Two polypeptides associated with the ribonucleic acid polymerase core of Bacillus subtilis during sporulation

Identification and characterization of a stress-responsive promoter in the macromolecular synthesis operon of Bacillus subtilis

Bacillus subtilis DB1005 is a temperature-sensitive (Ts) sigA mutant. Induction of sigmaA has been observed exclusively in this mutant harbouring extra copies of the plasmid-borne Ts sigA gene transcriptionally controlled by the P1P2 promoters of the B. subtilis macromolecular synthesis (MMS; rpoD or sigA) operon. Investigation of the mechanisms leading to the induction has allowed us to identify a sigmaB-type promoter, P7, in the MMS operon for the first time. Therefore, at least seven promoters in total are responsible for the regulation of the B. subtilis MMS operon, including the four known sigmaA- and sigmaH-type promoters, as well as two incompletely defined promoters. The P7 promoter was activated in B. subtilis after the imposition of heat, ethanol and salt stresses, indicating that the MMS operon of B. subtilis is subjected to the control of general stress. The significant heat induction of P7 in B. subtilis DB1005 harbouring a plasmid-borne Ts sigA gene can be explained by a model of competition between sigmaA and sigmaB for core binding; very probably, the sigmaB factor binds more efficiently to core RNA polymerase under heat shock. This mechanism may provide a means for the expression of the B. subtilis MMS operon when sigmaA becomes defective in core binding.

The temperature sensitivity of Bacillus subtilis DB1005 is due to insufficient activity, rather than insufficient concentration, of the mutant delta A factor

The delta A factor of Bacillus subtilis DB1005 contains two amino acid substitutions (I198A and I202A) in the promoter-10 binding region. It has been confirmed that this delta factor is responsible for the temperature sensitivity of B. subtilis DB1005. An investigation was conducted into how the mutant delta A could cause temperature-sensitive (Ts) cell growth by analysing its structural stability, cellular concentration and transcriptional activity. The mutant delta A was unstable even at the permissive temperature of 37 degrees C (t1/2 59 min), whereas the wild-type counterpart was fairly stable under the same conditions (t1/2 > 600 min). However, neither wild-type delta A nor mutant delta A was stable at 49 degrees C (t1/2 34 min and 23 min, respectively). Analyses of the rates of delta A synthesis revealed that B. subtilis DB1005 was able to compensate for unstable delta A by elevating the level of delta A at 37 degrees C but not at 49 degrees C. Moreover, overexpression of the mutant delta A at 49 degrees C could not suppress the Ts phenotype of B. subtilis DB1005. This indicates that the temperature sensitivity of B. subtilis DB1005 is not due to insufficient delta A concentration in the cell. The greater decline of an already reduced activity of the mutant delta A at 49 degrees C suggests that the temperature sensitivity of B. subtilis DB1005 is instead the result of a very low activity of delta A; probably below a critical level necessary for cell growth.

The sigma factors of Bacillus subtilis

The specificity of DNA-dependent RNA polymerase for target promotes is largely due to the replaceable sigma subunit that it carries. Multiple sigma proteins, each conferring a unique promoter preference on RNA polymerase, are likely to be present in all bacteria; however, their abundance and diversity have been best characterized in Bacillus subtilis, the bacterium in which multiple sigma factors were first discovered. The 10 sigma factors thus far identified in B. subtilis directly contribute to the bacterium's ability to control gene expression. These proteins are not merely necessary for the expression of those operons whose promoters they recognize; in many instances, their appearance within the cell is sufficient to activate these operons. This review describes the discovery of each of the known B. subtilis sigma factors, their characteristics, the regulons they direct, and the complex restrictions placed on their synthesis and activities. These controls include the anticipated transcriptional regulation that modulates the expression of the sigma factor structural genes but, in the case of several of the B. subtilis sigma factors, go beyond this, adding novel posttranslational restraints on sigma factor activity. Two of the sigma factors (sigma E and sigma K) are, for example, synthesized as inactive precursor proteins. Their activities are kept in check by "pro-protein" sequences which are cleaved from the precursor molecules in response to intercellular cues. Other sigma factors (sigma B, sigma F, and sigma G) are inhibited by "anti-sigma factor" proteins that sequester them into complexes which block their ability to form RNA polymerase holoenzymes. The anti-sigma factors are, in turn, opposed by additional proteins which participate in the sigma factors' release. The devices used to control sigma factor activity in B, subtilis may prove to be as widespread as multiple sigma factors themselves, providing ways of coupling sigma factor activation to environmental or physiological signals that cannot be readily joined to other regulatory mechanisms.

