Regulatory gene 28 of bacteriophage SPO1 codes for a phage-induced subunit of RNA polymerase

Exploring the synthetic biology potential of bacteriophages for engineering non-model bacteria

Non-model bacteria like Pseudomonas putida, Lactococcus lactis and other species have unique and versatile metabolisms, offering unique opportunities for Synthetic Biology (SynBio). However, key genome editing and recombineering tools require optimization and large-scale multiplexing to unlock the full SynBio potential of these bacteria. In addition, the limited availability of a set of characterized, species-specific biological parts hampers the construction of reliable genetic circuitry. Mining of currently available, diverse bacteriophages could complete the SynBio toolbox, as they constitute an unexplored treasure trove for fully adapted metabolic modulators and orthogonally-functioning parts, driven by the longstanding co-evolution between phage and host.

Transcriptional Regulation and Mechanism of SigN (ZpdN), a pBS32-Encoded Sigma Factor in Bacillus subtilis

Laboratory strains of Bacillus subtilis encode many alternative sigma factors, each dedicated to expressing a unique regulon such as those involved in stress resistance, sporulation, and motility. The ancestral strain of B. subtilis also encodes an additional sigma factor homolog, ZpdN, not found in lab strains due to being encoded on the large, low-copy-number plasmid pBS32, which was lost during domestication. DNA damage triggers pBS32 hyperreplication and cell death in a manner that depends on ZpdN, but how ZpdN mediates these effects is unknown. Here, we show that ZpdN is a bona fide sigma factor that can direct RNA polymerase to transcribe ZpdN-dependent genes, and we rename ZpdN SigN accordingly. Rend-seq (end-enriched transcriptome sequencing) analysis was used to determine the SigN regulon on pBS32, and the 5' ends of transcripts were used to predict the SigN consensus sequence. Finally, we characterize the regulation of SigN itself and show that it is transcribed by at least three promoters: P_sigN1 , a strong SigA-dependent LexA-repressed promoter; P_sigN2 , a weak SigA-dependent constitutive promoter; and P_sigN3 , a SigN-dependent promoter. Thus, in response to DNA damage SigN is derepressed and then experiences positive feedback. How cells die in a pBS32-dependent manner remains unknown, but we predict that death is the product of expressing one or more genes in the SigN regulon.IMPORTANCE Sigma factors are utilized by bacteria to control and regulate gene expression. Some sigma factors are activated during times of stress to ensure the survival of the bacterium. Here, we report the presence of a sigma factor that is encoded on a plasmid that leads to cellular death after DNA damage.

The pneumococcal σX activator, ComW, is a DNA-binding protein critical for natural transformation

Natural genetic transformation via horizontal gene transfer enables rapid adaptation to dynamic environments and contributes to both antibiotic resistance and vaccine evasion among bacterial populations. In Streptococcus pneumoniae (pneumococcus), transformation occurs when cells enter competence, a transient state in which cells express the competence master regulator, SigX (σ^Χ), an alternative σ factor (σ), and a competence co-regulator, ComW. Together, ComW and σ^X facilitate expression of the genes required for DNA uptake and genetic recombination. SigX activity depends on ComW, as ΔcomW cells transcribe late genes and transform at levels 10- and 10,000-fold below that of WT cells, respectively. Previous findings suggest that ComW functions during assembly of the RNA polymerase-σ^X holoenzyme to help promote transcription from σ^X-targeted promoters. However, it remains unknown how ComW facilitates holoenzyme assembly. As ComW seems to be unique to Gram-positive cocci and has no sequence similarity with known transcriptional activators, here we used Rosetta to generate an ab initio model of pneumococcal ComW's 3D-structure. Using this model as a basis for further biochemical, biophysical, and genetic investigations into the molecular features important for its function, we report that ComW is a predicted globular protein and that it interacts with DNA, independently of DNA sequence. We also identified conserved motifs in ComW and show that key residues in these motifs contribute to DNA binding. Lastly, we provide evidence that ComW's DNA-binding activity is important for transformation in pneumococcus. Our findings begin to fill the gaps in understanding how ComW regulates σ^Χ activity during bacterial natural transformation.

