Mother Cell Compartment Research Articles

A feedback loop regulates the switch from one sigma factor to the next in the cascade controlling Bacillus subtilis mother cell gene expression.

Regulation of gene expression in the mother cell compartment of sporulating Bacillus subtilis involves sequential activation and inactivation of several transcription factors. Among them are two sigma factors, sigmaE and sigmaK, and a DNA-binding protein, SpoIIID. A decrease in the level of SpoIIID is thought to relieve its repressive effect on transcription by sigmaK RNA polymerase of certain spore coat genes. Previous studies showed that sigmaK negatively regulates the level of spoIIID mRNA. Here, it is shown that sigmaK does not affect the stability of spoIIID mRNA. Rather, sigmaK appears to negatively regulate the synthesis of spoIIID mRNA by accelerating the disappearance of sigmaE RNA polymerase, which transcribes spoIIID. As sigmaK begins to accumulate by 4 h into sporulation, the sigmaE level drops rapidly in wild-type cells but remains twofold to fivefold higher in sigK mutant cells during the subsequent 4 h. In a strain engineered to produce sigmaK 1 h earlier than normal, twofold less sigmaE than that in wild-type cells accumulates. SigmaK did not detectably alter the stability of sigmaE in pulse-chase experiments. However, beta-galactosidase expression from a sigE-lacZ transcriptional fusion showed a pattern similar to the level of sigmaE protein in sigK mutant cells and cells prematurely expressing sigmaK. These results suggest that the appearance of sigmaK initiates a negative feedback loop controlling not only transcription of spoIIID, but the entire sigmaE regulon, by directly or indirectly inhibiting the transcription of sigE.

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.

Analysis of cryIAa expression in sigE and sigK mutants of Bacillus thuringiensis.

The sigE and sigK genes, encoding the sporulation-specific sigma factors sigma 35 and sigma 28 of Bacillus thuringiensis, were each disrupted by inserting a gene conferring resistance to kanamycin into their coding sequences. The B. thuringiensis SigE- and sigK- mutant strains were blocked at different sporulation stages and were unable to sporulate. The SigE-strain was blocked at stage II of sporulation, whereas the SigK- strain was blocked at stage IV. The expression of a cryIAa'-'lacZ transcriptional fusion was analysed in these genetic backgrounds and it was found that both sigma factors are involved in the in vivo transcription of this gene. However, the SigK- strain harbouring the cryIAa gene produced amounts of toxin similar to those produced by the B. thuringiensis Spo+ strain. The toxins accumulated in the mother cell compartment to form a crystal inclusion which remained encapsulated within the cell wall. Thus, transcription from the sigma E-dependent promoter alone (Bt I promoter) is sufficient to support high levels of toxin production in B. thuringiensis.

Bacterial differentiation: Sizing up sporulation

New results on Bacillus subtilis sporulation suggest that size differences between the post-septation compartments trigger differential gene expression, which is then coordinated by communication between the nascent mother cell and forespore compartments.

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.

Identification of a gene, spoIIR, that links the activation of sigma E to the transcriptional activity of sigma F during sporulation in Bacillus subtilis.

Sporulation of Bacillus subtilis requires the coordinated expression of two separate developmental programs in the mother cell and forespore compartments by sigma E and sigma F, respectively. This coordination is maintained through the action of cross-regulatory factors that control the activities of the various sporulation-specific sigma factors. We present here the isolation and characterization of one such cross-regulatory factor, the spoIIR gene. Using a genetic screen, we have isolated four mutant alleles of spoIIR. These mutants were isolated as expressing sigma F-directed genes but not sigma E-directed genes. The block in sigma E-directed gene expression in spoIIR mutants was caused by an inability to process pro-sigma E to its active form. Cloning and characterization of the spoIIR gene determined that its transcription is directed by sigma F. Thus, SpoIIR is required for linking the activation of sigma E to the activation of sigma F and coordinating the initiation of the two developmental programs required to form a spore.

Cloning and characterization of a Bacillus thuringiensis homolog of the spoIIID gene from Bacillus subtilis

The SpoIIID protein of Bacillus subtilis (Bs) is a small DNA-binding protein that is essential for gene expression of the mother cell compartment during sporulation. We have cloned a DNA fragment from Bacillus thuringiensis (Bt) that showed a specific hybridization with the Bs spoIIID gene. Sequence analysis found an open reading frame encoding 90 amino acids (aa), which are 89% identical to the deduced aa sequence of Bs spoIIID. Upstream from the transcription start point ( tsp), a nucleotide sequence highly homologous to the consensus sequence motif for the σ 35-recognized promoters was found. Northern blot analysis has indicated that the expression of the gene is induced only at the midsporulation stage, and that the gene constitutes an operon with a downstream gene, mreB. The Bs strain carrying the spoIIIDΔerm or spoIIID83 mutation completely restored sporulation ability upon introduction of the spoIIID homologous gene from Bt. These results strongly suggest that the gene we have cloned is a Bt homolog of spoIIID.

