Expression of the Bacillus subtilis spoIVB gene is under dual sigma F/sigma G control

Regulation of pro-σK activation: a key checkpoint in Bacillus subtilis sporulation

The Gram-positive bacterium Bacillus subtilis initiates the sporulation process under conditions of nutrient limitation. Here, we review related work in this field, focusing on the protein processing of the pro-σ^K activation. The purpose of this review is to illustrate the mechanism of pro-σ^K activation and provide structural insights into the regulation of spore production. Sporulation is not only important in basic science but also provides mechanistic insight for bacterial control in applications in, e.g., food industry.

Solution Structure of SpoIVB Reveals Mechanism of PDZ Domain-Regulated Protease Activity

Intramembrane proteases hydrolyze peptide bonds within the cell membrane as the decision-making step of various signaling pathways. Sporulation factor IV B protease (SpoIVB) and C-terminal processing proteases B (CtpB) play central roles in cellular differentiation via regulated intramembrane proteolysis (RIP) process which activates pro-σ^K processing at the σ^K checkpoint during spore formation. SpoIVB joins CtpB in belonging to the widespread family of PDZ-proteases, but much remains unclear about the molecular mechanisms and structure of SpoIVB. In this study, we expressed inactive SpoIVB (SpoIVB^S378A) fused with maltose binding protein (MBP)-tag and obtained the solution structure of SpoIVB^S378A from its small angle X-ray scattering (SAXS) data. The fusion protein is more soluble, stable, and yields higher expression compared to SpoIVB without the tag. MBP-tag not only facilitates modeling of the structure in the SAXS envelope but also evaluates reliability of the model. The solution structure of SpoIVB^S378A fits closely with the experimental scattering data (χ²= 1.76). Comparing the conformations of PDZ-proteases indicates that SpoIVB adopts a PDZ-protease pattern similar to the high temperature requirement A proteases (HtrAs) rather than CtpB. We not only propose that SpoIVB uses a more direct and simple way to cleave the substrates than that of CtpB, but also that they work together as signal amplifiers to activate downstream proteins in the RIP pathway.

Regulated proteolysis in bacterial development

Bacteria use proteases to control three types of events temporally and spatially during the processes of morphological development. These events are the destruction of regulatory proteins, activation of regulatory proteins, and production of signals. While some of these events are entirely cytoplasmic, others involve intramembrane proteolysis of a substrate, transmembrane signaling, or secretion. In some cases, multiple proteolytic events are organized into pathways, for example turnover of a regulatory protein activates a protease that generates a signal. We review well-studied and emerging examples and identify recurring themes and important questions for future research. We focus primarily on paradigms learned from studies of model organisms, but we note connections to regulated proteolytic events that govern bacterial adaptation, biofilm formation and disassembly, and pathogenesis.

Perturbations to engulfment trigger a degradative response that prevents cell-cell signalling during sporulation in Bacillus subtilis

During sporulation in Bacillus subtilis, the mother cell membranes migrate around the forespore in a phagocytic-like process called engulfment. Developmental gene expression requires the successful completion of this key morphological event. Here we show that perturbations to engulfment block the accumulation of proteins secreted into the space between the mother cell and forespore membranes. Our data support a model in which engulfment defects cause the proteolytic clearance of these secreted proteins. Importantly, we show that this degradative response is reversible; once proper engulfment is restored, secreted proteins again accumulate. In particular, we have found that the forespore signalling protein SpoIVB fails to accumulate when engulfment is impaired and, as a result, late mother cell gene expression under the control of sigma(K) is blocked. If engulfment is restored, SpoIVB accumulates and cell-cell signalling resumes. Thus, this degradative pathway functions like a developmental checkpoint ensuring that mother cell gene expression does not commence unless morphogenesis proceeds normally.

Impact of membrane fusion and proteolysis on SpoIIQ dynamics and interaction with SpoIIIAH

The onset of engulfment-dependent gene expression during Bacillus subtilis sporulation requires the forespore membrane protein SpoIIQ, which recruits mother cell proteins involved in late gene expression to the outer forespore membrane. Engulfment activates the late forespore transcription factor sigmaG, which produces high levels of the secreted SpoIVB protease that is required for activation of the late mother cell transcription factor sigmaK. Engulfment also triggers the proteolytic cleavage of SpoIIQ, an event that depends on the SpoIVB protease but not on sigmaG activity. To determine if SpoIVB directly cleaves SpoIIQ and to determine if this event participates in the onset of late gene expression, we purified SpoIVB, SpoIIQ, and SpoIVFA (another SpoIVB substrate). SpoIVB directly cleaved SpoIIQ at the same site in vitro and in vivo and cleaved SpoIVFA in at least three different locations. SpoIIQ cleavage depends on membrane fusion, but not on sigmaG activity, suggesting that the ability of SpoIVB to cleave substrates is regulated by membrane fusion. We isolated SpoIVB-resistant SpoIIQ proteins by random mutagenesis of codons at the cleavage site and demonstrated that SpoIIQ processing is dispensable for spore formation and for activation of late forespore and mother cell gene expression. Fluorescence recovery after photobleaching analysis demonstrated that membrane fusion releases SpoIIQ from an immobile complex, an event that could allow SpoIVB to cleave SpoIIQ. We propose that this membrane fusion-dependent reorganization in the complex, rather than SpoIIQ proteolysis itself, is necessary for the onset of late transcription.

