Analysis of the role of prespore gene expression in the compartmentalization of mother cell-specific gene expression during sporulation of Bacillus subtilis

Genome-wide analysis of cell type-specific gene transcription during spore formation in Clostridium difficile

Clostridium difficile, a Gram positive, anaerobic, spore-forming bacterium is an emergent pathogen and the most common cause of nosocomial diarrhea. Although transmission of C. difficile is mediated by contamination of the gut by spores, the regulatory cascade controlling spore formation remains poorly characterized. During Bacillus subtilis sporulation, a cascade of four sigma factors, σ(F) and σ(G) in the forespore and σ(E) and σ(K) in the mother cell governs compartment-specific gene expression. In this work, we combined genome wide transcriptional analyses and promoter mapping to define the C. difficile σ(F), σ(E), σ(G) and σ(K) regulons. We identified about 225 genes under the control of these sigma factors: 25 in the σ(F) regulon, 97 σ(E)-dependent genes, 50 σ(G)-governed genes and 56 genes under σ(K) control. A significant fraction of genes in each regulon is of unknown function but new candidates for spore coat proteins could be proposed as being synthesized under σ(E) or σ(K) control and detected in a previously published spore proteome. SpoIIID of C. difficile also plays a pivotal role in the mother cell line of expression repressing the transcription of many members of the σ(E) regulon and activating sigK expression. Global analysis of developmental gene expression under the control of these sigma factors revealed deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We showed that the expression of the σ(E) regulon in the mother cell was not strictly under the control of σ(F) despite the fact that the forespore product SpoIIR was required for the processing of pro-σ(E). In addition, the σ(K) regulon was not controlled by σ(G) in C. difficile in agreement with the lack of pro-σ(K) processing. This work is one key step to obtain new insights about the diversity and evolution of the sporulation process among Firmicutes.

Loss of compartmentalization of σ(E) activity need not prevent formation of spores by Bacillus subtilis

Compartmentalization of the activities of RNA polymerase sigma factors is a hallmark of formation of spores by Bacillus subtilis. It is initiated soon after the asymmetrically located sporulation division takes place with the activation of σ(F) in the smaller cell, the prespore. σ(F) then directs a signal via the membrane protease SpoIIGA to activate σ(E) in the larger mother cell by processing of pro-σ(E). Here, we show that σ(E) can be activated in the prespore with little effect on sporulation efficiency, implying that complete compartmentalization of σ(E) activity is not essential for spore formation. σ(E) activity in the prespore can be obtained by inducing transcription in the prespore of spoIIGA or of sigE*, which encodes a constitutively active form of σ(E), but not of spoIIGB, which encodes pro-σ(E). We infer that σ(E) compartmentalization is partially attributed to a competition between the compartments for the activation signaling protein SpoIIR. Normally, SpoIIGA is predominantly located in the mother cell and as a consequence confines σ(E) activation to it. In addition, we find that CsfB, previously shown to inhibit σ(G), is independently inhibiting σ(E) activity in the prespore. CsfB thus appears to serve a gatekeeper function in blocking the action of two sigma factors in the prespore: it prevents σ(G) from becoming active before completion of engulfment and helps prevent σ(E) from becoming active at all.

SpoIIIE strips proteins off the DNA during chromosome translocation

The FtsK/SpoIIIE family of DNA transporters are responsible for translocating missegregated chromosomes after the completion of cell division. An extreme example of this post-cytokinetic DNA segregation occurs during spore formation in the bacterium Bacillus subtilis, where SpoIIIE pumps three-quarters of the chromosome (>3 megabases) into one of the two daughter cells. Here, we investigate the fate of the proteins associated with the translocated DNA. Taking advantage of several unique features of Bacillus sporulation, we demonstrate that RNA polymerase, transcription factors, and chromosome remodeling proteins are stripped off the DNA during translocation of the chromosome into the forespore compartment. Furthermore, we show that in vitro the soluble ATPase domain of SpoIIIE can displace RNA polymerase bound to DNA, suggesting that SpoIIIE alone is capable of this wire-stripping activity. Our data suggest that the bulk of the forespore chromosome is translocated naked into the forespore compartment. We propose that the translocation-stripping activity of SpoIIIE plays a key role in reprogramming developmental gene expression in the forespore.

