, matR, located upstream of matABC, transcribed in the opposite direction, and encoding a putative regulatory protein by sequence analysis was discovered from Rhizobium leguminosarum bv. trifolii. The matA, matB, and matC genes encode malonyl-CoA decarboxylase, malonyl-CoA synthetase, and a presumed malonate transporter, respectively. Together, these enzymes catalyze the uptake and conversion of malonate to acetyl-CoA. The deduced amino-acid sequence of matR showed sequence similarity with GntR from Bacillus subtilis in the N-terminal region encoding a helix-turn-helix domain. Electrophoretic mobility shift assay indicated that MatR bound to a fragment of DNA corresponding to the mat promoter region. The addition of malonate or methylmalonate increased the association of MatR and DNA fragment. DNase I footprinting assays identified a MatR binding site encompassing 66 nucleotides near the mat promoter. The mat operator region included an inverted repeat (TCTTGTA/TACACGA) centered -46.5 relative to the transcription start site. Transcriptional assays, using the luciferase gene, revealed that MatR represses transcription from the mat promoter and malonate alleviates MatR-mediated repression effect on the expression of Pmat-luc+ reporter fusion.

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

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

Mutually exclusive utilization of P(R) and P(RM) promoters in bacteriophage 434 O(R)

Establishment and maintenance of a lysogen of the lambdoid bacteriophage 434 require that the 434 repressor both activate transcription from the P(RM) promoter and repress transcription from the divergent P(R) promoter. Several lines of evidence indicate that the 434 repressor activates initiation of P(RM) transcription by occupying a binding site adjacent to the P(RM) promoter and directly contacting RNA polymerase. The overlapping architecture of the P(RM) and P(R) promoters suggests that an RNA polymerase bound at P(R) may repress P(RM) transcription initiation. Hence, part of the stimulatory effect of the 434 repressor may be relief of interference between RNA polymerase binding to the P(RM) promoter and to the P(R) promoter. Consistent with this proposal, we show that the repressor cannot activate P(RM) transcription if RNA polymerase binds at P(R) prior to addition of the 434 repressor. However, unlike the findings with the related lambda phage, formation of RNA polymerase promoter complexes at P(RM) and at P(R) apparently are mutually exclusive. We find that the RNA polymerase-mediated inhibition of repressor-stimulated P(RM) transcription requires the presence of an open complex at P(R). Taken together, these results indicate that establishment of an open complex at P(R) directly prevents formation of an RNA polymerase-P(RM) complex.

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.