Regulation of expression of genes coding for small, acid-soluble proteins of Bacillus subtilis spores: studies using lacZ gene fusions

Complete spore-cortex hydrolysis during germination of Bacillus subtilis 168 requires SleB and YpeB

The role of the sleB gene of Bacillus subtilis, which encodes a putative spore-cortex-lytic enzyme, and the downstream ypeB gene were investigated. Both SleB and YpeB were required for normal germination to occur. The corresponding mutants formed phase-bright, heat-resistant spores with no apparent defects in dormancy. However, mutant spore suspensions lost optical density slower than the wild-type and spores were phase-grey even 12 h after the triggering of germination. Since the loss of heat resistance and release of dipicolinic acid was similar to the wild-type, these mutants were blocked in the later stages of germination. The mutants were nevertheless capable of outgrowth on rich agar to form colonies, indicating that other spore components can compensate for their function sufficiently to allow outgrowth. The expression and regulation of the operon was examined using a lacZ transcriptional fusion. Expression of the operon began 2 h after the onset of sporulation and was under the control of RNA polymerase containing the forespore-specific sigma factor, sigmaG. The application of reverse phase HPLC revealed that the mutants do not have any structural defect in the dormant spore cortex and therefore these genes are not required for normal spore-cortex synthesis. The analysis of peptidoglycan dynamics during germination showed, however, that the cortex was only partially hydrolysed in both mutants. This analysis also revealed that the likely hydrolytic bond specificity of SleB is likely to be that of a lytic transglycosylase.

The TRAP-like SplA protein is a trans-acting negative regulator of spore photoproduct lyase synthesis during Bacillus subtilis sporulation

UV resistance of bacterial endospores derives from a unique DNA photochemistry in which the major UV photoproduct is the thymine dimer 5-thyminyl-5,6-dihydrothymine (spore photoproduct [SP]) instead of cyclobutane pyrimidine dimers. Repair of SP during spore germination is due in large part to the activity of the enzyme SP lyase encoded by splB, the second cistron of the splAB operon. Expression of the splAB operon in Bacillus subtilis is transcriptionally activated by the Esigma(G) form of RNA polymerase during morphological stage III in the developing forespore compartment, and SP lyase is packaged into the dormant spore. In addition to temporal and compartmental control of splAB expression, a second regulatory circuit which modulates the level of expression of splB-lacZ fusions without altering their developmental timing or compartmentalization is reported here. This second regulatory circuit involves the negative action of the splA gene product, a 79-amino-acid protein with approximately 50% similarity and 17% identity to TRAP, the tryptophan RNA-binding attenuation protein from B. subtilis and Bacillus pumilus.

sigmaK can negatively regulate sigE expression by two different mechanisms during sporulation of Bacillus subtilis

Temporal and spatial gene regulation during Bacillus subtilis sporulation involves the activation and inactivation of multiple sigma subunits of RNA polymerase in a cascade. In the mother cell compartment of sporulating cells, expression of the sigE gene, encoding the earlier-acting sigma factor, sigmaE, is negatively regulated by the later-acting sigma factor, sigmaK. Here, it is shown that the negative feedback loop does not require SinR, an inhibitor of sigE transcription. Production of sigmaK about 1 h earlier than normal does affect Spo0A, which when phosphorylated is an activator of sigE transcription. A mutation in the spo0A gene, which bypasses the phosphorelay leading to the phosphorylation of Spo0A, diminished the negative effect of early sigmaK production on sigE expression early in sporulation. Also, early production of sigmaK reduced expression of other Spo0A-dependent genes but not expression of the Spo0A-independent ald gene. In contrast, both sigE and ald were overexpressed late in development of cells that fail to make sigmaK. The ald promoter, like the sigE promoter, is believed to be recognized by sigmaA RNA polymerase, suggesting that sigmaK may inhibit sigmaA activity late in sporulation. To exert this negative effect, sigmaK must be transcriptionally active. A mutant form of sigmaK that associates with core RNA polymerase, but does not direct transcription of a sigmaK-dependent gene, failed to negatively regulate expression of sigE or ald late in development. On the other hand, the negative effect of early sigmaK production on sigE expression early in sporulation did not require transcriptional activity of sigmaK RNA polymerase. These results demonstrate that sigmaK can negatively regulate sigE expression by two different mechanisms, one observed when sigmaK is produced earlier than normal, which does not require sigmaK to be transcriptionally active and affects Spo0A, and the other observed when sigmaK is produced at the normal time, which requires sigmaK RNA polymerase transcriptional activity. The latter mechanism facilitates the switch from sigmaE to sigmaK in the cascade controlling mother cell gene expression.

New small, acid-soluble proteins unique to spores of Bacillus subtilis: identification of the coding genes and regulation and function of two of these genes

Eleven small, acid-soluble proteins (SASP) which are present in spores but not in growing cells of Bacillus subtilis were identified by sequence analysis of proteins separated by acrylamide gel electrophoresis of acid extracts from spores which lack the three major SASP (alpha, beta, and gamma). Six of these proteins are encoded by open reading frames identified previously or by analysis of the complete sequence of the B. subtilis genome, including two minor alpha/beta-type SASP (SspC and SspD) and a putative spore coat protein (CotK). Five proteins are encoded by short open reading frames that were not identified as coding regions in the analysis of the complete B. subtilis genomic sequence. Studies of the regulation of two of the latter genes, termed sspG and sspJ, showed that both are expressed only in sporulation. The sspG gene is transcribed in the mother cell compartment by RNA polymerase with the mother cell-specific sigma factor for RNA polymerase, sigmaK, and is cotranscribed with a downstream gene, yurS; sspG transcription also requires the DNA binding protein GerE. In contrast, sspJ is transcribed in the forespore compartment by RNA polymerase with the forespore-specific sigmaG and appears to give a monocistronic transcript. A mutation eliminating SspG had no effect on sporulation or spore properties, while loss of SspJ caused a slight decrease in the rate of spore outgrowth in an otherwise wild-type background.

Identification of protein-protein contacts between alpha/beta-type small, acid-soluble spore proteins of Bacillus species bound to DNA

Small, acid-soluble spore proteins (SASP) of the alpha/beta-type from several Bacillus species were cross-linked into homodimers, heterodimers and homooligomers with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) in the presence of linear plasmid DNA. Significant protein cross-linking was not detected in the absence of DNA. In all four alpha/beta-type SASP examined, the amino donor in the EDC induced amide cross-links was the alpha-amino group of the protein. However, the carboxylate containing amino acid residues involved in cross-linking varied. In SASP-A and SASP-C of Bacillus megaterium two conserved glutamate residues, which form part of the germination protease recognition sequence, were involved in cross-link formation. In SspC from Bacillus subtilis and Bce1 from Bacillus cereus the acidic residues involved in cross-link formation were not in the protease recognition sequence, but at a site closer to the N terminus of the proteins. These data indicate that, although there are likely to be subtle structural differences between different alpha/beta-type SASP, the N-terminal regions of these proteins are involved in protein-protein interactions while in the DNA bound state.

Characterization of yhcN, a new forespore-specific gene of Bacillus subtilis

A new Bacillus subtilis sporulation-specific gene, yhcN, has been identified, the expression of which is dependent on the forespore-specific sigma factor sigmaG and to a much lesser extent on sigmaF. A translational yhcN-lacZ fusion is expressed at a very high level in the forespore, and the protein encoded by yhcN was detected in the inner spore membrane. A yhcN mutant sporulates normally and yhcN spores have identical resistance properties to wild-type spores. However, the outgrowth of yhcN spores is slower than that of wild-type spores.