Control of the expression and compartmentalization of (sigma)G activity during sporulation of Bacillus subtilis by regulators of (sigma)F and (sigma)E

During formation of spores by Bacillus subtilis the RNA polymerase factor sigma(G) ordinarily becomes active during spore formation exclusively in the prespore upon completion of engulfment of the prespore by the mother cell. Formation and activation of sigma(G) ordinarily requires prior activity of sigma(F) in the prespore and sigma(E) in the mother cell. Here we report that in spoIIA mutants lacking both sigma(F) and the anti-sigma factor SpoIIAB and in which sigma(E) is not active, sigma(G) nevertheless becomes active. Further, its activity is largely confined to the mother cell. Thus, there is a switch in the location of sigma(G) activity from prespore to mother cell. Factors contributing to the mother cell location are inferred to be read-through of spoIIIG, the structural gene for sigma(G), from the upstream spoIIG locus and the absence of SpoIIAB, which can act in the mother cell as an anti-sigma factor to sigma(G). When the spoIIIG locus was moved away from spoIIG to the distal amyE locus, sigma(G) became active earlier in sporulation in spoIIA deletion mutants, and the sporulation septum was not formed, suggesting that premature sigma(G) activation can block septum formation. We report a previously unrecognized control in which SpoIIGA can prevent the appearance of sigma(G) activity, and pro-sigma(E) (but not sigma(E)) can counteract this effect of SpoIIGA. We find that in strains lacking sigma(F) and SpoIIAB and engineered to produce active sigma(E) in the mother cell without the need for SpoIIGA, sigma(G) also becomes active in the mother cell.

Subcellular localization of a sporulation membrane protein is achieved through a network of interactions along and across the septum

During the process of spore formation in Bacillus subtilis many membrane proteins localize to the sporulation septum where they play key roles in morphogenesis and cell-cell signalling. However, the mechanism by which these proteins are anchored at this site is not understood. In this report we have defined the localization requirements for the mother-cell membrane protein SpoIVFA, which anchors a signalling complex in the septal membrane on the mother cell side. We have identified five proteins (SpoIID, SpoIIP, SpoIIM, BofA and SpoIIIAH) synthesized in the mother cell under the control of sigma(E) and one protein (SpoIIQ) synthesized in the forespore under the control of sigma(F) that are all required for the proper localization of SpoIVFA. Surprisingly, these proteins appear to have complementary and overlapping anchoring roles suggesting that SpoIVFA is localized in the septal membrane through a web of protein interactions. Furthermore, we demonstrate a direct biochemical interaction between the extracellular domains of two of the proteins required to anchor SpoIVFA: the forespore protein SpoIIQ and the mother-cell protein SpoIIIAH. This result supports the idea that the web of interactions that anchors SpoIVFA is itself held in the septal membrane through a zipper-like interaction across the sporulation septum. Importantly, our results suggest that a second mechanism independent of forespore proteins participates in anchoring SpoIVFA. Finally, we show that the dynamic localization of SpoIIQ in the forespore is impaired in the absence of SpoIVFA but not SpoIIIAH. Thus, a complex web of interactions among mother cell and forespore proteins is responsible for static and dynamic protein localization in both compartments of the sporangium. We envision that this proposed network is involved in anchoring other sporulation proteins in the septum and that protein networks with overlapping anchoring capacity is a feature of protein localization in all bacteria.

Compartmentalization of gene expression during Bacillus subtilis spore formation

Gene expression in members of the family Bacillaceae becomes compartmentalized after the distinctive, asymmetrically located sporulation division. It involves complete compartmentalization of the activities of sporulation-specific sigma factors, sigma(F) in the prespore and then sigma(E) in the mother cell, and then later, following engulfment, sigma(G) in the prespore and then sigma(K) in the mother cell. The coupling of the activation of sigma(F) to septation and sigma(G) to engulfment is clear; the mechanisms are not. The sigma factors provide the bare framework of compartment-specific gene expression. Within each sigma regulon are several temporal classes of genes, and for key regulators, timing is critical. There are also complex intercompartmental regulatory signals. The determinants for sigma(F) regulation are assembled before septation, but activation follows septation. Reversal of the anti-sigma(F) activity of SpoIIAB is critical. Only the origin-proximal 30% of a chromosome is present in the prespore when first formed; it takes approximately 15 min for the rest to be transferred. This transient genetic asymmetry is important for prespore-specific sigma(F) activation. Activation of sigma(E) requires sigma(F) activity and occurs by cleavage of a prosequence. It must occur rapidly to prevent the formation of a second septum. sigma(G) is formed only in the prespore. SpoIIAB can block sigma(G) activity, but SpoIIAB control does not explain why sigma(G) is activated only after engulfment. There is mother cell-specific excision of an insertion element in sigK and sigma(E)-directed transcription of sigK, which encodes pro-sigma(K). Activation requires removal of the prosequence following a sigma(G)-directed signal from the prespore.