Engulfment-regulated proteolysis of SpoIIQ: evidence that dual checkpoints control sigma activity

During Bacillus subtilis sporulation, the engulfment checkpoint is thought to directly regulate late forespore transcription but to indirectly regulate late mother cell transcription, via the sigmaG-produced protease SpoIVB. We here demonstrate that SpoIIQ is subject to sigmaG-independent, but engulfment-dependent, proteolysis that depends on SpoIVB. Thus, SpoIVB produced before engulfment supports some SpoIVB-dependent events, suggesting that its activity or access to substrates must be regulated by engulfment. Furthermore, a mutation (bofA) that allows sigmaK to be active without sigmaG does not allow sigmaK activity in engulfment mutants, although the pro-sigmaK processing enzyme (SpoIVFB) is localized to the septum in engulfment mutants, suggesting that engulfment comprises a second checkpoint for sigmaK Finally, we find that SpoIIQ and another protein required for sigmaG activity (SpoIIIAH), which directly interact and assemble helical structures around the forespore, recruit the sigmaK-processing enzyme SpoIVFB to the forespore and these structures. We suggest that these foci serve a synapse-like role, allowing engulfment to simultaneously control both sigmaG and sigmaK, and integrating multiple checkpoints and signalling pathways.

Genome-wide analysis of temporally regulated and compartment-specific gene expression in sporulating cells of Bacillus subtilis

Temporal and compartment-specific control of gene expression during sporulation inBacillus subtilisis governed by a cascade of four RNA polymerase subunits.σFin the prespore andσEin the mother cell control early stages of development, and are replaced at later stages byσGandσK, respectively. Ultimately, a comprehensive description of the molecular mechanisms underlying spore morphogenesis requires the knowledge of all the intervening genes and their assignment to specific regulons. Here, in an extension of earlier work, DNA macroarrays have been used, and members of the four compartment-specific sporulation regulons have been identified. Genes were identified and grouped based on: i) their temporal expression profile and ii) the use of mutants for each of the four sigma factors and abofAallele, which allowsσKactivation in the absence ofσG. As a further test, artificial production of active alleles of the sigma factors in non-sporulating cells was employed. A total of 439 genes were found, including previously characterized genes whose transcription is induced during sporulation: 55 in theσFregulon, 154σE-governed genes, 113σG-dependent genes, and 132 genes underσKcontrol. The results strengthen the view that the activities ofσF,σE,σGandσKare largely compartmentalized, both temporally as well as spatially, and that the major vegetative sigma factor (σA) is active throughout sporulation. The results provide a dynamic picture of the changes in the overall pattern of gene expression in the two compartments of the sporulating cell, and offer insight into the roles of the prespore and the mother cell at different times of spore morphogenesis.

The PDZ domain of the SpoIVB transmembrane signaling protein enables cis-trans interactions involving multiple partners leading to the activation of the pro-sigmaK processing complex in Bacillus subtilis

In sporulating cells of Bacillus subtilis, the serine peptidase SpoIVB is the essential component of a transmembrane signaling cascade between the two intracellular compartments (forespore and mother cell) that leads to activation of the sigmaK transcription factor in the mother cell chamber. This regulatory process, referred to as the sigmaK checkpoint, is essential for ensuring proper development of the spore and introduces an appropriate level of fidelity to the developmental process. This work unravels the signaling process and establishes how SpoIVB interacts with other protein partners in the sigmaK checkpoint. SpoIVB is synthesized as a zymogen that is autoproteolytically activated and carries a PDZ domain that is responsible for at least three distinct binding reactions, a phenomenon not previously demonstrated for an individual PDZ domain. First, binding to the SpoIVB NH2 terminus to maintain the protein in its zymogen form. Second, following secretion across a spore membrane, binding in trans to the COOH terminus of another SpoIVB molecule. Binding in trans facilitates the first cleavage event of SpoIVB near the NH2 terminus releasing it from the inner forespore membrane. We show that at least two further cis cleavage events occur at specific sites near the NH2 terminus after which the PDZ domain targets SpoIVB to the pro-sigmaK processing complex in the outer forespore membrane. Specifically, SpoIVB binds to the COOH terminus of BofA. In turn, this allows SpoIVB to cleave the COOH terminus of SpoIVFA an event pivotal to activating the SpoIVFB zinc metalloprotease by disruption of the heteroligomeric pro-sigmaK complex.