A null mutation in the Bacillus subtilis aconitase gene causes a block in Spo0A-phosphate-dependent gene expression

The citB gene of Bacillus subtilis encodes aconitase, the enzyme of the Krebs citric acid cycle, which is responsible for the interconversion of citrate and isocitrate. A B. subtilis strain with an insertion mutation in the citB gene was devoid of aconitase activity and aconitase protein, required glutamate for growth in minimal medium, and was unable to sporulate efficiently in nutrient broth sporulation medium. Mutant cells failed to form the asymmetric septum characteristic of sporulating cells and were defective in transcription of the earliest-expressed spo genes, that is, the genes dependent on the Spo0A phosphorelay. However, this early block in sporulation was partially overcome when cells of the citB mutant were induced to sporulate by resuspension in a poor medium. Accumulation of citrate in the mutant cells or in their culture fluid may be responsible for the early block, possibly because citrate can chelate divalent cations needed for the activity of the phosphorelay.

A compartmentalized regulator of developmental gene expression in Bacillus subtilis

We have identified a new Bacillus subtilis gene, spoVT, whose gene product is homologous to the transcriptional regulator AbrB and serves as a regulator of E sigmaG-controlled gene expression. SpoVT acts both positively and negatively in controlling sigmaG-dependent gene expression, providing an additional level of refinement to forespore gene regulation and feedback control of spoIIIG expression.

The Bacillus subtilis soj-spo0J locus is required for a centromere-like function involved in prespore chromosome partitioning

During sporulation in Bacillus subtilis a small prespore cell is formed by an asymmetric cell division. Pre-spore chromosome partitioning occurs by a specialised mechanism in which septation precedes chromosome movement. We show that the spo0J gene is needed to specify the orientation of the chromosome at the time of polar division and to impose directionality on the subsequent transport of the remainder of the chromosome through the septum. Both phenotypes may arise by disruption of a centromere-like apparatus that anchors the or/C region of the prespore chromosome in the pole of the cell.

Analysis of the relationship between the decrease in pH and accumulation of 3-phosphoglyceric acid in developing forespores of Bacillus species

Analysis of the pH decrease and 3-phosphoglyceric acid (3PGA) accumulation in the forespore compartment of sporulating cells of Bacillus subtilis showed that the pH decrease of 1 to 1.2 units at approximately 4 h of sporulation preceded 3PGA accumulation, as observed previously in B. megaterium. These data, as well as analysis of the forespore pH decrease in asporogenous mutants of B. subtilis, indicated that sigma G-dependent forespore transcription, but not sigma K-dependent mother cell transcription, is required for the forespore pH decrease. Further analysis of these asporogenous mutants showed an excellent correlation between the forespore pH decrease and the forespore's accumulation of 3PGA. These latter results are consistent with our previous suggestion that the decrease in forespore pH results in greatly decreased activity of phosphoglycerate mutase in the forespore, which in turn leads to 3PGA accumulation. In further support of this suggestion, we found that (i) elevating the pH of developing forespores of B. megaterium resulted in rapid utilization of the forespore's 3PGA depot and (ii) increasing forespore levels of PGM approximately 10-fold in B. subtilis resulted in a large decrease in the spore's depot of 3PGA. The B. subtilis strain with a high phosphoglycerate mutase level sporulated, and the spores germinated and went through outgrowth normally, indicating that forespore accumulation of a large 3PGA depot is not essential for these processes.

Altering the level and regulation of the major sigma subunit of RNA polymerase affects gene expression and development in Bacillus subtilis

In Bacillus subtilis, the major sigma factor, sigma-A (rpoD), and the minor sigma factor, sigma-H (spo0H), are present during growth and are required for the initiation of sporulation. Our experiments indicate that sigma-A and sigma-H compete for binding to core RNA polymerase. We used a fusion of rpoD to the LacI-repressible IPTG-inducible promoter, Pspac, to vary the levels of sigma-A in the cell. Increasing the amount of sigma-A caused a decrease in expression of genes controlled by sigma-H, and a delay in the production of heat-resistant spores. Decreasing the amount of sigma-A, in a strain deleted for the chromosomal rpoD, caused an increase in expression of genes controlled by sigma-H. As rpoD itself is controlled by at least two promoters recognized by RNA polymerase that contains sigma-H, the effect of sigma-A levels on expression of sigma-H-controlled promoters represents a feedback mechanism that might contribute to maintaining appropriate levels of sigma-A. While the level of sigma-A was important for efficient sporulation, our results indicate that the normal transcriptional control of rpoD, in the context of the rpoD operon and the numerous promoters in that operon, is not required for efficient sporulation or germination, provided that the sigma-A level from a heterologous promoter is comparable to that in wild-type cells.

A Bacillus subtilis malate dehydrogenase gene

A Bacillus subtilis gene for malate dehydrogenase (citH) was found downstream of genes for citrate synthase and isocitrate dehydrogenase. Disruption of citH caused partial auxotrophy for aspartate and a requirement for aspartate during sporulation. In the absence of aspartate, citH mutant cells were blocked at a late stage of spore formation.

ssp genes and spore osmotolerance in Bacillus thuringiensis israelensis and Bacillus sphaericus

It was shown previously that spores and vegetative cells of Bacillus sphaericus (Bf) and Bacillus thuringiensis israelensis (Bti) are very sensitive to osmotic variations. Since spore osmotolerance has been associated with their SASP (small acid soluble spore proteins) content coded by ssp genes, hybridization assays were performed with sspE and sspA genes from B. subtilis as probes and showed that Bti and Bf strains could lack an sspE-like gene. The B. subtilis sspE gene was then introduced into Bti 4Q2 strain; spores were obtained and showed a 65 to 650 times higher level of osmotolerance to NaCl, without affecting other important properties: hypoosmotic resistance in vegetative cells, spore UV resistance, and larvicidal activity against diptera larvae.

Construction of gusA transcriptional fusion vectors for Bacillus subtilis and their utilization for studies of spore formation

A series of gusA transcriptional fusion vectors is described for Bacillus subtilis (Bs). The series includes a vector for use with the amyE system of Shimotsu and Henner [Gene 43 (1986) 85-94], an integrative vector and vectors that provide gusA or gusA neo cassettes. The gusA fusions are compatible with lacZ fusion vectors that are widely used with Bs, and gusA and lacZ fusions are expressed at similar levels. beta-Glucuronidase (beta Glu) and beta-galactosidase (beta Gal) do not exhibit any cross-reactivity, there is very little endogenous beta Glu activity in Bs, and there is no indication of mutation to high-level expression. We have use strains containing both gusA and lacZ fusions to compare the times of expression of different genes during sporulation.

Use of immunofluorescence to visualize cell-specific gene expression during sporulation in Bacillus subtilis

We have adapted immunofluorescence microscopy for use in Bacillus subtilis and have employed this procedure for visualizing cell-specific gene expression at early to intermediate stages of sporulation. Sporangia were doubly stained with propidium iodide to visualize the forespore and mother cell nucleoids and with fluorescein-conjugated antibodies to visualize the location of beta-galactosidase produced under the control of the sporulation RNA polymerase sigma factors sigma E and sigma F. In confirmation and extension of earlier reports, we found that expression of a lacZ fusion under the control of sigma E was confined to the mother cell compartment of sporangia at the septation (II) and engulfment (III) stages of morphogenesis. Conversely, sigma F-directed gene expression was confined to the forespore compartment of sporangia at postseptation stages of development. Little indication was found for sigma E- or sigma F-directed gene expression prior to septation or in both compartments of postseptation sporangia. Gene expression under the control of the forespore sigma factor sigma G also exhibited a high level of compartmentalization. A high proportion of sporangia exhibited fluorescence in our immunostaining protocol, which should be suitable for the subcellular localization of sporulation proteins for which specific antibodies are available.