Contrasting effects of sigmaE on compartmentalization of sigmaF activity during sporulation of Bacillus subtilis

Spore formation by Bacillus subtilis is a primitive form of development. In response to nutrient starvation and high cell density, B. subtilis divides asymmetrically, resulting in two cells with different sizes and cell fates. Immediately after division, the transcription factor sigmaF becomes active in the smaller prespore, which is followed by the activation of sigmaE in the larger mother cell. In this report, we examine the role of the mother cell-specific transcription factor sigmaE in maintaining the compartmentalization of gene expression during development. We have studied a strain with a deletion of the spoIIIE gene, encoding a DNA translocase, that exhibits uncompartmentalized sigmaF activity. We have determined that the deletion of spoIIIE alone does not substantially impact compartmentalization, but in the spoIIIE mutant, the expression of putative peptidoglycan hydrolases under the control of sigmaE in the mother cell destroys the integrity of the septum. As a consequence, small proteins can cross the septum, thereby abolishing compartmentalization. In addition, we have found that in a mutant with partially impaired control of sigmaF, the activation of sigmaE in the mother cell is important to prevent the activation of sigmaF in this compartment. Therefore, the activity of sigmaE can either maintain or abolish the compartmentalization of sigmaF, depending upon the genetic makeup of the strain. We conclude that sigmaE activity must be carefully regulated in order to maintain compartmentalization of gene expression during development.

Compartmentalization of gene expression during sporulation of Bacillus subtilis is compromised in mutants blocked at stage III of sporulation

Mutations in the spoIIIA and spoIIIJ loci disrupt the compartmentalization of gene expression during sporulation of Bacillus subtilis. The breakdown in compartmentalization is not the cause of their being blocked in spore formation. Rather, it appears to be a consequence of the engulfed prespore's being unstable.

Novel spoIIE mutation that causes uncompartmentalized sigmaF activation in Bacillus subtilis

During sporulation, Bacillus subtilis undergoes an asymmetric division that results in two cells with different fates, the larger mother cell and the smaller forespore. The protein phosphatase SpoIIE, which is required for activation of the forespore-specific transcription factor sigma(F), is also required for optimal efficiency and timing of asymmetric division. We performed a genetic screen for spoIIE mutants that were impaired in sporulation but not sigma(F) activity and isolated a strain with the mutation spoIIEV697A. The mutant exhibited a 10- to 40-fold reduction in sporulation and a sixfold reduction in asymmetric division compared to the parent. Transcription of the sigma(F)-dependent spoIIQ promoter was increased more than 10-fold and was no longer confined to the forespore. The excessive sigma(F) activity persisted even when asymmetric division was prevented. Disruption of spoIIGB did not restore asymmetric division to the spoIIEV697A mutant, indicating that the deficiency is not a consequence of predivisional activation of the mother cell-specific transcription factor sigma(E). Deletion of the gene encoding sigma(F) (spoIIAC) restored asymmetric division; however, a mutation that dramatically reduced the number of promoters responsive to sigma(F), spoIIAC561 (spoIIACV233 M), failed to do so. This result suggests that the block is due to expression of one of the small subset of sigma(F)-dependent genes expressed in this background or to unregulated interaction of sigmaF with some other factor. Our results indicate that regulation of SpoIIE plays a critical role in coupling asymmetric division to sigma(F) activation in order to ensure proper spatial and temporal expression of forespore-specific genes.

Subcellular localization of a small sporulation protein in Bacillus subtilis

SpoVM is an unusually small (26-residue-long) protein that is produced in the mother cell chamber of the sporangium during the process of sporulation in Bacillus subtilis. We investigated the subcellular localization of SpoVM, which is believed to be an amphipathic alpha-helix, by using a fusion of the sporulation protein to the green fluorescence protein (GFP). We found that SpoVM-GFP is recruited to the polar septum shortly after the sporangium undergoes asymmetric division and that the fusion protein localizes to the mother cell membrane that surrounds the forespore during the subsequent process of engulfment. We identified a patch of three residues near the N terminus of the proposed alpha-helix that is needed both for proper subcellular localization and for SpoVM function. We also identified a patch of residues on the opposite face of the helix and residues near both ends of the protein that are needed for SpoVM function but not for subcellular localization. Subcellular localization of SpoVM-GFP was found to require an unknown gene(s) under the control of the mother cell transcription factor sigmaE. We propose that the N-terminal patch binds to an unknown anchoring protein that is produced under the control of sigmaE and that other residues important in SpoVM function to recruit an unknown sporulation protein(s) to the mother cell membrane that surrounds the forespore. Our results provide evidence that SpoVM function depends on proper subcellular localization.