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.

SpoIVB-mediated cleavage of SpoIVFA could provide the intercellular signal to activate processing of Pro-sigmaK in Bacillus subtilis

SpoIVB is the critical determinant for intercompartmental signalling of pro-sigmaK processing during sporulation in Bacillus subtilis. We show here that the SpoIVB serine peptidase can cleave the SpoIVFA protein, which is one component of the pro-sigmaK processing complex. SpoIVFA has been shown elsewhere (Rudner, D.Z., and Losick, R., 2002, Genes Dev 16: 1007-1018) to tether BofA and SpoIVFB in a membrane-embedded heteroligomeric complex in which BofA directly inhibits the activity of SpoIVFB. Cleavage of SpoIVFA would provide the necessary signal to dissolve this complex and release BofA-mediated inhibition on the zinc metalloprotease, SpoIVFB, that is responsible for cleaving pro-sigmaK to its mature form. We also show that the SpoIVB PDZ domain is required for self-recognition and trans cleavage of SpoIVB and is probably also used to target an internal motif within the C-terminal region of SpoIVFA exposed in the space between the inner and outer forespore membranes. This work reveals the mechanism of intercompartmental signalling and provides a unified model as to how sigmaK-directed gene expression in the mother cell is co-ordinated with events in the forespore chamber.

Forespore signaling is necessary for pro-sigmaK processing during Bacillus subtilis sporulation despite the loss of SpoIVFA upon translational arrest

The sigmaK checkpoint coordinates gene expression in the mother cell with signaling from the forespore during Bacillus subtilis sporulation. The signaling pathway involves SpoIVB, a serine peptidase produced in the forespore, which is believed to cross the innermost membrane surrounding the forespore and activate a complex of proteins, including BofA, SpoIVFA, and SpoIVFB, located in the outermost membrane surrounding the forespore. Activation of the complex allows proteolytic processing of pro-sigmaK, and the resulting sigmaK RNA polymerase transcribes genes in the mother cell. To investigate activation of the pro-sigmaK processing complex, the level of SpoIVFA in extracts of sporulating cells was examined by Western blot analysis. The SpoIVFA level decreased when pro-sigmaK processing began during sporulation. In extracts of a spoIVB mutant defective in forespore signaling, the SpoIVFA level failed to decrease normally and no processing of pro-sigmaK was observed. Although these results are consistent with a model in which SpoIVFA inhibits processing until the SpoIVB-mediated signal is received from the forespore, we discovered that loss of SpoIVFA was insufficient to allow processing under certain conditions, including static incubation of the culture and continued shaking after the addition of inhibitors of oxidative phosphorylation or translation. Under these conditions, loss of SpoIVFA was independent of spoIVB. The inability to process pro-sigmaK under these conditions was not due to loss of SpoIVFB, the putative processing enzyme, or to a requirement for ongoing synthesis of pro-sigmaK. Rather, it was found that the requirements for shaking of the culture, for oxidative phosphorylation, and for translation could be bypassed by mutations that uncouple processing from dependence on forespore signaling. This suggests that ongoing translation is normally required for efficient pro-sigmaK processing because synthesis of the SpoIVB signal protein is needed to activate the processing complex. When translation is blocked, synthesis of SpoIVB ceases, and the processing complex remains inactive despite the loss of SpoIVFA. Taken together, the results suggest that SpoIVB signaling activates the processing complex by performing another function in addition to causing loss of SpoIVFA or by causing loss of SpoIVFA in a different way than when translation is blocked. The results also demonstrate that the processing machinery can function in the absence of translation or an electrochemical gradient across membranes.

Analysis of promoter recognition in vivo directed by sigma(F) of Bacillus subtilis by using random-sequence oligonucleotides

Formation of spores from vegetative bacteria by Bacillus subtilis is a primitive system of cell differentiation. Critical to spore formation is the action of a series of sporulation-specific RNA polymerase sigma factors. Of these, sigma(F) is the first to become active. Few genes have been identified that are transcribed by RNA polymerase containing sigma(F) (E-sigma(F)), and only two genes of known function are exclusively under the control of E-sigma(F), spoIIR and spoIIQ. In order to investigate the features of promoters that are recognized by E-sigma(F), we studied the effects of randomizing sequences for the -10 and -35 regions of the promoter for spoIIQ. The randomized promoter regions were cloned in front of a promoterless copy of lacZ in a vector designed for insertion by double crossover of single copies of the promoter-lacZ fusions into the amyE region of the B. subtilis chromosome. This system made it possible to test for transcription of lacZ by E-sigma(F) in vivo. The results indicate a weak sigma(F)-specific -10 consensus, GG/tNNANNNT, of which the ANNNT portion is common to all sporulation-associated sigma factors, as well as to sigma(A). There was a rather stronger -35 consensus, GTATA/T, of which GNATA is also recognized by other sporulation-associated sigma factors. The looseness of the sigma(F) promoter requirement contrasts with the strict requirement for sigma(A)-directed promoters of B. subtilis. It suggests that additional, unknown, parameters may help determine the specificity of promoter recognition by E-sigma(F) in vivo.