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.

Bacillus subtilis lon protease prevents inappropriate transcription of genes under the control of the sporulation transcription factor sigma G

The Bacillus subtilis RNA polymerase sigma factor sigma G is a cell-type-specific regulatory protein that governs the transcription of genes that are expressed at an intermediate to late stage of sporulation in the forespore compartment of the sporangium. Here we report the identification of a mutation (lon-1) that causes inappropriate transcription of genes under the control of sigma G under nutritional and genetic conditions in which sporulation is prevented. The mutation is located at 245 degrees on the genetic map and lies within a newly identified open reading frame that is predicted to encode a homolog to Lon protease. Inappropriate transcription of sigma G-controlled genes in the lon-1 mutant is not prevented by mutations in genes that are normally required for the appearance of sigma G during sporulation but is prevented by a mutation in the structural gene (spoIIIG) for sigma G itself. In light of previous work showing that spoIIIG is subject to positive autoregulation, we propose that Lon protease is responsible (possibly by causing degradation of sigma G) for preventing sigma G-directed transcription of spoIIIG and hence the accumulation of sigma G in cells that are not undergoing sporulation. An integrated physical and genetic map is presented that encompasses 36 kb of uninterrupted DNA sequence from the lon pheA region of the chromosome, corresponding to 245 degrees to 239 degrees on the genetic map.

Identification of two distinct Bacillus subtilis citrate synthase genes

Two distinct Bacillus subtilis genes (citA and citZ) were found to encode citrate synthase isozymes that catalyze the first step of the Krebs cycle. The citA gene was cloned by genetic complementation of an Escherichia coli citrate synthase mutant strain (W620) and was in a monocistronic transcriptional unit. A divergently transcribed gene, citR, could encode a protein with strong similarity to the bacterial LysR family of regulatory proteins. A null mutation in citA had little effect on citrate synthase enzyme activity or sporulation. The residual citrate synthase activity was purified from a citA null mutant strain, and the partial amino acid sequence for the purified protein (CitZ) was determined. The citZ gene was cloned from B. subtilis chromosomal DNA by using a PCR-generated probe synthesized with oligonucleotide primers derived from the partial amino acid sequence of purified CitZ. The citZ gene proved to be the first gene in a tricistronic cluster that also included citC (coding for isocitrate dehydrogenase) and citH (coding for malate dehydrogenase). A mutation in citZ caused a substantial loss of citrate synthase enzyme activity, glutamate auxotrophy, and a defect in sporulation.

Temporal regulation and forespore-specific expression of the spore photoproduct lyase gene by sigma-G RNA polymerase during Bacillus subtilis sporulation

Bacterial spores are highly resistant to killing by UV radiation and exhibit unique DNA photochemistry. UV irradiation of spore DNA results in formation of spore photoproduct (SP), the thymine dimer 5-thyminyl-5,6-dihydrothymine. Repair of SP occurs during germination of Bacillus subtilis spores by two distinct routes, either by the general nucleotide excision repair (uvr) pathway or by a novel SP-specific monomerization reaction mediated by the enzyme SP lyase, which is encoded by the spl gene. Repair of SP occurs early in spore germination and is independent of de novo protein synthesis, suggesting that the SP repair enzymes are synthesized during sporulation and are packaged in the dormant spore. To test this hypothesis, the expression of a translational spl-lacZ fusion integrated at the spl locus was monitored during B. subtilis growth and sporulation. beta-Galactosidase expression from the spl-lacZ fusion was silent during vegetative growth and was not DNA damage inducible, but it was activated at morphological stage III of sporulation specifically in the forespore compartment, coincident with activation of expression of the stage III marker enzyme glucose dehydrogenase. Expression of the spl-lacZ fusion was shown to be dependent upon the sporulation-specific RNA polymerase containing the sigma-G factor (E sigma G), as spl-lacZ expression was abolished in a mutant harboring a deletion in the sigG gene and restored by expression of the sigG gene in trans. Primer extension analysis of spl mRNA revealed a major extension product initiating upstream from a small open reading frame of unknown function which precedes spl, and it revealed two other shorter minor extension products. All three extension products were present in higher quantities during sporulation and after sigG induction. The three putative transcripts are all preceded by sequences which share homology with the consensus sigma-G factor-type promoter sequence, but in vitro transcription by purified sigma-G RNA polymerase was detected only from the promoter corresponding to the major extension product. The open reading frame-spl operon therefore appears to be an additional member of the sigma-G regulon, which also includes as members the small, acid-soluble spore proteins which are in large part responsible for spore DNA photochemistry. Therefore, sporulating bacteria appear to coordinately regulate genes whose products not only alter spore DNA photochemistry but also repair the major spore-specific photoproduct during germination

Overproducing the Bacillus subtilis mother cell sigma factor precursor, Pro-sigma K, uncouples sigma K-dependent gene expression from dependence on intercompartmental communication

During sporulation of Bacillus subtilis, proteolytic activation of pro-sigma K and ensuing sigma K-dependent gene expression normally require the activity of many sporulation gene products. We report here that overproducing pro-sigma K at the onset of sporulation substantially uncouples sigma K-dependent gene expression from its normal dependency. Overproducing pro-sigma K in strains with a mutation in spoIIIG, spoIIIA, spoIIIE, or spoIVB partially restored sigma K-dependent gene expression in the mother cell and resulted in accumulation of a small amount of polypeptide that comigrated with sigma K, but these mutants still failed to form spores. In contrast, sporulation of spoIVF mutants was greatly enhanced by pro-sigma K overproduction. The products of the spoIVF operon are made in the mother cell and normally govern pro-sigma K processing, but overproduction of pro-sigma K appears to allow accumulation of a small amount of sigma K, which is sufficient to partially restore mother cell gene expression and spore formation. This spoIVF-independent mechanism for processing pro-sigma K depends on sigma E, an earlier-acting mother cell-specific sigma factor. The spoIIID gene, which encodes a mother cell-specific DNA-binding protein that is normally required for pro-sigma K production, was shown to be required for efficient pro-sigma K processing as well. bof (bypass of forespore) mutations bypassed this requirement for spoIIID, suggesting that SpoIIID is less directly involved in pro-sigma K processing than are spoIVF gene products. However, bof spoIIID double mutants overproducing pro-sigma K still failed to sporulate, indicating that SpoIIID serves another essential role(s) in sporulation in addition to its multiple roles in the production of sigma K.