An investigation into the compartmentalization of the sporulation transcription factor sigmaE in Bacillus subtilis

Sporulation in Bacillus subtilis involves the formation of a polar septum, which divides the sporangium into a mother cell and a forespore. The sigmaE factor, which is encoded within the spoIIG operon, is a cell-specific regulatory protein that directs gene transcription in the mother cell. SigmaE is synthesized as an inactive proprotein pro-sigmaE, which is converted to the mature factor by the putative processing enzyme SpoIIGA. Processing of pro-sigmaE does not commence until after asymmetric division when sigmaE is largely confined to the mother cell. Processing depends on the signalling protein SpoIIR, which delays proteolysis until after polar septation, but the mechanism by which sigmaE is confined to the mother cell is not understood. Previous work favoured a model in which pro-sigmaE localizes to the mother cell face of the polar septum, such that sigmaE would be selectively released into mother cell cytoplasm. Based on the use of green fluorescent protein (GFP) fusions, we now report that pro-sigmaE is distributed approximately uniformly along all membrane surfaces and is not confined to the mother- cell face of the septum. Rather, our results are consistent with a model in which preferential and persistent transcription of the spoIIG operon in the mother cell and degradation of sigmaE in the forespore contribute to the selective accumulation of sigmaE in the mother cell. Persistent transcription of spoIIG after polar septation also contributes to the proper timing of pro-sigmaE processing.

Forespore-specific transcription of the lonB gene during sporulation in Bacillus subtilis

The Bacillus subtilis genome encodes two members of the Lon family of prokaryotic ATP-dependent proteases. One, LonA, is produced in response to temperature, osmotic, and oxidative stress and has also been implicated in preventing sigma(G) activity under nonsporulation conditions. The second is encoded by the lonB gene, which resides immediately upstream from lonA. Here we report that transcription of lonB occurs during sporulation under sigma(F) control and thus is restricted to the prespore compartment of sporulating cells. First, expression of a lonB-lacZ transcriptional fusion was abolished in strains unable to produce sigma(F) but remained unaffected upon disruption of the genes encoding the early and late mother cell regulators sigma(E) and sigma(K) or the late forespore regulator sigma(G). Second, the fluorescence of strains harboring a lonB-gfp fusion was confined to the prespore compartment and depended on sigma(F) production. Last, primer extension analysis of the lonB transcript revealed -10 and -35 sequences resembling the consensus sequence recognized by sigma(F)-containing RNA polymerase. We further show that the lonB message accumulated as a single monocistronic transcript during sporulation, synthesis of which required sigma(F) activity. Disruption of the lonB gene did not confer any discernible sporulation phenotype to otherwise wild-type cells, nor did expression of lonB from a multicopy plasmid. In contrast, expression of a fusion of the lonB promoter to the lonA gene severely reduced expression of the sigma(G)-dependent sspE gene and the frequency of sporulation. In confirmation of earlier observations, we found elevated levels of sigma(F)-dependent activity in a spoIIIE47 mutant, in which the lonB region of the chromosome is not translocated into the prespore. Expression of either lonB or the P(lonB)-lonA fusion from a plasmid in the spoIIIE47 mutant reduced sigma(F) -dependent activity to wild-type levels. The results suggest that both LonA and LonB can prevent abnormally high sigma(F) activity but that only LonA can negatively regulate sigma(G).

Chromosomal organization governs the timing of cell type-specific gene expression required for spore formation in Bacillus subtilis

During the early stages of spore formation in Bacillus subtilis, asymmetric division precedes chromosome segregation, such that the forespore transiently contains only about one-third of the genetic material surrounding the origin of replication. Shortly after septum formation, the transcription factor sigmaF initiates forespore-specific gene expression that is essential for the proteolytic activation of pro-sigmaE in the neighbouring mother cell. Moving the sigmaF-dependent spoIIR gene from its original origin-proximal position to an ectopic origin-distal site caused a delay in spoIIR transcription, as well as delays and reductions in the proteolytic activation of pro-sigmaE and sigmaE-directed gene expression. These defects correlated with the accumulation of disporic sporangia, thus reducing sporulation efficiency in a manner that depended upon the distance that spoIIR had been moved from the origin-proximal third of the chromosome. A significant proportion of disporic sporangia exhibited sigmaE activity in their central compartment, indicating that delays and reductions in sigmaE activation can lead to the formation of a second septum at the opposite pole. These observations support a model in which chromosomal spoIIR position temporally regulates sigmaE activation, thereby allowing for the rapid establishment of mother cell-specific gene expression that is essential for efficient spore formation. The implications of these findings for cell type-specific gene expression during the early stages of spore formation in B. subtilis are discussed.