Where to begin? Sigma factors and the selectivity of transcription initiation in bacteria

Transcription is the fundamental process that enables the expression of genetic information. DNA-directed RNA polymerase (RNAP) uses one strand of the DNA duplex as template to produce complementary RNA molecules that serve in translation (rRNA, tRNA), protein synthesis (mRNA) and regulation (sRNA). Although the RNAP core is catalytically competent for RNA synthesis, the selectivity of transcription initiation requires a sigma (σ) factor for promoter recognition and opening. Expression of alternative σ factors provides a powerful mechanism to control the expression of discrete sets of genes (a σ regulon) in response to specific nutritional, developmental or stress-related signals. Here, I review the key insights that led to the original discovery of σ factor 50 years ago and the subsequent discovery of alternative σ factors as a ubiquitous mechanism of bacterial gene regulation. These studies form a prelude to the more recent, genomics-enabled insights into the vast diversity of σ factors in bacteria.

Characterization of Five Novel Brevibacillus Bacteriophages and Genomic Comparison of Brevibacillus Phages

Brevibacillus laterosporus is a spore-forming bacterium that causes a secondary infection in beehives following European Foulbrood disease. To better understand the contributions of Brevibacillus bacteriophages to the evolution of their hosts, five novel phages (Jenst, Osiris, Powder, SecTim467, and Sundance) were isolated and characterized. When compared with the five Brevibacillus phages currently in NCBI, these phages were assigned to clusters based on whole genome and proteome synteny. Powder and Osiris, both myoviruses, were assigned to the previously described Jimmer-like cluster. SecTim467 and Jenst, both siphoviruses, formed a novel phage cluster. Sundance, a siphovirus, was assigned as a singleton phage along with the previously isolated singleton, Emery. In addition to characterizing the basic relationships between these phages, several genomic features were observed. A motif repeated throughout phages Jenst and SecTim467 was frequently upstream of genes predicted to function in DNA replication, nucleotide metabolism, and transcription, suggesting transcriptional co-regulation. In addition, paralogous gene pairs that encode a putative transcriptional regulator were identified in four Brevibacillus phages. These paralogs likely evolved to bind different DNA sequences due to variation at amino acid residues predicted to bind specific nucleotides. Finally, a putative transposable element was identified in SecTim467 and Sundance that carries genes homologous to those found in Brevibacillus chromosomes. Remnants of this transposable element were also identified in phage Jenst. These discoveries provide a greater understanding of the diversity of phages, their behavior, and their evolutionary relationships to one another and to their host. In addition, they provide a foundation with which further Brevibacillus phages can be compared.

A love affair with Bacillus subtilis

My career in science was launched when I was an undergraduate at Princeton University and reinforced by graduate training at the Massachusetts Institute of Technology. However, it was only after I moved to Harvard University as a junior fellow that my affections were captured by a seemingly mundane soil bacterium. What Bacillus subtilis offered was endless fascinating biological problems (alternative sigma factors, sporulation, swarming, biofilm formation, stochastic cell fate switching) embedded in a uniquely powerful genetic system. Along the way, my career in science became inseparably interwoven with teaching and mentoring, which proved to be as rewarding as the thrill of discovery.

Without a license, or accidents waiting to happen

This is a memoir of circumstances that have shaped my life as a scientist, some of the questions that have excited my interest, and some of the people with whom I have shared that pursuit. I was introduced to transcription soon after the discovery of RNA polymerase and have been fascinated by questions relating to gene regulation since that time. My account touches on early experiments dealing with the ability of RNA polymerase to selectively transcribe its DNA template. Temporal programs of transcription that control the multiplication cycles of viruses (phages) and the precise mechanisms generating this regulation have been a continuing source of fascination and new challenges. A longtime interest in eukaryotic RNA polymerase III has centered on yeast and on the enumeration and properties of its transcription initiation factors, the architecture of its promoter complexes, and the mechanism of transcriptional initiation. These areas of research are widely regarded as separate, but to my thinking they have posed similar questions, and I have been unwilling or unable to abandon either one for the other. An additional interest in archaeal transcription can be seen as stemming naturally from this point of view.