Analysis by fluorescence microscopy of the development of compartment-specific gene expression during sporulation of Bacillus subtilis

The use of a fluorogenic substrate, 5-octanoylaminofluorescein-di-beta-D-galactopyranoside, for beta-galactosidase has made it possible to visualize enzyme activity in individual cells of sporulating populations of Bacillus subtilis by fluorescence microscopy. lacZ fusions to different sporulation-associated genes have been used to investigate the cell compartmentalization of gene expression during sporulation. A strain with a lacZ fusion to sspA, a gene which is transcribed by E-sigma G at a late stage of sporulation, displayed predominantly compartment-specific fluorescence. Expression of the early-expressed spoIIA locus, which includes the structural gene for sigma F, was seen not to be compartmentalized. Populations of strains with lacZ fusions to gpr and dacF, genes which are transcribed by E-sigma F at intermediate stages of sporulation, included some organisms showing uncompartmentalized fluorescence and others showing compartment-specific fluorescence; the proportion showing compartment-specific fluorescence increased in samples taken later in sporulation. Several possible explanations of the results obtained with gpr and dacF are considered. A plausible interpretation is that sigma F activity is initially not compartmentalized and becomes compartmentalized as sporulation progresses. The progression to compartmentalization does not require the activities of the sporulation-specific factor sigma E or sigma G but may require some product of sigma F activity.

Sigma factors, asymmetry, and the determination of cell fate in Bacillus subtilis

Soon after the initiation of sporulation, Bacillus subtilis divides asymmetrically to produce sister cells that have very different developmental fates. Recently, it has been proposed that the differential gene expression which begins soon after this division is due to cell-specific activation of the transcription factors sigma F and sigma E in the prespore and the mother cell, respectively. We describe the use of a method for the localization of gene expression in individual sporulating cells that lends strong support to the cell-specific localization of sigma F and sigma E activities. The dependence of sigma E activity on integrity of the gene encoding sigma F has led to the suggestion that activation of sigma F in the prespore leads to a directional signal that triggers activation of sigma E only in the mother cell. Here we show that sigma E actually specifies the fate of the mother cell; in the absence of sigma E, two prespore-like cells are made. The appearance of sigma F activity at both poles of a sigma E-deficient mutant supports the idea that sigma F normally remains latent in the mother cell and that its activation depends on some morphological or physiological feature of the prespore. We present a model for the generation of asymmetry and the establishment of cell fate in B. subtilis.

Binding of small, acid-soluble spore proteins to DNA plays a significant role in the resistance of Bacillus subtilis spores to hydrogen peroxide

Dormant spores of Bacillus subtilis which lack the majority of the alpha/beta-type small, acid-soluble proteins (SASP) (termed alpha- beta- spores) that coat the DNA in wild-type spores are significantly more sensitive to hydrogen peroxide than are wild-type spores. Hydrogen peroxide treatment of alpha- beta- spores causes DNA strand breaks more readily than does comparable treatment of wild-type spores, and alpha- beta- spores, but not wild-type spores, which survive hydrogen peroxide treatment have acquired a significant number of mutations. The hydrogen peroxide resistance of wild-type spores appears to be acquired in at least two incremental steps during sporulation. The first increment is acquired at about the time of alpha/beta-type SASP synthesis, and the second increment is acquired approximately 2 h later, at about the time of dipicolinic acid accumulation. During sporulation of the alpha- beta- strain, only the second increment of hydrogen peroxide resistance is acquired. In contrast, sporulation mutants which accumulate alpha/beta-type SASP but progress no further in sporulation acquire only the first increment of hydrogen peroxide resistance. These findings strongly suggest that binding of alpha/beta-type SASP to DNA provides one increment of spore hydrogen peroxide resistance. Indeed, binding of alpha/beta-type SASP to DNA in vitro provides strong protection against cleavage of DNA by hydrogen peroxide.

Transcription factor sigma B of Bacillus subtilis controls a large stationary-phase regulon

Transcription factor sigma B of Bacillus subtilis is active during the stationary growth phase, but its physiological role remains unknown. Understanding the function and regulation of genes controlled by sigma B (csb genes) should provide important clues to sigma B function in stationary-phase cells. To this end, we used a genetic approach to identify six new csb genes. This strategy relies on two elements: (i) random transcriptional fusions between the Escherichia coli lacZ gene and genes on the B. subtilis chromosome, generated in vivo with transposon Tn917lacZ, and (ii) a plate transformation technique to introduce a null sigB mutation into the fusion-bearing recipients directly on indicator plates. This strategy allowed the comparison of fusion expression in strains that were isogenic save for the presence or absence of a functional sigma B protein. Beginning with 1,400 active fusions, we identified 11 that were wholly or partly controlled by sigma B. These fusions mapped to six different loci that exhibit substantial contrasts in their patterns of expression in the logarithmic and stationary growth phases, suggesting that they participate in diverse cellular functions. However, for all six loci, the sigma B-dependent component of their expression was manifest largely in the stationary phase. The high frequency of six independent csb loci detected in a random collection of 1,400 fusions screened, the fact that four of the six new loci were defined by a single fusion, and the absence of the previously identified ctc and csbA genes in the present collection strongly suggest that sigma B controls a large stationary-phase regulon.

Evidence that the spoIIM gene of Bacillus subtilis is transcribed by RNA polymerase associated with sigma E

We have investigated the temporal and spatial regulation of spoIIM, a gene of Bacillus subtilis whose product is required for complete septum migration and engulfment of the forespore compartment during sporulation. The spoIIM promoter was found to become active about 2 h after the initiation of sporulation. The effects of mutations on the expression of a spoIIM-lacZ fusion were most consistent with its utilization by sigma-E-associated RNA polymerase (E sigma E). A unique 5' end of the in vivo spoIIM transcript was detected by primer extension analysis and was determined to initiate at the appropriate distance from a sequence conforming very closely to the consensus for genes transcribed by E sigma E. A partially purified preparation of E sigma E produced a transcript in vitro that initiated at the same nucleotide as the primer extension product generated from in vivo RNA. Ectopic induction of sigma E synthesis during growth resulted in the immediate and strong expression of a spoIIM-lacZ fusion, but an identical fusion was completely unresponsive to induced synthesis of either sigma F or sigma G under similar conditions. The results of plasmid integration-excision experiments in which the spoIIM gene was reversibly disrupted by a temperature-sensitive integrational vector suggested that spoIIM expression is required in the forespore compartment, but direct examination of subcellular fractions enriched for mother cell or forespore material indicated that spoIIM expression cannot be confined to the forespore. We conclude that spoIIM is a member of the sigma E regulon and that it may be transcribed exclusively by E sigma E. We discuss the implications of this conclusion for models in which activation of sigma E in the mother cell is proposed to be a part of the mechanism responsible for initiating separate programs of gene activity in the two sporangium compartments.

Physical and functional characterization of the Bacillus subtilis spoIIM gene

The spoIIM locus of Bacillus subtilis is the most recently discovered of six genetic loci in which mutations can prevent the synthesis of a normal asymmetric septum or prevent migration of the septal structure to engulf the forespore compartment of the sporangium. Ultrastructure studies of a spoIIM mutant confirmed a block prior to the completion of engulfment. Introduction of a spoIIM mutation into a panel of strains containing lacZ fusions belonging to different regulatory classes allowed us to determine that the spoIIM gene product is required for the efficient expression of genes transcribed by sigma G-associated RNA polymerase but is not required for the expression of sigma F-controlled genes, including spoIIIG, which encodes sigma G. The results of complementation studies, gene disruption analysis, and DNA sequencing revealed that the spoIIM locus contains a single sporulation-essential gene encoding a polypeptide with a predicted molecular mass of 24,850 Da. The predicted spoIIM gene product is highly hydrophobic and very basic, and it does not exhibit significant homology to sequence files in several major data bases.