The PDZ domain of the SpoIVB serine peptidase facilitates multiple functions

During spore formation in Bacillus subtilis, the SpoIVB protein is a critical component of the sigma(K) regulatory checkpoint. SpoIVB has been shown to be a serine peptidase that is synthesized in the spore chamber and which self-cleaves, releasing active forms. These forms can signal proteolytic processing of the transcription factor sigma(K) in the outer mother cell chamber of the sporulating cell. This forms the basis of the sigma(K) checkpoint and ensures accurate sigma(K)-controlled gene expression. SpoIVB has also been shown to activate a second distinct process, termed the second function, which is essential for the formation of heat-resistant spores. In addition to the serine peptidase domain, SpoIVB contains a PDZ domain. We have altered a number of conserved residues in the PDZ domain by site-directed mutagenesis and assayed the sporulation phenotype and signaling properties of mutant SpoIVB proteins. Our work has revealed that the SpoIVB PDZ domain could be used for up to four distinct processes, (i) targeting of itself for trans proteolysis, (ii) binding to the protease inhibitor BofC, (iii) signaling of pro-sigma(K) processing, and (iv) signaling of the second function of SpoIVB.

BofC negatively regulates SpoIVB-mediated signalling in the Bacillus subtilis sigmaK-checkpoint

The BofC protein acts negatively on intercompartmental signalling of pro-sigma(K) processing in the sigma(K)-checkpoint of Bacillus subtilis. Signalling is brought about by the SpoIVB protein, which is synthesized in the forespore and initiates proteolytic processing of pro-sigmaK to its mature and active form in the opposed mother cell chamber of the developing cell. We have shown here that BofC, like SpoIVB, is secreted across the inner forespore membrane and, from the analysis of a bofC deletion and insertion mutant, is likely to interact with SpoIVB. In the absence of BofC, the amount of SpoIVB found in sporulating cells is substantially reduced, although SpoIVB is still able to activate proteolysis of pro-sigma(K). Conversely, in the absence of SpoIVB, the levels of BofC accumulate suggesting that the fate of each molecule is dependent upon their mutual interaction. Our results suggest that BofC could maintain SpoIVB in a stable but inactive form. Supporting this, we have shown that overproduction of BofC inhibits SpoIVB autoproteolysis and leads to a delay in proteolytic cleavage of pro-sigma(K). Based on our work here, we have proposed a model for BofC's functional role in intercompartmental signalling.

Proteolysis of SpolVB is a critical determinant in signalling of Pro-sigmaK processing in Bacillus subtilis

SpoIVB is essential for intercompartmental signalling in the sigma(K)-checkpoint of Bacillus subtilis. SpoIVB is synthesized in the spore chamber and is the signal which activates proteolytic processing of pro-sigma(K) to its mature and active form sigma(K). We show here that SpoIVB is a serine peptidase of the SA clan. Expression of SpoIVB in Escherichia coli has shown that SpoIVB is able to self-cleave into at least three discrete products, and in vitro studies have shown cleavage in trans. Autoproteolysis of SpoIVB is tightly linked to the initiation of the two developmental functions of this protein, signalling of pro-sigma(K) processing and a yet, uncharacterized, second function which is essential for the formation of heat-resistant spores. In B. subtilis, SpoIVB is synthesized as a zymogen and is subject to two levels of proteolysis. First, autoproteolysis generating intermediate products, at least one of which is proposed to be the active form, followed by processing by one or more enzymes to smaller species. This could provide a mechanism for switching off the active SpoIVB intermediate(s) and suggests a similarity to other proteolytic cascades such as those found in blood coagulation.

BofC encodes a putative forespore regulator of the Bacillus subtilis sigma K checkpoint

A mutation, bofC1, that restores sigma K activation in Bacillus subtilis strains unable to produce active sigma G has been identified. This mutation defines a new sporulation gene, bofC, that has been cloned and sequenced and encodes a 19 kDa protein. bofC is transcribed in the forespore by RNA polymerase associated with the transcription factors sigma F (E sigma F) and sigma G (E sigma G). BofC acts negatively on SpoIVB and the results described suggest that BofC regulates SpoIVB activity and its intercompartmental signalling role in the sigma K checkpoint.