The chromosomal location of the Bacillus subtilis sporulation gene spoIIR is important for its function

Formation of the asymmetrically located septum during sporulation of Bacillus subtilis results in enclosure of the origin-proximal 30% of the chromosome in the prespore compartment. The rest of the chromosome is then translocated into the prespore from the mother cell. Transcription of spoIIR is initiated in the prespore by RNA polymerase containing sigma(F) soon after the septum is formed. The SpoIIR protein is required for the activation of the transcription program directed by sigma(E) in the mother cell. The spoIIR locus is located at 324 degrees, near the origin of replication (0/360 degrees ). We show here that movement of spoIIR to 28 degrees had little effect on sporulation. However, movement to regions not in the origin-proximal part of the chromosome substantially reduced sporulation efficiency. At 283 degrees sporulation was reduced to less than 20% of the level obtained when spoIIR was at its natural location, and movement to 190 degrees reduced sporulation to about 6% of that level. These positional effects were also seen in the transcription of a spoIIR-lacZ fusion. In contrast, movement of other spo-lacZ fusions from 28 degrees to 190 degrees had little effect on their expression. These results suggest that spoIIR is the subject of "positional regulation," in the sense that the chromosomal position of spoIIR is important for its expression and function.

A dispensable role for forespore-specific gene expression in engulfment of the forespore during sporulation of Bacillus subtilis

During the stage of engulfment in the Bacillus subtilis spore formation pathway, the larger mother cell engulfs the smaller forespore. We have tested the role of forespore-specific gene expression in engulfment using two separate approaches. First, using an assay that unambiguously detects sporangia that have completed engulfment, we found that a mutant lacking the only forespore-expressed engulfment protein identified thus far, SpoIIQ, is able to efficiently complete engulfment under certain sporulation conditions. However, we have found that the mutant is defective, under all conditions, in the expression of the late-forespore-specific transcription factor sigma(G); thus, SpoIIQ is essential for spore production. Second, to determine if engulfment could proceed in the absence of forespore-specific gene expression, we made use of a strain in which activation of the mother cell-specific sigma factor sigma(E) was uncoupled from forespore-specific gene expression. Remarkably, engulfment occurred in the complete absence of sigma(F)-directed gene expression under the same conditions permissive for engulfment in the absence of SpoIIQ. Our results demonstrate that forespore-specific gene expression is not essential for engulfment, suggesting that the machinery used to move the membranes around the forespore is within the mother cell.

The "pro" sequence of the sporulation-specific sigma transcription factor sigma(E) directs it to the mother cell side of the sporulation septum

sigma(E), a mother cell-specific transcription factor of sporulating Bacillus subtilis, is derived from an inactive precursor protein (pro-sigma(E)). Activation of sigma(E) occurs when a sporulation-specific protease (SpoIIGA) cleaves 27 amino acids from the pro-sigma(E) amino terminus. This reaction is believed to take place at the mother cell-forespore septum. Using a chimera of pro-sigma(E) and green fluorescent protein (GFP) to visualize the intracellular location of pro-sigma(E) by fluorescence microscopy, and lysozyme treatment to separate the mother cell and forespore compartments, we determined that the pro-sigma(E)::GFP signal, localized to the forespore septum prior to lysozyme treatment, is restricted to the mother cell compartment after treatment. Thus, pro-sigma(E)::GFP had been sequestered to the mother cell side of the septum. This segregation of pro-sigma(E)::GFP, and presumably pro-sigma(E), to the mother cell is likely to be the reason why sigma(E) activity is restricted to that compartment.

Nucleosides as a carbon source in Bacillus subtilis: characterization of the drm-pupG operon

In Bacillus subtilis, nucleosides are readily taken up from the growth medium and metabolized. The key enzymes in nucleoside catabolism are nucleoside phosphorylases, phosphopentomutase, and deoxyriboaldolase. The characterization of two closely linked loci, drm and pupG, which encode phosphopentomutase (Drm) and guanosine (inosine) phosphorylase (PupG), respectively, is reported here. When expressed in Escherichia coli mutant backgrounds, drm and pupG confer phosphopentomutase and purine-nucleoside phosphorylase activity. Northern blot and enzyme analyses showed that drm and pupG form a dicistronic operon. Both enzymes are induced when nucleosides are present in the growth medium. Using mutants deficient in nucleoside catabolism, it was demonstrated that the low-molecular-mass effectors of this induction most likely were deoxyribose 5-phosphate and ribose 5-phosphate. Both Drm and PupG activity levels were higher when succinate rather than glucose served as the carbon source, indicating that the expression of the operon is subject to catabolite repression. Primer extension analysis identified two transcription initiation signals upstream of drm; both were utilized in induced and non-induced cells. The nucleoside-catabolizing system in B. subtilis serves to utilize the base for nucleotide synthesis while the pentose moiety serves as the carbon source. When added alone, inosine barely supports growth of B. subtilis. This slow nucleoside catabolism contrasts with that of E. coli, which grows rapidly on a nucleoside as a carbon source. When inosine was added with succinate or deoxyribose, however, a significant increase in growth was observed in B. subtilis. The findings of this study therefore indicate that the B. subtilis system for nucleoside catabolism differs greatly from the well-studied system in E. coli.