Proteolytic processing of the protease which initiates degradation of small, acid-soluble proteins during germination of Bacillus subtilis spores

Degradation of small, acid-soluble spore proteins during germination of Bacillus subtilis spores is initiated by a sequence-specific protease called GPR. Western blot (immunoblot) analysis of either Bacillus megaterium or B. subtilis GPR expressed in B. subtilis showed that GPR is synthesized at about the third hour of sporulation in a precursor form and is processed to an approximately 2- to 5-kDa-smaller species 2 to 3 h later, at or slightly before the time of accumulation of dipicolinic acid by the forespore. This was found with both normal levels of expression of B. subtilis and B. megaterium GPR in B. subtilis, as well as when either protein was overexpressed up to 100-fold. The sporulation-specific processing of GPR was blocked in all spoIII, -IV, and -V mutants tested (none of which accumulated dipicolinic acid), but not in a spoVI mutant which accumulated dipicolinic acid. The amino-terminal sequences of the B. megaterium and B. subtilis GPR initially synthesized in sporulation were identical to those predicted from the coding genes' sequences. However, the processed form generated in sporulation lacked 15 (B. megaterium) or 16 (B. subtilis) amino-terminal residues. The amino acid sequence surrounding this proteolytic cleavage site was very homologous to the consensus sequence recognized and cleaved by GPR in its small, acid-soluble spore protein substrates. This observation, plus the efficient processing of overproduced GPR during sporulation, suggests that the GPR precursor may autoproteolyze itself during sporulation. During spore germination, the GPR from either species expressed in B. subtilis was further processed by removal of one additional amino-terminal amino acid (leucine), generating the mature protease which acts during spore germination.

The importance of morphological events and intercellular interactions in the regulation of prespore-specific gene expression during sporulation in Bacillus subtilis

We have established a time course for the early morphological events of sporulation in Bacillus subtilis and related this to changes in gene expression, particularly those occurring in the prespore compartment. We have also systematically studied the effects of mutations in various regulatory (spo) genes on prespore-specific gene expression. On the basis of these results, and those of other laboratories, at least four distinct temporal classes of prespore-specific gene expression can now be distinguished. The first class begins within 15 min of the formation of the spore septum, and requires the sigma F form of RNA polymerase. The second class, also directed by RNA polymerase containing sigma F, begins soon after the completion of prespore engulfment, and depends on an intercellular signal from the mother cell. This transcription results in synthesis of sigma G. However, sigma G activity, directing the third class of gene expression, appears only about 30 min later and is dependent on the completion of prespore engulfment and on further interactions with the mother cell. The fourth class of gene expression has been described. The results demonstrate that the prespore programme of gene expression incorporates a series of control points modulated by information from the mother cell and on progress through the morphogenetic process.

Cloning, nucleotide sequence, and regulation of the Bacillus subtilis pbpE operon, which codes for penicillin-binding protein 4* and an apparent amino acid racemase

Penicillin-binding protein 4* (PBP 4*) was purified from Bacillus subtilis, its N-terminal sequence was determined, and the coding gene, termed pbpE, was cloned and sequenced. The predicted amino acid sequence of PBP 4* exhibited similarity to those of other penicillin-recognizing enzymes. Downstream of pbpE there was a second gene, termed orf2, which exhibited sequence similarity with aspartate racemase. The two genes were found to constitute an operon adjacent to and divergently transcribed from the sacB gene at 296 degrees on the chromosomal map. A weak beta-lactamase activity was associated with PBP 4*, but no enzymatic activity was found for the product of orf2. Mutation of pbpE, orf2, or both genes resulted in no observable effect on growth, sporulation, spore heat resistance, or spore germination. A translational pbpE-lacZ fusion was weakly expressed during vegetative growth and was significantly induced at the onset of sporulation. This induction depended on the activity of the spo0A product in relieving repression by the abrB repressor. A single transcription start site which was apparently dependent on E sigma A was detected upstream of pbpE.

Forespore-specific disappearance of the sigma-factor antagonist spoIIAB: implications for its role in determination of cell fate in Bacillus subtilis

Endospore formation in Bacillus subtilis is a morphologically complex process in which the bacterium divides into two compartments (forespore and mother cell) that follow different developmental paths. Compartment-specific transcription in the forespore is initiated by RNA polymerase containing sigma F, and results in the forespore-specific production of sigma G, which directs most of the subsequent forespore-specific transcription. The activity of sigma F is thought to be restricted to the forespore by the sigma factor antagonist SpoIIAB. We used antibodies against SpoIIAB to monitor its accumulation during sporulation. We found that SpoIIAB accumulates early after the initiation of sporulation, and that it was present in the mother-cell compartment 2h after sigma F became active in the forespore. SpoIIAB disappeared preferentially from the forespore during development, and its disappearance from the forespore compartment correlated with the activation of sigma G in that compartment, raising the possibility that SpoIIAB may be involved regulating sigma G activity. We tested whether SpoIIAB could antagonize sigma G activity by replacing the sigma F-dependent promoter that drives expression of spoIIIG, the structural gene for sigma G, with a sigma H-dependent promoter. This resulted in a lytic phenotype that was suppressed by the simultaneous expression of a plasmid-borne copy of spoIIAB. This suggests that SpoIIAB can suppress this effect of sigma G expression. Moreover, these cells formed spores efficiently.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning, nucleotide sequence, and regulation of the Bacillus subtilis nadB gene and a nifS-like gene, both of which are essential for NAD biosynthesis

A number of Bacillus subtilis genes involved in NAD biosynthesis have been cloned and sequenced. One of the genes encodes a polypeptide homologous to Escherichia coli L-aspartate oxidase, and its mutation resulted in a nicotinic acid (Nic)-dependent phenotype; this gene was termed nadB. A second open reading frame (orf2) was found downstream of nadB, and an insertional plasmid separating orf2 and nadB also gave a Nic-dependent phenotype. This result suggests that orf2 may also be involved in NAD biosynthesis and that nadB and orf2 are in the same operon. Upstream of nadB was a third gene, transcribed in the opposite direction to that of nadB-orf2. The amino acid sequence derived from the third gene was quite similar to those derived from nifS genes of various nitrogen-fixing bacteria; therefore, the third gene was termed nifS. As with nadB and orf2, mutations in nifS also resulted in a Nic-dependent phenotype. The promoter regions of nadB and nifS overlapped each other and both contained -10 and -35 sequences which resemble those of E sigma A-type promoters. Transcription from both the nifS and nadB promoters, as well as expression of a nadB-lacZ fusion, was repressed by Nic. However, nadB transcription and nadB-lacZ expression were decreased, at most, only slightly by a deletion in nifS. The possible role of the nifS gene product in NAD biosynthesis is discussed.

Molecular cloning and characterization of the Bacillus subtilis spore photoproduct lyase (spl) gene, which is involved in repair of UV radiation-induced DNA damage during spore germination

Upon UV irradiation, Bacillus subtilis spore DNA accumulates the novel thymine dimer 5-thyminyl-5,6-dihydrothymine. Spores can repair this "spore photoproduct" (SP) upon germination either by the uvr-mediated general excision repair pathway or by the SP-specific spl pathway, which involves in situ monomerization of SP to two thymines by an enzyme named SP lyase. Mutants lacking both repair pathways produce spores that are extremely sensitive to UV. For cloning DNA that can repair a mutation in the spl pathway called spl-1, a library of EcoRI fragments of chromosomal DNA from B. subtilis 168 was constructed in integrative plasmid pJH101 and introduced by transformation into a mutant B. subtilis strain that carries both the uvrA42 and spl-1 mutations, and transformants whose spores exhibited UV resistance were selected by UV irradiation. With a combination of genetic and physical mapping techniques, the DNA responsible for the restoration of UV resistance was shown to be present on a 2.3-kb EcoRI-HindIII fragment that was mapped to a new locus in the metC-pyrD region of the B. subtilis chromosome immediately downstream from the pstI gene. The spl coding sequence was localized on the cloned fragment by analysis of in vitro-generated deletions and by nucleotide sequencing. The spl nucleotide sequence contains an open reading frame capable of encoding a 40-kDa polypeptide that shows regional amino acid sequence homology to DNA photolyases from a number of bacteria and fungi.