Bacteriophages: how bacterial spores capture and protect phage DNA

A recent study explains how bacterial spores capture and protect phage DNA, which remains free in the host cytoplasm but is unable to initiate the virulence pathway that leads to lysis of actively growing bacterial cells.

Bacillus subtilis mutant allele sup-3 causes lysine insertion at ochre codons: use of sup-3 in studies of translational attenuation

The mutation sup-3 in Bacillus subtilis suppresses ochre (TAA) mutations at each of three codons in the 5' end of the cat-86 coding sequence. The suppressor is shown to insert lysine at ochre codons. The efficiency of suppression by sup-3 is about 15%, as determined by changing a cat-86 Lys codon (codon 12) to an ochre codon and measuring the level of CAT in the suppressor-containing strain. The results obtained are discussed in light of previous observations that ochre mutations at cat leader codons 2 and 3 can be phenotypically suppressed by sup-3, whereas ochre mutations at leader codons 4 and 5 cannot. Translation of the cat leader is essential to inducible expression of cat. Our data support the interpretation that the nature of amino acids 2 through 5 of the leader peptide contributes to determining whether chloramphenicol can stall a ribosome in the leader, which in turn leads to induction of cat expression.

Gene encoding the sigma 37 species of RNA polymerase sigma factor from Bacillus subtilis

sigma 37 is a minor species of RNA polymerase sigma factor found in the Gram-positive bacterium Bacillus subtilis. sigma 37 governs the transcription in vitro of genes that are turned on at an early stage in spore formation, as well as other genes that are switched on at the end of the exponential phase of growth but that are not under sporulation control. To study the role of sigma 37 in B. subtilis gene expression, we have cloned the gene for this minor species of sigma factor in Escherichia coli by using as a hybridization probe a synthetic oligonucleotide that was designed on the basis of the NH2-terminal amino acid sequence of sigma 37 protein. We determined the nucleotide sequence of the entire sigma 37 gene, which was found to encode a 262-amino acid residue polypeptide of 29.9 kDa. The predicted amino acid sequence of sigma 37 showed significant homology to that of other sigma proteins in a region that has been proposed to be the site of binding of these factors to core RNA polymerase. Genetic mapping experiments placed the gene for sigma 37, herein designated sigB, at 40 degrees on the genetic map of Piggot and Hoch [Piggot, P. & Hoch, J. A. (1985) Microbiol. Rev. 49, 158-179]. An insertion mutation was constructed in sigB and found not to impair growth or sporulation.

Mapping the genes in the terminal redundancy of bacteriophage SPO1 with restriction endonucleases

Although most early transcription from SPO1, a lytic DNA bacteriophage of Bacillus subtilis, is specified by the 12.6-kilobase region of the terminal redundancy, early genes from this region have not been identified by standard genetic means. We mapped genes to DNA regions of the SPO1 terminal redundancy by analyzing in vitro protein synthesis from isolated SPO1 restriction fragments in an Escherichia coli-coupled transcription-translation cell-free system. DNA from the terminal redundancy directs the synthesis in vitro of eleven proteins, e3, e4, e6, e7, e9, e12, e15, e16, e18, e20, and e21, which correspond in mobility on sodium dodecyl sulfate-polyacrylamide gels with authentic SPO1 early proteins. From their mapped positions on the DNA, genes were positioned downstream from most, but not all, of the twelve early promoter regions identified in vitro in the terminal redundancy. The temporal patterns of early protein synthesis in vivo suggest a differential turning on and off of early promoters in the terminal redundancy. Both in vivo and in vitro evidence suggests the existence of previously unidentified early promoter regions upstream from the genes for e6 and e4 as well as a middle promoter region upstream from the gene for e16.

Bacteriophage SPO1 DNA polymerase and the activity of viral gene 31

Bacteriophage SPO1 DNA-negative (D0) mutants were tested for the induction of viral DNA polymerase during Bacillus subtilis infection. Extracts from SPO1-infected bacteria exhibited enzymatic activity when representative mutants of seven out of the nine known D0 genes were employed. This activity was undetectable in cells infected with mutants in genes 28 and 31. The product of gene 28 (gp28) is known to be responsible for turning on SPO1 middle gene expression. Results show that nonsense mutation in gene 31 leads to the absence of a single polypeptide of 100-105 kDa and that phage DNA synthesis "in vivo" directly depends on gp31 activity. Based on these data it is proposed that SPO1 gene 31 codes for the viral DNA polymerase.