Bacillus subtilis spore coat

In response to starvation, bacilli and clostridia undergo a specialized program of development that results in the production of a highly resistant dormant cell type known as the spore. A proteinacious shell, called the coat, encases the spore and plays a major role in spore survival. The coat is composed of over 25 polypeptide species, organized into several morphologically distinct layers. The mechanisms that guide coat assembly have been largely unknown until recently. We now know that proper formation of the coat relies on the genetic program that guides the synthesis of spore components during development as well as on morphogenetic proteins dedicated to coat assembly. Over 20 structural and morphogenetic genes have been cloned. In this review, we consider the contributions of the known coat and morphogenetic proteins to coat function and assembly. We present a model that describes how morphogenetic proteins direct coat assembly to the specific subcellular site of the nascent spore surface and how they establish the coat layers. We also discuss the importance of posttranslational processing of coat proteins in coat morphogenesis. Finally, we review some of the major outstanding questions in the field.

Control of sigma factor activity during Bacillus subtilis sporulation

When starved, Bacillus subtilis undergoes asymmetric division to produce two cell types with different fates. The larger mother cell engulfs the smaller forespore, then nurtures it and, eventually, lyses to release a dormant, environmentally resistant spore. Driving these changes is a programme of transcriptional gene regulation. At the heart of the programme are sigma factors, which become active at different times, some only in one cell type or the other, and each directing RNA polymerase to transcribe a different set of genes. The activity of each sigma factor in the cascade is carefully regulated by multiple mechanisms. In some cases, novel proteins control both sigma factor activity and morphogenesis, co-ordinating the programme of gene expression with morphological change. These bifunctional proteins, as well as other proteins involved in sigma factor activation, and even precursors of sigma factors themselves, are targeted to critical locations, allowing the mother cell and forespore to communicate with each other and to co-ordinate their programmes of gene expression. This signalling can result in proteolytic sigma factor activation. Other mechanisms, such as an anti-sigma factor and, perhaps, proteolytic degradation, prevent sigma factors from becoming active in the wrong cell type. Accessory transcription factors modulate RNA polymerase activity at specific promoters. Negative feedback loops limit sigma factor production and facilitate the transition from one sigma factor to the next. Together, the mechanisms controlling sigma factor activity ensure that genes are expressed at the proper time and level in each cell type.

De novo fatty acid synthesis is required for establishment of cell type-specific gene transcription during sporulation in Bacillus subtilis

A hallmark of sporulation of Bacillus subtilis is the formation of two distinct cells by an asymmetric septum. The developmental programme of these two cells involves the compartmentalized activities of sigmaE in the larger mother cell and of sigmaF in the smaller prespore. A potential role of de novo lipid synthesis on development was investigated by treating B. subtilis cells with cerulenin, a specific inhibitor of fatty acid biosynthesis. These experiments demonstrated that spore formation requires de novo fatty acid synthesis at the onset of sporulation. The transcription of the sporulation genes that are induced before the formation of two cell types or that are under the exclusive control of sigmaF occurred in the absence of fatty acid synthesis, as monitored by spo-lacZ fusions. However, expression of lacZ fusions to genes that required activation of sigmaE for transcription was inhibited in the absence of fatty acid synthesis. The block in sigmaE-directed gene expression in cerulenin-treated cells was caused by an inability to process pro-sigmaE to its active form. Electron microscopy revealed that these fatty acid-starved cells initiate abnormal polar septation, suggesting that de novo fatty acid synthesis may be essential to couple the activation of the mother cell transcription factors with the formation of the differentiating cells.

Suppression of TGA mutations in the Bacillus subtilis spoIIR gene by prfB mutations

An unexpectedly high proportion of TGA nonsense mutations was obtained in a collection of chemically induced mutations in the spoIIR locus of Bacillus subtilis. Of 11 different mutations obtained, TGA mutations were found in four codons, whereas only three codons yielded missense mutations. Six suppressors of the TGA mutations were isolated, and five of the suppressing mutations were mapped to the prfB gene encoding protein release factor 2. These are the first mutations shown to map to the B. subtilis prfB locus. The sequence of the prfB gene was completed, and two revisions of the published sequence were made. The five prfB mutations also resulted in suppression of the catA86-TGA mutation to between 19 and 54% of the expression of catA86(+), compared to the readthrough level of 6% in the prfB+ strain. N-terminal sequencing of suppressed catA86-TGA-specified protein demonstrated that the amino acid inserted at UGA because of the prfB1 mutations was tryptophan.