Cloning and characterization of a gene required for assembly of the Bacillus subtilis spore coat

During endospore formation in Bacillus subtilis, approximately a dozen proteins are synthesized and assembled around the prespore to form a protective coat. Little is known about the assembly process, but several of the genes encoding these coat proteins are expressed in the mother cell compartment, where the proteins accumulate on the outer side of the developing endospore. Transcription of these genes is directed by the mother cell-specific sigma factor, sigma K, during the later stages of endospore development. sigma E may direct expression of the genes that encode proteins that function in the earliest stages of coat assembly. By screening for sigma E-dependent promoters, we cloned a gene, designated spoVID, required for assembly of a normal spore coat. Expression of spoVID was initiated at about the second hour of sporulation and continued throughout development from a sigma E-dependent promoter. The spoVID gene was located on the B. subtilis chromosome just downstream of the previously characterized hemAXCDBL operon and is predicted to encode an extremely acidic protein with 575 residues. Insertion mutants of spoVID produced refractile spores that were resistant to heat and to chloroform but were sensitive to lysozyme. Electron microscopic examination of sporulating spoVID mutant cells revealed normal morphological development up to about the third hour of sporulation. However, during the later stages of development the coat proteins assembled into aberrant structures that occurred freely in the mother cell cytoplasm and that consisted of reiterations of the single inner and outer layers that normally make up the spore coat.

Bacillus subtilis sporulation: regulation of gene expression and control of morphogenesis

Bacillus subtilis sporulation is an adaptive response to nutritional stress and involves the differential development of two cells. In the last 10 years or so, virtually all of the regulatory genes controlling sporulation, and many genes directing the structural and morphological changes that accompany sporulation, have been cloned and characterized. This review describes our current knowledge of the program of gene expression during sporulation and summarizes what is known about the functions of the genes that determine the specialized biochemical and morphological properties of sporulating cells. Most steps in the genetic program are controlled by transcription factors that have been characterized in vitro. Two sporulation-specific sigma factors, sigma E and sigma F, appear to segregate at septation, effectively determining the differential development of the mother cell and prespore. Later, each sigma is replaced by a second cell-specific sigma factor, sigma K in the mother cell and sigma G in the prespore. The synthesis of each sigma factor is tightly regulated at both the transcriptional and posttranslational levels. Usually this regulation involves an intercellular interaction that coordinates the developmental programmes of the two cells. At least two other transcription factors fine tune the timing and levels of expression of genes in the sigma E and sigma K regulons. The controlled synthesis of the sigma factors and other transcription factors leads to a spatially and temporally ordered program of gene expression. The gene products made during each successive stage of sporulation help to bring about a sequence of gross morphological changes and biochemical adaptations. The formation of the asymmetric spore septum, engulfment of the prespore by the mother cell, and formation of the spore core, cortex, and coat are described. The importance of these structures in the development of the resistance, dormancy, and germination properties of the spore is assessed.

Prevention of DNA damage in spores and in vitro by small, acid-soluble proteins from Bacillus species

The DNA in dormant spores of Bacillus species is saturated with a group of nonspecific DNA-binding proteins, termed alpha/beta-type small, acid-soluble spore proteins (SASP). These proteins alter DNA structure in vivo and in vitro, providing spore resistance to UV light. In addition, heat treatments (e.g., 85 degrees C for 30 min) which give little killing of wild-type spores of B. subtilis kill > 99% of spores which lack most alpha/beta-type SASP (termed alpha - beta - spores). Similar large differences in survival of wild-type and alpha - beta - spores were found at 90, 80, 65, 22, and 10 degrees C. After heat treatment (85 degrees C for 30 min) or prolonged storage (22 degrees C for 6 months) that gave > 99% killing of alpha - beta - spores, 10 to 20% of the survivors contained auxotrophic or asporogenous mutations. However, alpha - beta - spores heated for 30 min at 85 degrees C released no more dipicolinic acid than similarly heated wild-type spores (< 20% of the total dipicolinic acid) and triggered germination normally. In contrast, after a heat treatment (93 degrees C for 30 min) that gave > or = 99% killing of wild-type spores, < 1% of the survivors had acquired new obvious mutations, > 85% of the spore's dipicolinic acid had been released, and < 1% of the surviving spores could initiate spore germination. Analysis of DNA extracted from heated (85 degrees C, 30 min) and unheated wild-type spores and unheated alpha - beta - spores revealed very few single-strand breaks (< 1 per 20 kb) in the DNA. In contrast, the DNA from heated alpha- beta- spores had more than 10 single-strand breaks per 20 kb. These data suggest that binding of alpha/beta-type SASP to spore DNA in vivo greatly reduces DNA damage caused by heating, increasing spore heat resistance and long-term survival. While the precise nature of the initial DNA damage after heating of alpha- beta- spores that results in the single-strand breaks is not clear, a likely possibility is DNA depurination. A role for alpha/beta-type SASP in protecting DNA against depurination (and thus promoting spore survival) was further suggested by the demonstration that these proteins reduce the rate of DNA depurination in vitro at least 20-fold.

Dipicolinic Acid Greatly Enhances Production of Spore Photoproduct in Bacterial Spores upon UV Irradiation

Formation of the spore photoproduct (SP) (5-thyminyl-5,6-dihydrothymine) in DNA of dormant spores of Bacillus subtilis upon UV irradiation is due to binding of α/β-type small, acid-soluble proteins (SASP). However, the yield of SP as a function of UV fluence is ∼15-fold higher in spores than in an α/β-type-SASP-DNA complex in vitro. The yield of SP as a function of UV fluence in forespore DNA from mutants which make α/β-type SASP but not dipicolinic acid (DPA) was 10 to 20 times lower than that in dormant spores. Furthermore, the yield of SP as a function of UV fluence in an α/β-type-SASP-DNA complex in vitro was increased sixfold by DPA. These data provide further support for the idea that the high DPA level in dormant spores increases the yield of SP as a function of UV fluence and thereby sensitizes spores to UV.

Sporulation gene spoIIB from Bacillus subtilis

We have cloned and characterized the sporulation gene spoIIB from Bacillus subtilis. In extension of previous nucleotide sequence analysis, our results show that the order of genes in the vicinity of spoIIB is valS folC comC spoIIB orfA orfB mreB mreC mreD minC minD spoIVFA spoIVFB L20 orfX L24 spoOB obg pheB pheA. All 20 genes have the same orientation; the direction of transcription is from valS to pheA. We show that spoIIB is a 332-codon-long open reading frame whose transcription is under sporulation control. The deduced amino acid sequence of the spoIIB gene product, a 36-kDa polypeptide, is highly charged and contains a stretch of uncharged amino acids that could correspond to a transmembrane segment. Surprisingly, mutations in spoIIB, including an in vitro-constructed null mutation, cause only a mild impairment of spore formation in certain otherwise wild-type bacteria. However, when combined with mutations in another sporulation gene, spoVG, mutations in spoIIB cause a severe block in spore formation at the stage (stage II) of septum formation. (As with spoIIB mutations, mutations in spoVG cause little impairment in sporulation on their own.) The nature of the spoIIB spoVG mutant phenotype is discussed in terms of the events involved in the maturation of the sporulation septum and in the activation of sporulation transcription factors sigma F and sigma E.