The response of a Bacillus subtilis temperature-sensitive sigA mutant to heat stress

The mutant sigA allele of Bacillus subtilis DB1005 was confirmed to be temperature sensitive (ts) and transferable among strains of B. subtilis by chromosomal transformation and gene conversion. This ts sigA allele had a pleiotropic effect on gene expression of DB1005. The induction of certain heat shock proteins in DB1005 was markedly less significant than that observed in the wild-type strain (DB2) under heat stress. In contrast, some proteins required for coping with oxidative stress and glucose starvation were induced abruptly in DB1005 but not in DB2. Heat induction of the groEL gene in vivo at both transcription and translation levels was much lower in DB1005 than in DB2. Besides, the putative sigma A-type promoter from the groESL operon of B. subtilis was able to be transcribed by the reconstituted sigma A RNA polymerase in vitro at both 37 and 49 degrees C. These results strongly suggest that the expression of the groEL gene of B. subtilis under heat stress is regulated at least in part by sigma A at the level of transcription. Our results also showed that DB1005 did not respond too differently from the wild type to ethanol stress, except after a relatively long exposure.

Overproduction, purification, and characterization of Bacillus subtilis RNA polymerase sigma A factor

By use of a T7 expression system, large amounts of active Bacillus subtilis RNA polymerase sigma A factor were produced in Escherichia coli cells. This overproduced protein was found in the form of inclusion bodies and constituted 40% of the total cellular protein. Because of the ease of isolation of the inclusion bodies and the acidic properties of sigma A, the protein was purified to more than 99% purity and the yield was about 90 mg/liter of culture. Gel mobility, antigenicity, specificity of promoter recognition, and N-terminal amino acid sequence of the overproduced sigma were found to be the same as those of native sigma A. Partial proteolysis analysis of sigma A protein suggested the presence of a protease-sensitive surface region in the C-terminal part of the sigma A protein. The promoter -10 binding region of sigma A was less sensitive to proteases and was probably involved in a hydrophobic, tightly folded domain of sigma A protein.

Bacillus subtilis subtilisin gene (aprE) is expressed from a sigma A (sigma 43) promoter in vitro and in vivo

In vitro studies demonstrated that the Bacillus subtilis subtilisin gene (aprE) could be transcribed by RNA polymerase holoenzyme reconstituted from core and sigma A factor obtained from vegetative cells. Upstream deletions (from -45) reduced the amount of transcription from the promoter. A deletion downstream of the promoter that overlapped a putative downstream minor promoter did not affect transcription from the sigma A promoter, which indicated that the putative downstream promoter is not utilized in vivo. S1 nuclease mapping studies showed that there was a low level of transcription from the subtilisin promoter during the growth phase and that the site of transcription initiation was the same during log and stationary phases. We conclude from these findings that there is only one promoter for the subtilisin gene and that it can be transcribed by the sigma A form of RNA polymerase in vitro.

Characteristics of an RNA polymerase population isolated from Bacillus subtilis late in sporulation

The sigma-factor composition of Bacillus subtilis RNA polymerase alters during endospore formation. The best-documented change is the appearance of a major sporulation-specific sigma factor (sigma epsilon), which is an RNA polymerase subunit readily detected at 2 to 4 h into the 8-h sporulation process. To determine the nature of the RNA polymerase in differentiating cells after the period of sigma epsilon abundance, we isolated RNA polymerase from cells that were harvested at 6 h after the onset of sporulation. Highly purified fractions of RNA polymerase from these cells contained at least six proteins which cosedimented with core RNA polymerase (beta beta' alpha 2) during glycerol gradient centrifugation. Most of these proteins were in the size range of 20,000 to 29,000 daltons, although one 90,000-dalton protein was also evident. None of the putative RNA polymerase subunits were present in quantities similar to that observed for sigma epsilon during its period of prominence in the cell but instead resembled the minor vegetative-cell sigma factors in abundance. In vitro transcriptions using cloned B. subtilis DNAs as templates revealed at least two novel transcriptional activities in the enzyme that was isolated from cells at 6 h after the onset of sporulation but absent in an RNA polymerase preparation extracted from cells at 4 h after the onset of sporulation. One of these activities was reconstituted by the addition of a 25,000 to 27,000-dalton protein fraction to core RNA polymerase.