Cloning and mapping of the SPO1 genome

Many of the XbaI, EcoRI, KpnI, and BglII fragments of bacteriophage SPO1, accounting for about 65% of the genomic sequences, were cloned in Bacillus subtilis. Four of the EcoRI fragments were specifically refractory to cloning in both Escherichia coli and B. subtilis, probably because of expression of deleterious genes carried on the SPO1 fragments. To permit complete identification of the regions cloned, the SPO1 restriction map has been extended to include the XbaI fragments and the previously unmapped KpnI fragments. Markers for 26 of the 39 known genes have been located on specific cloned fragments, permitting more precise determination of the positions of most of the genes. One cloned SPO1 fragment was inhibitory to SPO1 development.

Bacteriophage SPO1 genes 33 and 34. Location and primary structure of genes encoding regulatory subunits of Bacillus subtilis RNA polymerase

Bacteriophage SPO1 gene 33 and 34 products are required for SPO1 late gene transcription. Both proteins bind to the core RNA polymerase of the Bacillus subtilis host to direct the recognition of SPO1 late gene promoters, whose sequences differ from those of SPO1 early and middle gene promoters. We have located and cloned the genes for these two regulatory proteins, and have engineered their expression in Escherichia coli by placing them under the control of the bacteriophage lambda PL promoter. Nucleotide sequence analysis indicated that genes 33 and 34 overlap by 4 base-pairs and encode highly charged, slightly basic proteins of molecular weight 11,902 and 23,677, respectively.

Defining a bacteriophage T4 late promoter: bacteriophage T4 gene 55 protein suffices for directing late promoter recognition

The RNA polymerase from bacteriophage T4-infected Escherichia coli, which specifically initiates transcription at phage T4 late promoters, is extensively modified by ADP-ribosylation of core subunits and by binding several virus-encoded subunits. We show here that one of these subunits, the phage T4 gene 55 protein, designated gp55, alone endows unmodified RNA polymerase core enzyme from uninfected E. coli with the ability to selectively initiate transcription at the phage T4 late promoters, without participation by E. coli RNA polymerase o- subunit.

Bacteriophage SPO1 gene 27: location and nucleotide sequence

Bacteriophage SPO1 gene 27, whose product is required for late gene transcription and DNA replication, has been cloned in Escherichia coli, and its complete nucleotide sequence has been determined. We infer that the product of gene 27 is a highly basic 17,518-dalton protein of 155 amino acids. The gene for this regulatory protein is transcribed from two promoters: an early promoter situated before the adjacent upstream gene 28 and a middle promoter located between genes 28 and 27.

Structure of a Bacillus subtilis bacteriophage SPO1 gene encoding RNA polymerase sigma factor

Gene 28 of Bacillus subtilis bacteriophage SPO1 codes for a regulatory protein, a sigma factor known as sigma gp28, that binds to the bacterial core RNA polymerase to direct the recognition of phage middle gene promoters. middle promoters exhibit distinctive and conserved nucleotide sequences in two regions centered about 10 and 35 base pairs upstream from the start point of mRNA synthesis. Here we report the cloning of gene 28 and its complete nucleotide sequence. We infer that sigma gp28 is a 25,707-dalton protein of 220 amino acids. Neither the nucleotide sequence of gene 28 nor the inferred amino acid sequence of sigma gp28 exhibits extensive homology to the gene or protein sequence of Escherichia coli sigma factor.

Chromosomal location of a Bacillus subtilis DNA fragment uniquely transcribed by sigma-28-containing RNA polymerase

A fragment of the Bacillus subtilis chromosome containing a gene whose transcription is dependent on sigma-28-containing RNA polymerase has been genetically mapped by means of an integrable plasmid. This gene resides on the chromosome adjacent to the stage 0 sporulation locus spo0E between metC and citL. The gene was insertionally inactivated by cloning an internal EcoRI-HindIII fragment in the integrable plasmid pJH101 and by inserting the plasmid into the chromosome by transformation. Transformants bearing an inactivated gene were indifferent to this inactivation for both growth and sporulation.