Activity of mutant sigma F proteins truncated near the C terminus

sigma F, the product of the spoIIAC gene of Bacillus subtilis, is homologous in amino acid sequence throughout most of its length with several other sigma factors of B. subtilis and Escherichia coli. However, 8 residues from the C terminus the homology abruptly breaks down, suggesting that the C-terminal tail of the protein may be dispensable. It is known that an amber mutation at the 11th codon (wild-type glutamine 245) from the C terminus abolishes the function of the sigma factor. We have now placed chain-terminating codons at the ninth codon (wild-type lysine 247), the eighth codon (wild-type valine 248), or the seventh codon (wild-type glutamine 249) from the C terminus. We have tested the resulting mutants for their capacity to sporulate and for their ability to transcribe from a promoter (spoIIIG) that is normally read by RNA polymerase bound to sigma F (E sigma F). The results indicate that a mutant sigma F lacking the terminal 7 residues functions almost normally, which suggests that glutamine 249 is dispensable. By contrast, lysine 247 is crucial for the activity of sigma F: deletion of the 9 C-terminal residues totally inactivates the protein. When the terminal 8 residues were deleted, placing lysine 247 at the C terminus, the transcriptional activity of the factor is reduced by about 80%: we attribute this effect to neutralization of the positive charge of lysine 247 by formation of a salt bridge with the -COO- terminus.

Compartmentalized transcription and the establishment of cell type during sporulation in Bacillus subtilis

An early step in sporulation of the bacterium Bacillus subtilis, is the formation of two compartments in the developing sporangium: the mother cell and the forespore. These compartments differ in their programs of gene expression and developmental fate. The establishment of cell type within this simple developmental program, is accomplished by the compartmentalization of sigma subunits of RNA polymerase. The localization of these sigma factors results in compartment-specific gene expression. Recent experiments have elucidated some of the early steps in the establishment of cell type. After septum formation, the activity of the sigma factor, sigma F, is confined to the forespore compartment. This, in turn, results in the localized expression of another developmental sigma factor, sigma G. The forespore localization of these two sigma factors, establishes the forespore line of gene expression. sigma F and sigma G also regulate mother cell events. sigma F activity in the forespore regulates the proteolytic processing of sigma E within the mother cell compartment. The localization sigma E activity leads to mother cell expression of another sigma factor, pro-sigma K. The proteolytic processing of pro-sigma K to mature sigma K is controlled by the forespore sigma factor, sigma G. Mature sigma K then directs the transcription of mother cell specific genes. Therefore, the initial localization of sigma F activity to the forespore compartment, orchestrates the establishment of cell type in both forespore and mother cell compartments.

Characterization of spoIVA, a sporulation gene involved in coat morphogenesis in Bacillus subtilis

We report the cloning and characterization of the Bacillus subtilis sporulation locus spoIVA, mutations at which cause an unusual defect in spore formation in which the coat misassembles as swirls within the mother cell. We show that spoIVA is a single gene of 492 codons that is capable of encoding a polypeptide of 55 kDa. Transcription of spoIVA is induced at about the second hour of sporulation by the regulatory protein sigma E from two closely spaced promoters designated P1 and P2. Experiments in which the upstream promoter P1 was removed show that transcription of spoIVA from P2 is sufficient for efficient spore formation. Based on these and other findings, we infer that the spoIVA gene product is a morphogenetic protein; we discuss its role in the deposition of coat polypeptides around the developing forespore.

Characterization of a sporulation gene, spoIVA, involved in spore coat morphogenesis in Bacillus subtilis

Mutations in the spoIVA locus of Bacillus subtilis abolish cortex synthesis and interfere with the synthesis and assembly of the spore coat. We have characterized the cloned spoIVA locus in terms of its physical structure and regulation during sporulation. The locus contains a single gene capable of encoding an acidic protein of 492 amino acids (molecular weight, 55,174). The gene is transcribed from a sigma E-dependent promoter soon after the formation of the spore septum. A genetic test indicated that expression of spoIVA is only necessary in the mother cell compartment for the formation of a mature spore. This, together with the phenotypic properties of spoIVA mutations, would be in accord with the hypothesis that sigma E is only active after septation and in the mother cell compartment.

Effect of chromosome location of Bacillus subtilis forespore genes on their spo gene dependence and transcription by E sigma F: identification of features of good E sigma F-dependent promoters

Translational lacZ fusions to forespore genes of Bacillus subtilis were not expressed in spoIIAC (sigma F) or spoIIIE mutants when the lacZ fusions were integrated at the loci of the same genes or at the SP beta locus. However, some of these genes, including gerA, gpr, spoIIIG (sigma G), and sspE, were expressed in spoIIIE mutants and spoIIIE spoIIIG double mutants (but not in spoIIAC mutants) when the lacZ fusions were integrated at the amyE locus. When tested, the beta-galactosidase made in these mutants was found only in the forespore, and the 5' ends of the mRNAs produced in these mutants were identical to those in a Spo+ background. Analysis of the in vitro transcription of forespore genes by RNA polymerase containing sigma F (E sigma F) revealed a direct correlation between good in vitro transcription by E sigma F and expression at the amyE locus in spoIIIE mutants. This result suggests that forespore genes are transcribed by E sigma F in spoIIIE and spoIIIE spoIIIG mutants. Comparison of the promoter regions of genes transcribed well and poorly by E sigma F in vivo and in vitro showed that good transcription by E sigma F was correlated with G residues at positions -15 and -16, a purine residue at position -13, and a T residue at position -7 relative to the start site of transcription. The importance of these residues in sigma F recognition was confirmed by analysis of the E sigma F-dependent transcription in vivo and in vitro of mutant ssp genes.

Cloning, characterization, and expression of the spoVB gene of Bacillus subtilis

Mutation of the spoVB gene in Bacillus subtilis causes the production of spores containing a defective cortex and unable to acquire heat resistance. The spoVB locus is highly linked to another spo locus, spoIIIF, characterized by a single mutation (I. L. Lamont and J. Mandelstam, J. Gen. Microbiol. 130:1253-1261, 1984). A 18-kb DNA region overlapping the spoIIIF-spoVB region was cloned in successive steps starting from a Tn917 insertion in the nic locus. The exact location of the spoIIIF and spoVB loci was defined with various integrative plasmids carrying subfragments of that region. DNA sequencing established that spoIIIF and spoVB are a single monocistronic locus encoding a 518-amino-acid polypeptide with features of an integral membrane protein. The precise location of the spoIIIF590 and spoVB91 mutations in that unique open reading frame was determined, and both mutations were sequenced. A null mutation was engineered in the spoIIIF-spoVB locus and led to a typical spoVB phenotype, identical to the phenotype created by either spoIIIF590 or spoVB91, suggesting that the original spoIIIF mutant contained a secondary mutation arresting sporulation at an earlier stage. A transcriptional spoVB-lacZ fusion was constructed, and its expression was found to be directly dependent on RNA polymerase containing sigma E. A null mutation of spoVB had no effect on expression of sspB and cotA, members of the sigma G- and sigma K-controlled regulons respectively, while expression of cotC, a member of the latest known mother cell regulon, was delayed and strongly reduced. These results are consistent with SpoVB being involved in cortex biosynthesis and affecting only indirectly expression of late sporulation genes.