The Bacillus subtilis spoIIG operon encodes both sigma E and a gene necessary for sigma E activation

A sporulation-specific sigma factor of Bacillus subtilis (sigma E) is formed by a proteolytic activation of a precursor protein (P31). Synthesis of the precursor protein is shown to be abolished in B. subtilis mutants with plasmid insertions as far as 940 base pairs upstream of the P31 structural gene (sigE), and processing of P31 to sigma E is blocked by a deletion in this upstream region. These results substantiate the view that sigE is the distal member of a 2-gene operon and demonstrate that the upstream gene (spoIIGA) is necessary for sigma E formation.

Sporulation-specific sigma factor sigma 29 of Bacillus subtilis is synthesized from a precursor protein, P31

Evidence is presented that a sporulation-essential sigma factor of Bacillus subtilis, sigma 29, is synthesized as an inactive precursor (P31) and that its activation occurs by a developmentally regulated cleavage of 29 amino acids from the P31 amino terminus. A pulse-chase experiment demonstrated that sigma 29 was derived from a preexisting protein, with appearance of radioactively labeled sigma 29 paralleling the disappearance of labeled P31. The disappearance of pulse-labeled P31 did not occur when the experiment was done with a B. subtilis strain carrying a mutation in a locus (spoIIE) required for sigma 29, but not P31, synthesis. Microsequencing of sigma 29 protein revealed that its amino terminus originates at amino acid 30 of the P31 amino acid sequence. In order to test whether a proteolytic event alone could activate P31 to a protein with sigma 29-like properties, a fusion protein (P31*) containing most of P31 was overproduced in Escherichia coli and converted in vitro into a protein with the electrophoretic mobility of sigma 29 by limited treatment with Staphylococcus aureus V8 protease. Protease-treated P31*, but not untreated P31*, was capable of directing B. subtilis core RNA polymerase to specifically initiate RNA synthesis at a sigma 29-recognized promoter in vitro.

Sigma 29-like protein is a common sporulation-specific element in bacteria of the genus Bacillus

A monoclonal antibody specific for an antigenic determinant on the Bacillus subtilis sporulation-induced sigma factor sigma 29 reacted with proteins similar in size to sigma 29 in extracts of sporulating Bacillus licheniformis, Bacillus amyloliquifaciens, Bacillus cereus, Bacillus natto, and Bacillus pumilus but not in extracts prepared from vegetatively growing cultures of these bacteria. These results indicate that RNA polymerase modifications, initially described for B. subtilis, are likely to be common among sporulating Bacillus spp. and that at least some of the specific modifications that are observed in sporulating B. subtilis are conserved among members of this genus.

Bacillus subtilis sigma factor sigma 29 is the product of the sporulation-essential gene spoIIG

Evidence is presented that the sporulation-essential locus spoIIG codes for both sigma 29 and a structurally related protein, P31. This demonstrates that at least one specific Bacillus subtilis RNA polymerase binding protein provides a critical function in endospore formation. spoIIG-specific RNA is present in B. subtilis cultures that are synthesizing P31 and sigma 29 and is absent in those that are not. A monoclonal antibody specific for an antigenic determinant on P31/sigma 29 detected crossreacting proteins (P25/P21) but not P31 or sigma 29 in a Spo- B. subtilis strain with a mutation at the spoIIG locus (spoIIG41). The appearance of P25 and P21 occurs in this mutant at a time when P31 and sigma 29 would normally appear and suggests that they are homologous proteins. Transformation of the spoIIG41 strain with plasmid DNA carrying the structural gene for spoIIG complements the Spo- phenotype and results in the synthesis of P31, sigma 29, P25, and P21 at the appropriate times during sporulation. In Escherichia coli, the cloned spoIIG sequence encoded a protein that reacted with the anti-P31/sigma 29 monoclonal antibody and had the electrophoretic mobility of authentic P31.