Activation of the proprotein transcription factor pro-sigmaE is associated with its progression through three patterns of subcellular localization during sporulation in Bacillus subtilis

The activity of the sporulation transcription factor sigmaE in Bacillus subtilis is governed by an intercellular signal transduction pathway that controls the conversion of the inactive proprotein pro-sigmaE to the mature and active form of the factor. Here I use immunofluorescence microscopy to show that the activation of the proprotein is associated with its progression through three patterns of subcellular localization. In the predivisional sporangium, pro-sigmaE was found to be associated with the cytoplasmic membrane. Next, at the stage of asymmetric division, pro-sigmaE accumulated at the sporulation septum. Finally, after processing, mature sigmaE was found to be distributed throughout the mother cell cytoplasm. The results of subcellular fractionation and sedimentation in density gradients of extracts prepared from postdivisional sporangia confirmed that pro-sigmaE was chiefly present in the membrane fraction and that sigmaE was predominantly cytoplasmic, findings that suggest that the pro-amino acid sequence is responsible for the sequestration of pro-sigmaE to the membrane. The results of chemical cross-linking experiments showed that pro-sigmaE was present in a complex with its putative processing protein, SpoIIGA, or with a protein that depended on SpoIIGA. The membrane association of pro-sigmaE was, however, independent of SpoIIGA and other proteins specific to B. subtilis. Likewise, accumulation of pro-sigmaE at the septum did not depend on its interaction with SpoIIGA. Sequestration of pro-sigmaE to the membrane might serve to facilitate its interaction with SpoIIGA and may be important for preventing its premature association with core RNA polymerase. The implications of these findings for the compartmentalization of sigmaE are discussed.

Forespore expression and processing of the SigE transcription factor in wild-type and mutant Bacillus subtilis

SigmaE is a mother cell-specific transcription factor of sporulating Bacillus subtilis that is derived from an inactive precursor protein (pro-sigmaE). To examine the process that prevents sigmaE activity from developing in the forespore, we fused the sigmaE structural gene (sigE) to forespore-specific promoters (PdacF and PspoIIIG), placed these fusions at sites on the B. subtilis chromosome which translocate into the forespore either early or late, and used Western blot analysis to monitor SigE accumulation and pro-sigmaE processing. sigE alleles, placed at sites which entered the forespore early, were found to generate more protein product than the same fusion placed at a late entering site. SigE accumulation and processing in the forespore were enhanced by null mutations in spoIIIE, a gene whose product is essential for translocation of the distal portion of the B. subtilis chromosome into the forespore. In other experiments, a chimera of pro-sigmaE and green fluorescence protein, previously shown to be unprocessed if it is synthesized within the forespore, was found to be processed in this compartment if coexpressed with the gene for the pro-sigmaE-processing enzyme, SpoIIGA. The need for spoIIGA coexpression is obviated in the absence of SpoIIIE. We interpret these results as evidence that selective degradation of both SigE and SpoIIGA prevent mature sigmaE from accumulating in the forespore compartment of wild-type B. subtilis. Presumably, a gene(s) located at a site that is distal to the origin of chromosome transfer is responsible for this phenomenon when it is translocated and expressed in the forespore.

The spoIIE locus is involved in the Spo0A-dependent switch in the location of FtsZ rings in Bacillus subtilis

A switch in the location of FtsZ ring structures from medial to polar is one of the earliest morphological indicators of sporulation in Bacillus subtilis. This switch can be artificially caused during vegetative growth by induction of an active form, Sad67, of the transcription regulator, Spo0A (P. A. Levin and R. Losick, Genes Dev. 10:478-488, 1996). We have used immunofluorescence microscopy to show that the switch in FtsZ ring location during vegetative growth caused by Sad67 induction is blocked by a spoIIE deletion mutation. The spoIIE mutation also impaired polar FtsZ ring formation during sporulation. These results suggest that SpoIIE mediates the Spo0A-directed formation of polar FtsZ rings.

Bacillus subtilis Pro-sigmaE fusion protein localizes to the forespore septum and fails to be processed when synthesized in the forespore

Endospore formation in Bacillus subtilis begins with an asymmetric cell division that partitions the bacterium into mother cell and forespore compartments. Mother cell-specific gene expression is initiated by sigmaE, a transcription factor that is active only in the mother cell but which existed as an inactive precursor (pro-sigmaE) in the predivisional cell. Activation of pro-sigmaE involves the removal of 27 amino acids from its amino terminus. A chimera of pro-sigmaE and the green fluorescent protein (GFP) was expressed from either the normal sigE promoter (P(spoIIG)), which places pro-sigmaE::GFP in both mother cell and forespore compartments, or the forespore-specific promoter (P(dacF)), which produces pro-sigmaE::GFP only in the forespore compartment. The pro-sigmaE::GFP expressed from P(spoIIG), but not P(dacF), was converted to a lower-molecular-weight form by a mechanism dependent on gene products (SpoIIGA and sigmaF) that are essential for normal pro-sigmaE processing. This finding is consistent with the pro-sigmaE processing reaction occurring only in the mother cell compartment. In processing-deficient cells, pro-sigmaE::GFP was found to accumulate at the septal membrane, a location where its processing apparatus would be susceptible to triggering from the adjoining forespore.