Compartmentalized expression of a gene under the control of sporulation transcription factor sigma E in Bacillus subtilis

Immunoelectron microscopy was used to visualize the expression of a gene under the control of developmental transcription factor sigma E during spore formation in Bacillus subtilis. sigma E is generated by cleavage of an inactive proprotein (pro-sigma E) shortly after the formation of the sporulation septum, which partitions the sporangium into mother-cell and forespore compartments. Specific antibodies and gold-conjugated secondary antibodies were used to localize beta-galactosidase in thin sections of sporangia from cells bearing a lacZ transcriptional fusion to a gene (spoIID) under the direct control of sigma E. Transcription of spoIID was found to be induced shortly after the formation of the sporulation septum and was largely confined to the mother cell. Cell-type-specific transcription of genes under the control of sigma E could be responsible for establishing the mother-cell line of gene expression.

Deletion of spoIIAB blocks endospore formation in Bacillus subtilis at an early stage

During an early stage of endospore formation in Bacillus subtilis, the cell divides asymmetrically into two compartments that follow different developmental paths. The differential expression of genes in these two compartments is controlled in part by the production of compartment-specific transcription factors, sigma G and sigma K. It is not known how sigma G accumulation is restricted to one of the two compartments, the forespore. However, the observations that sigma F directs transcription of the structural gene for sigma G and that sigma F activity can be modified by the product of a gene, spoIIAB, has led us to investigate the role of spoIIAB during sporulation. We have isolated mutants that carry deletion alleles of spoIIAB. Electron microscopic examination of these mutants revealed that these mutations blocked endospore formation at an early stage before septation and caused extensive cell lysis. The spoIIAB deletion alleles caused hyperexpression of genes that are normally expressed exclusively in the forespore compartments of sporulating wild-type cells, whereas these alleles reduced expression of other genes, including spoIIE, which is expressed before septation in wild-type cells. These observations confirm that spoIIAB is essential for sporulation and are consistent with models in which the product of spoIIAB plays a role in regulating the timing and/or compartment specificity of sigma F- and sigma G-directed transcription.

Establishment of cell type by compartmentalized activation of a transcription factor

Early in the process of spore formation in Bacillus subtilis a septum is formed that partitions the sporangium into daughter cells called the forespore and the mother cell. The daughter cells each have their own chromosome but follow dissimilar programs of gene expression. Differential gene expression in the forespore is now shown to be established by the compartmentalized activity of the transcription factor sigma F. The sigma F factor is produced prior to septation, but is active only in the forespore compartment of the post-septation sporangium. The sigma F factor is controlled by the products of sporulation operons spoIIA and spoIIE, which may be responsible for confining its activity to one of the daughter cells.

Condensation of the forespore nucleoid early in sporulation of Bacillus species

Fluorescence microscopic examination coupled with digital videoimage analysis of 4',6-diamidino-2-phenylindole-stained sporulating cells of Bacillus megaterium or Bacillus subtilis revealed a striking condensation of the forespore nucleoid. While both mother cell and forespore compartments had equal amounts of DNA, the forespore nucleoid became greater than 2-fold more condensed than the mother cell nucleoid. The condensation of the forespore nucleoid began after only the first hour of sporulation, 2 to 3 h before expression of most forespore-specific genes including those for small, acid-soluble spore proteins, and was abolished in spo0 mutants but not in spoII or spoIII mutants. It is possible that this striking condensation of forespore DNA plays some role in modulating gene expression during sporulation.

Analysis of transcriptional control of the gerD spore germination gene of Bacillus subtilis 168

The gerD locus of Bacillus subtilis comprises a single gene whose function is essential for the germination of B. subtilis spores in media containing asparagine, glucose, and fructose. The expression of gerD has been characterized by using a chromosomal lacZ fusion to the gerD promoter. The promoter is switched on at the same time as the synthesis of glucose dehydrogenase, 2.5 h after sporulation has been initiated in the developing forespore. The gerD gene is not expressed in spoIIB or spoIIIA, -IIIB, -EIII, -FIII, or -IIIG mutants, but it is expressed in spoIIIC and -IIID and spoIVA mutant backgrounds. The in vivo transcriptional start point of the gene has been mapped by primer extension analysis, and sequences upstream from the start point show considerable homology with the promoter consensus sequences recognized by RNA polymerase containing the forespore-specific sigma factor sigma G (E sigma G). gerD is transcribed in vitro by E sigma G with a similar if not identical start point to that found in vivo, and expression of the gene can be rapidly induced in vegetative cells following the induction of sigma G synthesis. These results indicate that gerD is another member of the sigma G regulon, which includes a number of genes expressed only in the forespore compartment of sporulating cells of B. subtilis.

The spoIIIA operon of Bacillus subtilis defines a new temporal class of mother-cell-specific sporulation genes under the control of the sigma E form of RNA polymerase

We have cloned and characterized a 5 kbp region of the Bacillus subtilis chromosome and show that it contains the promoter-proximal part of the spoIIIA locus. The locus consists of a polycistronic operon containing at least three genes. We show that the operon is regulated at the transcriptional level, from a promoter that is first activated about 80 minutes after the induction of sporulation, immediately after septation. Expression of spoIIIA in different spo mutant backgrounds correlates with the ability of each strain to synthesize the sporulation-specific sigma factor, sigma E. Moreover, synthesis of sigma E in vegetative cells by use of an inducible promoter causes expression of mother-cell-specific genes spoIID, spoIIIA, and spoIIID, but not the prespore-specific genes, spoIIIG and spoVA. We suggest that sigma E may be the primary determinant of mother-cell-specific gene expression and that the SpoIIID protein exerts an additional level of regulation on spoIIIA, apparently by acting as a transcriptional repressor. Since the onset of spoIIID expression occurs about 10 minutes after that of spoIIIA, spoIIIA expression is transient. Thus spoIIIA defines a third temporal class of gene controlled by the sigma E form of RNA polymerase.

Effects of mutant small, acid-soluble spore proteins from Bacillus subtilis on DNA in vivo and in vitro

alpha/beta-type small, acid-soluble spore proteins (SASP) of Bacillus subtilis bind to DNA and alter its conformation, topology, and photochemistry, and thereby spore resistance to UV light. Three mutations have been introduced into the B. subtilis sspC gene, which codes for the alpha/beta-type wild-type SASP, SspCwt. One mutation (SspCTyr) was a conservative change, as residue 29 (Leu) was changed to Tyr, an amino acid found at this position in other alpha/beta-type SASP. The other mutations changed residues conserved in all alpha/beta-type SASP. In one (SspCAla), residue 52 (Gly) was changed to Ala; in the second (SspCGln), residue 57 (Lys) was changed to Gln. The effects of the wild-type and mutant SspC on DNA properties were examined in vivo in B. subtilis spores and Escherichia coli as well as in vitro with use of purified protein. Both SspCwt and SspCTyr interacted similarly with DNA in vivo and in vitro, restoring much UV resistance to spores lacking major alpha/beta-type SASP, causing a large increase in plasmid negative supercoiling, and altering DNA UV photochemistry from cell type to spore type. In contrast, SspCAla had no detectable effect on DNA properties in vivo or in vitro, while SspCGln had effects intermediate between those of SspCAla and SspCwt. Strikingly, neither SspCAla nor SspCGln bound well to DNA in vitro. These results confirm the importance of the conserved primary sequence of alpha/beta-type SASP in the ability of these proteins to bind to spore DNA and cause spore UV resistance.