Transcriptional regulation of bacteriophage SPO1 protein synthesis in vivo and in vitro

There are six classes of SPO1 transcripts which are, at least partially, regulated independently of each other. Analysis of proteins made in infections by phage mutants defective in DNA synthesis, or in genes which positively control transcription, permitted each protein to be assigned to one transcription class. Most of the late proteins belong to transcription class m2l. There seem to be few, if any, phage proteins in the l class whose mRNA synthesis depends absolutely on phage DNA synthesis, UV irradiation of host cells allowed the detection of many additional early proteins. The early proteins detected in vivo were compared with proteins synthesized in vitro, using bacterial or gp28 phage-modified RNA polymerase in an Escherichia coli cell-free system. Proteins characterized in vivo as belonging to the e transcription class could be made efficiently in vitro only when transcription was performed by bacterial RNA polymerase. em proteins could be elicited through the use of either bacterial or gp28 polymerase, indicating that their genes can be transcribed in either the early or the middle mode.

SP01 gene 27 is required for viral late transcription

The SP01 mutant sus HA20 (gene 27) was found to be defective for synthesis of viral late RNA. It is known that gene 27 is also required for viral DNA replication. The SP01 gene 27 product resembles the T4 gene 45 product, which also has a dual role in viral DNA replication and late transcription.

Novel RNA polymerase sigma factor from Bacillus subtilis

A modified form of Bacillus subtilis RNA polymerase (RNA nucleotidyltransferase) has been isolated that exhibits distinctive transcriptional specificity. This modified enzyme transcribes two cloned genes from the purA-cysA region of the B. subtilis chromosome whose expression in vivo is associated with the process of sporulation. Neither of these genes is transcribed by the usual form of B. subtilis RNA polymerase holoenzyme containing a sigma factor of 55,000 daltons (sigma 55). The modified RNA polymerase lacks sigma 55 but contains a newly identified subunit of 37,000 daltons termed sigma 37. A reconstitution experiment in which sigma 37 was added to core RNA polymerase strongly suggests that sigma 37 is responsible for the transcriptional specificity of the modified RNA polymerase. Sigma 37 apparently acts at the level of promoter recognition; this transcriptional determinant enabled core RNA polymerase to form stable binary and ternary ("initiation") complexes with endonuclease restriction fragments containing promoters for the cloned B. subtilis genes.

Novobiocin blocks the shutoff of SPO1 early transcription

Novobiocin, an inhibitor of bacterial DNA gyrase strongly impairs the development of bacteriophage SPOl. DNA replication seems to be the primary target for the antibiotic in this system, but viral-coded transcription is also affected in several aspects: (a) The level of phage transcription is diminished; (b) the shutoff of the synthesis of early RNA classes is inhibited; (c) RNAs of late class are not synthesized. This last effect is a consequence of the coupling between transcription and replication. The other two results could be taken as an indication that the appropriate secondary structure of the parental phage DNA is a requisite for the recognition of promoters. The introduction of negative turns by DNA gyrase seems to make early genes unavailable for transcription.

The nature of transcription selectivity of bacteriophage SPO1-modified RNA polymerase

Escherichia coli and Bacillus subtilis RNA polymerase have almost identical transcription specificities on bacteriophage SPO1 DNA when assayed in a coupled transcription-translation cell free system. SPO1-modified B. subtilis RNA polymerase has altered transcription specificity. It is shown that rifampicin-inhibited E. coli RNA polymerase can completely block transcription of SPO1 DNA by rifampicin resistant B. subtilis enzyme, whereas it has no effect on transcription by SPO1-modified B. subtilis RNA polymerase. We conclude that the new transcription by SPO1-modified RNA polymerase results from newly recognized promoters, rather than by elongation of transcripts which could also be made by B. subtilis vegetative RNA polymerase.

Purification of a positive regulatory subunit from phage SP01-modified RNA polymerase

A phage-induced subunit has been purified from phage SP01-modified Bacillus subtilis RNA polymerase. This subunit binds in vitro to RNA polymerase core from uninfected B. subtilis thereby template-selective transcription and asymmetric synthesis of SP01 middle RNA.