Synthesis of sigma 29, an RNA polymerase specificity determinant, is a developmentally regulated event in Bacillus subtilis

Using an immunological probe, we have determined that the synthesis of the Bacillus subtilis RNA polymerase promoter specificity determinant sigma 29 is a developmentally regulated event. sigma 29 is absent from vegetatively growing cells but is abundant in sporulating cells for a restricted (2-h) period during differentiation (hour 2 to hour 4 into the sporeforming process). The narrowness of this period suggests that sigma 29 is a regulatory factor that directs the transcription of a subpopulation of genes at a precise, intermediate stage of spore formation. This view predicts that sigma 29 should be dispensable for early sporulation events. We verified this prediction by an analysis of sigma 29 accumulation in mutants that are blocked at different stages of sporulation in which we show that cells can advance to at least an intermediate point in development (stage III) in the absence of detectable sigma 29. Lastly, our anti-sigma 29 antibody probe detected a second, previously unrecognized protein in Bacillus cell extracts that may be a precursor to sigma 29. This protein, P31 (molecular weight, 31,000) is synthesized earlier in sporulation than is sigma 29. It has a peptide profile that is similar to sigma 29 and is present in all Bacillus subtilis Spo- mutants that were tested and found to still be able to accumulate sigma 29.

A developmental gene product of Bacillus subtilis homologous to the sigma factor of Escherichia coli

Sporulation of Bacillus subtilis involves sequential morphological and biochemical changes and is regulated by specific genes (spo genes) estimated to occupy more than 30 loci. A mutation in any one of these genes blocks the sporulation process at the corresponding developmental stage. Despite intensive genetic studies, the nature and function of the spo gene products remain unknown. Vegetative B. subtilis RNA polymerase core enzyme may interact with several sigma factors and discriminate among different classes of promoters. During sporulation, new polypeptides are associated with the core enzyme which may have a central role in modifying its promoter recognition specificity. As a first step to understanding their function in the switch from vegetative to sporulation mode, several early sporulation genes have been cloned and analysed. Here we report the cloning and nucleotide sequence of the spoIIG gene of B. subtilis. This gene encodes a polypeptide with a predicted relative molecular mass of 27,652 which contains a 65-amino acid region highly homologous to an internal part of the Escherichia coli sigma factor.

A temporally regulated promoter from Bacillus subtilis is transcribed only by an RNA polymerase with a 37,000 dalton sigma factor

A 1,250 base pair Bacillus subtilis chromosomal HindIII restriction fragment (S fragment) has been cloned into the B. subtilis expression-probe plasmid pGR71. The S fragment induces the expression of the pGR71 chloramphenicol resistance gene shortly after the initiation of sporulation. The transcriptional promoter responsible for the expression of this temporally regulated genetic element has been identified and mapped in vitro. This promoter is recognized exclusively by the minor B. subtilis RNA polymerase that contains the 37,000 dalton sigma factor.

Coat protein synthesis during sporulation of Bacillus subtilis: immunological detection of soluble precursors to the 12,200-dalton spore coat protein

Antibody specific to the 12,200-dalton spore coat protein of Bacillus subtilis was used to detect the synthesis of cross-reacting material during sporulation. Cross-reacting protein was first detected by immunoprecipitation after 4 h of development and represented at least 1 to 2% of the total soluble protein synthesis at 5.5 h. A polypeptide of 21,000 daltons was detected in immunoprecipitates by gel electrophoresis. This polypeptide did not accumulate in sporulating cells and was rapidly turned over at the time of coat deposition. In contrast, a 32,000-dalton polypeptide reacted with antibody when unlabeled cell protein was denatured with sodium dodecyl sulfate, separated by gel electrophoresis, and transferred to nitrocellulose paper. This polypeptide was not detected during cell growth or the first 3.5 h of development but was found to accumulate in sporulating cells at 5.5 h. The lack of detection of this polypeptide by immunoprecipitation of undenatured protein indicates that the antigenic sites which cross-reacted with antibody to the 12,200-dalton protein sequence were not exposed unless the molecular conformation was altered. The 32,000-dalton protein may be a primary translation product which is proteolytically processed into mature spore coat protein via a 21,000-dalton intermediate.