Mutational analysis of the early forespore/mother-cell signalling pathway in Bacillus subtilis

Intercellular communication is a crucial phenomenon during spore development in Bacillus subtilis. It couples the establishment of a compartment-specific genetic program to the transcriptional activity of a sigma factor in the other compartment. It also keeps sigma factor activation in register with the morphological process. This study used directed mutagenesis to analyse the pathway that couples sigma E activation in the mother-cell to activation of sigma F in the forespore following asymmetric septation. Targets for mutagenesis in SpoIIGA (the receptor) were chosen based on the predicted topology of the protein when associated with the cell membrane. The results showed that a residue near the N terminus (D6), predicted to be exposed outside the cell, is required for receptor activity, whereas the major extracellular loop (between membrane domains IV and V) is dispensable for function. In contrast, mutations in SpoIIR (the signal) that partially blocked protein release (but not membrane translocation) had no effect on signal transduction. These results do not rule out the possibility that uncharacterized molecules intervene in the signalling pathway that establishes the mother-cell-specific developmental program during the early stage of sporulation.

Protein localization and cell fate in bacteria

A major breakthrough in understanding the bacterial cell is the discovery that the cell is highly organized at the level of protein localization. Proteins are positioned at particular sites in bacteria, including the cell pole, the incipient division plane, and the septum. Differential protein localization can control DNA replication, chromosome segregation, and cytokinesis and is responsible for generating daughter cells with different fates upon cell division. Recent discoveries have revealed that progression through the cell cycle and communication between cellular compartments are mediated by two-component signal transduction systems and signaling pathways involving transcription factor activation by proteolytic processing. Asymmetric cell division in Caulobacter crescentus and sporulation in Bacillus subtilis are used as paradigms for the control of the cell cycle and cellular morphogenesis in bacterial cells.

Disappearance of the sigma E transcription factor from the forespore and the SpoIIE phosphatase from the mother cell contributes to establishment of cell-specific gene expression during sporulation in Bacillus subtilis

We used immunofluorescence microscopy to investigate mechanisms governing the establishment of cell-specific gene transcription during sporulation in the bacterium Bacillus subtilis. The transcription factors sigma E and sigma F are synthesized shortly after the start of sporulation but do not become active in directing gene transcription until after polar division, when the activity of sigma E is confined to the mother cell and the activity of sigma F is restricted to the forespore. We show that shortly after septation, sigma E and its proprotein precursor pro-sigma E appear to be absent from the forespore and that a null mutation in spoIIIE, a gene known to be required for the translocation of a chromosome into the forespore, allows sigma E and/or pro-sigma E to persist and sigma E to become active in the forespore. These findings suggest that the loss of sigma E/pro-sigma E from the forespore contributes to the compartmentalization of sigma E-directed gene transcription. We also investigated the distribution of SpoIIE, a regulatory phosphatase required for the activation of sigma F which exhibits a bipolar pattern of localization shortly after the start of sporulation. Normally, SpoIIE rapidly disappears from the sporangium, first from the mother-cell pole and then from the forespore pole. Here we show that a null mutation in spoIIIE causes the SpoIIE phosphatase to persist at both poles. The persistence of the SpoIIE phosphatase at the mother-cell pole could explain the lack of compartmentalization of sigma F activity observed in a spoIIIE null mutant. We conclude that the establishment of cell-specific gene transcription involves the loss of sigma E/pro-sigma E from the forespore and the loss of the SpoIIE phosphatase from the mother-cell pole and that both processes are dependent upon the SpoIIIE protein.

Molecular genetics of sporulation in Bacillus subtilis

The process of sporulation in the bacterium Bacillus subtilis proceeds through a well-defined series of morphological stages that involve the conversion of a growing cell into a two-cell-chamber sporangium within which a spore is produced. Over 125 genes are involved in this process, the transcription of which is temporally and spatially controlled by four DNA-binding proteins and five RNA polymerase sigma factors. Through a combination of genetic, biochemical, and cell biological approaches, regulatory networks have been elucidated that explicitly link the activation of these sigma factors to landmark events in the course of morphogenesis and to each other through pathways of intercellular communication. Signals targeting proteins to specific subcellular localizations and governing the assembly of macromolecular structures have been uncovered but their nature remains to be determined.

Spore development in Bacillus subtilis

Cell-cell and starvation signals are funneled through the phosphorelay to initiate sporulation by activating the transcription regulator SpoOA. Activation of SpoOA leads to synthesis of the transcription factors sigmaF and sigmaE. Substantial advances have been made in our understanding of the signal circuitry of the phosphorelay and of the cell-type-specific activation of the sigma factors.