Purification of Ribonucleic Acid Polymerase from SP82-infected Bacillus subtilis

Bacillus subtilis RNA polymerase and its modification in sporulating and phage-infected bacteria

Bacillus subtilis RNA polymerase holoenzyme consists of the subunits beta', beta, sigma, alpha, delta, and omega. In sporulating bacteria and in bacteria infected with phages SP01 and SP82, this enzyme undergoes changes in subunit composition and transcriptional specificity that could play a regulatory role in gene transcription. Sporulating bacteria may contain a specific component that inhibits the activity of the sigma subunit of polymerase probably by interfering with the binding of sigma-polypeptide to core enzyme. The hypothetical inhibitor may be metabolically unstable, since its activity is rapidly depleted from sporulating cells in the presence of chloramphenicol. Inhibition of sigma-polypeptide activity may restrict the transcription of phage DNA an infected sporulating cells. Although lacking the sigma-subunit, RNA polymerase purified from sporulating cells contains sporulation-specific subunits of 85,000 and 27,000 daltons. In SP01-infected bacteria, the sigma-subunit is replaced by phage-induced subunits. Purified enzyme containing the protein product of SP01 regulatory gene 28 directs the transcription of phage middle genes in vitro, while enzyme containing phage-induced polypeptides V and VI preferentially copies late genes. Accurate transcription of middle and late genes in vitro requires the host delta-subunit of polymerase (or high ionic strength) but not sigma-subunit. Phage PBS2 induces an entirely new multisubunit RNA polymerase that specifically transcribes PBS2 DNA in vitro. This enzyme is synthesized de novo after infection and does not arise by modification of the B. subtilis holoenzyme.

Mechanism of initiation of transcription by Bacillus subtilis RNA polymerase at several promoters

The behavior of the major vegetative cell RNA polymerase of Bacillus subtilis, E sigma A, during initiation of transcription was compared to that of its Escherichia coli counterpart, E sigma 70, at several promoters known to be actively transcribed by both RNA polymerases. Challenge experiments using heparin, restriction endonucleases, and competing promoter DNA under various conditions showed that, at several promoters, complexes with B. subtilis RNA polymerase formed in the absence of nucleoside triphosphates were unstable. These complexes produced DNase I footprints that were less extended than those produced by the E. coli enzyme at the same promoters. Further, in the presence of certain combinations of nucleoside triphosphates, conditions that allow production of abortive oligonucleotides, these B. subtilis RNA polymerase complexes remained dissociable. Thus, at these promoters, the B. subtilis enzyme interacted with the DNA and reached a catalytically active initial transcribing complex without becoming committed to the template. At these same promoters, E. coli RNA polymerase formed stable open complexes before forming any phosphodiester bonds. B. subtilis initial transcribing complexes also remained sensitive to the drug rifampicin until a later stage in the initiation process than did the corresponding E. coli complexes. At one promoter, B. subtilis E sigma A and E. coli E sigma 70 behaved similarly, forming stable open complexes in the absence of any nucleoside triphosphates.

Separation of Escherichia coli RNA polymerase sigma-70 holoenzyme from core enzyme on heparin-Sepharose columns

A method is described for the rapid purification of DNA-dependent RNA polymerase sigma-70 holoenzyme from Escherichia coli. The essential step in this protocol involves the differential elution of sigma-70 holoenzyme from core polymerase on a heparin-Sepharose column. Using a linear gradient of KCl, holoenzyme was found to elute at 0.25 M whereas core polymerase eluted at 0.35 M. From 20 g of cells, up to 1 mg of RNA polymerase holoenzyme could be isolated in two days. The preparations were greater than 95% pure with respect to protein, and saturated with the sigma subunit.

Effect of the delta subunit of Bacillus subtilis RNA polymerase on initiation of RNA synthesis at two bacteriophage phi 29 promoters

Initiation of RNA synthesis by Bacillus subtilis RNA polymerase (sigma-43) has been examined at two early promoters of phage phi 29: the A2 promoter, which is a weak promoter, and the G2 promoter, which is a strong promoter. The delta subunit of the polymerase inhibits the rate of initiation at A2, but not G2. In addition, formation of stable complexes by the polymerase at A2, but not at G2, requires the presence of the first two nucleotides of the A2 transcript.

New Ways to Study Developmental Genes in Spore-Forming Bacteria

The regulated activation of numerous sets of genes in multiple chromosomal locations is a hallmark of cellular differentiation in both eukaryotes and prokaryotes. Certain species of bacteria that experience complex developmental cycles are especially attractive as systems in which to study the mechanisms of this kind of gene regulation because they are highly amenable to both biochemical and genetic approaches. Bacillus subtilis, which undergoes extensive cellular differentiation when it sporulates, is one such system. Many new methods are now available in this Gram-positive species for identifying, manipulating, and studying the regulation of genes involved in spore formation, including the use of transposable genetic elements that create gene fusions in vivo as an automatic consequence of insertions into genes.

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.

The virus-specified subunits of a modified B. subtilis RNA polymerase are determinants of DNA binding and RNA chain initiation

The phage SPO1-modified RNA polymerase B-P can form rapidly initiating complexes with SPO1 DNA but not with heterologous phi1 DNA. The B-P enzyme binds only weakly to heterologous phi29 DNA: preincubation with phi29 DNA does not substantially slow the formation of rapidly initiating complexes between polymerase B-P and subsequently added SPO1 DNA. In contrast, B. subtilis holoenzyme and core polymerase are substantially sequestered by preincubation with phi29 DNA. The results show that at least one of the phage SPO1-coded subunits of the polymerase B-P determines selective transcription at the level of DNA binding and RNA chain initiation, weakens the binding of RNA polymerase core to heterologous DNA, and discriminates against promoter complex formation at certain promoters that are utilized by the B. subtilis holoenzyme.

DNA strand specificity of temporal RNA classes produced during infection of Bacillus subtilis by SP82

The DNA of the Bacillus subtilis bacteriophage SP82 has been separated into heavy (H) and light (L) fractions by centrifugation in buoyant density gradients in the presence of polyguanylic acid. Competition-hybridization experiments were performed with these separated fractions using RNAs isolated from cells labeled at intervals which account for 80% of the lytic cycle and unlabeled competitor RNAs isolated from phage-infected cells at 2-min intervals throughout infection. The analysis of temporal RNA classes were facilitated by use of a double reciprocal plot of the data. Five temporal classes binding to the H fraction and three binding to the L fraction were detected; the possible existence of an additional class transcribed from the H fraction is discussed. RNA synthesized in the presence of chloramphenicol contains two of the three classes produced from L-DNA and two of the five classes transcribed from H-DNA.