Cloning and expression of the Bacillus thuringiensis crystal protein gene in Escherichia coli

Sau 3A1 partial digestion fragments from Bacillus thuringiensis var. kurstaki HD-1 plasmid DNA were ligated into the BamHI site of the cloning vector pBR322 and transformed into Escherichia coli strain HB101. Colonies presumed to contain recombinant plasmids were screened for production of an antigen that would react with antibody made against B. thuringiensis crystals. One strain, ES12, was isolated by using this procedure. ES12 contains a plasmid of Mr 11 X 10(6) that has DNA sequence homology with pBR322 as well as with Mr 30 X 10(6) and Mr 47 X 10(6) plasmids of B. thuringiensis. It makes a protein antigen, detected by antibodies to crystal, which has the same electrophoretic mobility as the B. thuringiensis crystal protein. Protein extracts of ES12 are toxic to larvae of the tobacco hornworm Manduca sexta.

Heterogeneity of RNA polymerase in Bacillus subtilis: evidence for an additional sigma factor in vegetative cells

Preparations of Bacillus subtilis RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) from vegetatively growing cells contain small amounts of an activity (B. subtilis RNA polymerase holoenzyme II) that shows a unique promoter specificity with T7 bacteriophage DNA as compared with the normal B. subtilis holoenzyme (holoenzyme I) and lacks the normal sigma subunit [Jaehning, J. A., Wiggs, J. L. & Chamberlin, M. J. (1979) Proc. Natl. Acad. Sci. USA 76, 5470-5474]. By heparin-agarose chromatography we have obtained holoenzyme II fractions that have no detectable holoenzyme I activity as judged by their failure to utilize promoter sites for holoenzyme I on any template we have tested. These fractions are far more active with B. subtilis DNA than with T7 DNA or other heterologous templates. This high degree of specificity has allowed identification of plasmids containing cloned fragments of B. subtilis DNA that bear strong promoter sites for holoenzyme II. These promoter sites are not used at all by B. subtilis RNA polymerase holoenzyme I. The specificity of holoenzyme II is dictated by a peptide of Mr 28,000 as judged by copurification of the peptide with specific holoenzyme II activity and by reconstitution of the holoenzyme II promoter specificity when the isolated peptide is added to B. subtilis core polymerase. Hence the 28,000 Mr peptide appears to be a sigma factor that determines a promoter specificity distinct from that of RNA polymerase holoenzyme I and all other known bacterial RNA polymerases.

Analysis of Bacillus subtilis sporulation with spore-converting bacteriophage PMB12

Previous observations concerning the ability of the spore-converting bacteriophage PMB12 to cause sporulation in certain sporulation-deficient mutants of Bacillus subtilis 168 were extended to include a spoOK mutant and a mutant temperature sensitive for sporulation due to a ribosomal mutation. Mutants of PMB12 that were unable to induce sporulation in the spoOK mutant were isolated to determine whether PMB12-encoded products had to affect the sporulation-specific functions of both the transcription and the translation systems of B. subtilis to induce sporulation. A complementation assay for spore conversion was used to assign the spore conversion-negative PMB12 mutants to four groups. One group of mutants repressed the ability of wild-type PMB12 to induce sporulation. None of the spore conversion-negative PMB12 mutants could induce significant levels of sporulation in B. subtilis mutants that were temperature sensitive for sporulation due to mutations in the beta subunit of ribonucleic acid polymerase or the 30S ribosomal subunit. Our data suggest that PMB12 may have at least three genes for spore conversion. The products of these genes apparently interact with a host cell pathway that is expressed during the earliest stage of sporulation and is not dependent for expression upon sporulation-specific functions of the host cell's transcription and translation systems.

Free sigma subunit of Bacillus subtilis RNA polymerase binds to DNA

The affinity of Bacillus subtilis RNA polymerase sigma and delta subunits to DNA was examined by a non-denaturing polyacrylamide slab gel electrophoresis method which made it possible to resolve DNA-bound and free subunits. The results revealed that sigma subunit, but not delta subunit had a relatively high affinity for double stranded DNA. The sigma subunit was bound maximally to super-coiled pGR1-3 plasmid DNA at a mass ratio of sigma/DNA of 0.7. With B. subtilis double stranded linear DNA one sigma subunit was bound per approximately 1,000 base pairs. The sigma-DNA complex was sufficiently stable for isolation by a molecular gel filtration column. The sigma subunit had much higher affinity for super-coiled than for linear pGR1-3 DNA or for linear double stranded or denatured DNA from B. subtilis, E. coli, and calf thymus. These results indicate that the free B. subtilis sigma subunit, in contrast to the E. coli sigma subunit, can bind by itself to DNA.

Template-independent poly(A) x poly(U) synthesizing activity of different forms of Bacillus subtilis RNA polymerase

Several, but not all, forms of bacillus subtilis RNA polymerase found in vegetative and sporulating cells can synthesize poly(A) x poly(U) in vitro. The vegetative delta-containing form of RNA polymerase (E delta) has little or no poly(A) x poly(U)-synthesizing activity, whereas RNA polymerase core (E) and sigma-containing core (E delta) both have significant activity. When purified vegetative delta factor was added to core, the core synthetic activity was reduced essentially to that of the vegetative enzyme E delta. When E sigma enzymes from vegetative and sporulating cells were compared for their salt sensitivity, it was found that the sporulation enzyme E sigma retained much more of its activity at 0.1 M KCl than the vegetative enzyme E sigma. Furthermore, when sporulation enzyme E delta 1 was compared with vegetative enzyme E sigma, it was found that the activity of the E sigma 1 form was much more resistant to high KCl concentrations than that of the vegetative E sigma form. These differences in enzyme activity, as affected by salt concentrations, suggest that the conformations of the sporulation E sigma and E delta 1 enzymes are different from that found in vegetative E sigma enzyme. These differences in conformation may be involved in selective gene expression during sporularion.

Clostridium perfringens type A: in vitro system for sporulation and enterotoxin synthesis

Polysomes were isolated from an enterotoxigenic strain of Clostridium perfringens during vegetative growth and at 1-h intervals after transfer into Duncan-Strong sporulation medium. During vegetative growth, about 67% of the ribosomes were in polysomal complexes. This proportion decreased to about 20% during the first 2 h in sporulation medium and then gradually increased to a maximum of 45% at 6 h. Ribosomes isolated from cells in vegetative or in sporulation phase could equally translate vegetative, sporulation, and natural viral R17 messenger ribonucleic acid with either vegetative or sporulation initiation factors. When polysomes were allowed to complete their nascent chains with labeled amino acids in vitro, most of the polypeptides synthesized by the vegetative phase and by the sporulation phase polysomes appeared to be identical. There were, however, notable differences upon further investigation. Specifically, when antiserum against the enterotoxin was reacted with the completed polypeptides, no counts were precipitated from the vegetative products. On the other hand, up to 12% of the total labeled protein was precipitated from the products obtained with the sporulation phase polysomes. Upon electrophoresis on sodium dodecyl sulfate, the putative enterotoxin synthesized in vitro ran as a major band with a molecular weight of 35,000, and as two minor bands with molecular weights of 17,000 and 52,000, respectively.

Transcription-termination factor Rho from Bacills subtilis

A protein has been isolated from Bacillus subtilis which has functions similar to that of transcription termination factor rho (rho) from Escherichia coli. The apparent molecular weight of the B. subtilis rho factor is about 80000-95000 as estimated by a non-denaturing polyacrylamide gel electrophoresis method. It contains two subunits with a molecular weight of 47000 as determined by sodium dodecylsulfate/polyacrylamide gel electrophoresis. The rho factor shows poly(C)-dependent beta-gamma ATPase activity and depresses the activity of RNA synthesis from B. subtilis phage rho 29 DNA template with purified B. subtilis RNA polymerase holoenzyme. The specific activity of the poly(C)-dependent ATPase of the B. subtilis rho factor was significantly less than that of the E. coli rho factor. In the presence of rho factor fewer RNA transcripts were produced overall from the rho 29 template and smaller RNA transcripts with discrete sizes were made. These results suggest that the B. subtilis rho factor can catalyze transcription termination at specific sites on rho 29 phage DNA in vitro.

Sigma factor is not released during transcription in Bacillus subtilis

The relationship between sigma (sigma) and delta (delta) factors of Bacillus subtilis RNA polymerase has been analyzed during initiation of RNA synthesis. When core enzyme (E) containing delta factor (E delta) binds to DNA, the delta factor is released with the formation of an E-DNA complex. The addition of sigma to the E-DNA complex results in the formation of a stable E sigma-DNA complex which can synthesize RNA upon addition of nucleoside triphosphates. Sigma factor, significantly, is not released from the core during RNA synthesis. These results suggest that delta and sigma factors can act sequentially during initiation of RNA synthesis with delta acting as a DNA recognition factor and sigma acting as an initiation factor. The results do not preclude the possibility that E sigma can initiate RNA synthesis correctly since E sigma alone can bind to DNA and initiate RNA synthesis.

Morphology and patterns of protein synthesis during sporulation of Bacillus subtilis Eryr spo(Ts) mutants

Erythromycin-resistant (Eryr) mutants of Bacillus subtilis 168 fail to sporulate at high temperature (47 degrees C) but sporulate normally at 30 to 35 degrees C. They also fail to sporulate at any temperature in the presence of 2.5 micrograms of erythromycin per ml. Neither of these nonpermissive conditions appears to affect vegetative growth, and the periods of sensitivity to both conditions extend from 40 to 90% of the sporulation period. At 47 degrees C, net incorporation of methionine and phenylalanine in postexponential Eryr and 168 cells was similar, and fractionation of the labeled products by polyacrylamide gel electrophoresis gave patterns in which many of the bands produced by mutant and parental cells coincided. However, distinct differences were seen, and since no spore-specific morphogenesis occurred in the Eryr cells at 47 degrees C, a selective defect in spore gene expression was inferred. At 35 degrees C plus erythromycin, spore morphogenesis proceeded normally until forespores were produced and then ceased, coincident with a marked increase in sensitivity of total protein synthesis to erythromycin. The effects seem to be nonspecific, therefore, and may indicate a change in cell permeability or ribosomal sensitivity to erythromycin.

Asymmetric transcription during post-germinative development of Bacillus subtilis spores. II. Hybrid competition analyses

Hybrid-competition analyses were done to estimate the relatedness of 3H-labeled mRNA species synthesized during spore germination and log-phase growth. The competitions showed that early in the germination process 10--15 and 1--3% of the RNA transcribed from the H and from the L strand, respectively, were unique and absent during log-phase growth. At later stages, the amounts of the germination-specific H transcripts decreased more rapidly than the L transcripts. The competitions with pulse-labeled log-phase RNAs showed that vegetative genes were transcribed more rapidly from the H strand than from the L strand. Most of the results could be correlated with the observed decrease in the H/L asymmetry ration during spore germination.

Spore coat protein synthesis in cell-free systems from sporulating cells of Bacillus subtilis

Cell-free systems for protein synthesis were prepared from Bacillus subtilis 168 cells at several stages of sporulation. Immunological methods were used to determine whether spore coat protein could be synthesized in the cell-free systems prepared from sporulating cells. Spore coat protein synthesis first occurred in extracts from stage t2 cells. The proportion of spore coat protein to total proteins synthesized in the cell-free systems was 2.4 and 3.9% at stages t2 and t4, respectively. The sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis patterns of immunoprecipitates from the cell-free systems showed the complete synthesis of an apparent spore coat protein precursor (molecular weight, 25,000). A polypeptide of this weight was previously identified in studies in vivo (L.E. Munoz, Y. Sadaie, and R.H. Doi, J. Biol. Chem., in press). The synthesis in vitro of polysome-associated nascent spore coat polypeptides with varying molecular weights up to 23,000 was also detected. These results indicate that the spore coat protein may be synthesized as a precursor protein. The removal of proteases in the crude extracts by treatment with hemoglobin-Sepharose affinity techniques may be preventing the conversion of the large 25,000-dalton precursor to the 12,500-dalton mature spore coat protein.

Delta factor can displace sigma factor from Bacillus subtilis RNA polymerase holoenzyme and regulate its initiation activity

A protein with a molecular weight of 21,000 daltons is found associated with a fraction of Bacillus subtilis RNA polymerase core. This protein (delta) does not react with antibody made against sigma factor and has a peptide map which is significantly different from sigma factor. At ratios of 2:1 to 4:1 (delta:holoenzyme) the delta displaces sigma factor completely from the core and associates in a 1:1 ratio with core to form delta-core. Under the same incubation conditions sigma factor at a ratio of 10:1 (sigma factor:delta-core) does not displace delta from the delta-core. The delta-core has much less activity as compared to holoenzyme on various DNA templates. However, sigma factor does stimulate the activity of delta-core enzyme under conditions of RNA synthesis. These observations and the results of others suggest that delta-core enzyme binds initially to specific DNA sites followed by delta release from the core-DNA complex and that the sigma factor binds to the core-DNA complex to initiate RNA synthesis. Thus both delta and sigma factors are required in a sequential fashion for specific transcription to occur in B subtilis.