Sporulation protein SpoIVFB from Bacillus subtilis enhances processing of the sigma factor precursor Pro-sigma K in the absence of other sporulation gene products.

Processing of inactive pro-sigma K to active sigma K in the mother cell compartment of sporulating Bacillus subtilis is governed by a signal transduction pathway emanating from the forespore and involving SpoIVFB in the mother cell. Coexpression of spoIVFB and sigK (encoding pro-sigma K) genes in growing B. subtilis or Escherichia coli enhanced pro-sigma K processing in the absence of other sporulation-specific gene products. The simplest explanation of these results is that SpoIVFB is a protease that processes pro-sigma K.

Cloning and sequencing of a B. subtilis sigmaF dependent gene from B. megaterium

A promoter — monocistronic structural gene complex from genomic DNA of Bacillus megaterium has been isolated and sequenced. The activity of the promoter during sporulation was measured in B. subtilis using a fusion with the xylE gene of Pseudomonas putida which codes for a catechol-2,3-dioxygenase. From the time of activation in sporulating cells and the activity in a set of defined B. subtilis sporulation mutants we conclude that the promoter requires an active sigmaF-factor of RNA-polymerase. Since this sigma-factor is active only in forespores and not in the mothercell compartment it is likely that we have identified a forespore specific gene of B. megaterium. Its function is still unknown.

Regulation of the Transcription of a Cluster of Bacillus subtilis Spore Coat Genes

The pattern of transcription has been examined for a cluster of genes encoding polypeptides some or all of which are assembled into a cross-linked component of the Bacillus subtilis spore coat. Three promoters, designated PVWX, PX, PYZ, were indicated by reverse transcriptase mapping. On the basis of Norther hybridization, it appeared that the cotV, W and X genes were transcribed as a polycistronic mRNA from PVWX as well as a monocistronic cotX mRNA from PX. The cotY and cotZ genes are cotranscribed from the PYZ promoter with a smaller cotY mRNA resulting from premature termination or RNA processing. All four transcripts were synthesized late during sporulation and were not produced in mutants lacking sigma K, which directs RNA polymerase to transcribe genes in the mother-cell compartment of sporulating cells. The DNA-binding protein GerE, which affects transcription of many genes in the mother cell during the late stages of sporulation, was also shown to be involved. There was essentially no cotX mRNA in a gerE mutant and the amounts of cotVWX, cotYZ and cotY mRNAs were somewhat reduced. In vitro run-off transcription studies with σK RNA polymerase and GerE confirmed the presence of the three promoters, and directly showed that GerE was necessary for transcription from PX as well as enhanced transcription from the PVWX and PYZ promoters. The DNase I footprints of GerE for all three promoters were immediate upstream of the -35 regions. These GerE binding sites were compared to those in other GerE-responsive promoters and a large consensus sequence for GerE binding was recognized. This complex transcriptional pattern of the cotVWXYZ cluster is probably necessary to ensure that an optimal amount of each protein is made for the assembly of the spore coat.

Cloning, DNA Sequence, Functional Analysis and Transcriptional Regulation of the Genes Encoding Dipicolinic Acid Synthetase Required for Sporulation in Bacillus subtilis

Dipicolinic acid (DPA) is a small polar molecule that accumulates to high concentrations in bacterial endospores, and is thought to play a role in spore heat resistance, or the maintenance of heat resistance. Previous work has shown that mutations in the spo V F locus of Bacillus subtilis prevent the formation of DPA, and give rise to heat-sensitive spores. Addition of exogenous DPA during spore development led to the restoration of heat resistance. This suggested that the spo V F locus encoded dipicolinic acid synthetase, the enzyme thought to catalyse the single reaction needed to synthesise DPA from dihydroxydipicolinic acid, an intermediate in the lysine biosynthetic pathway. We have now cloned and sequenced the spo V F locus of Bacillus subtilis and show that it comprises two coordinately regulated genes, now designated dpaA and dpaB. Expression of fragments of the dpa operon in Escherichia coli has shown that the two gene products together specify DPA synthetase activity. The promoter of the dpa operon, which lies just upstream of the first gene, has been identified by primer extension analysis. Sequences in this region show strong sequence similarity to several promoters recognized by the σ K form of RNA polymerase. Transcription from this promoter was detected four hours after the onset of sporulation, at about the same time that σ K activity is known to appear. Furthermore, transcription was abolished by mutations in a series of genes that are known to be required for the synthesis of active σ K. These results are in accordance with previous work indicating that DPA synthetase activity was present only during the late stages of sporulation and specifically in the mother cell compartment. Transcription was enhanced by a gerE mutation, indicating that, like the previously described cotA gene, spo V F is negatively regulated by GerE. The mother-cell-specific synthesis of an enzyme responsible for a compound that accumulates to high concentrations in the prespore raises interesting questions about intercellular transport mechanisms.

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 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.

Mutagenesis and mapping of the gene for a sporulation-specific penicillin-binding protein in Bacillus subtilis.

Penicillin-binding protein (PBP) 5* is produced by Bacillus subtilis only during sporulation and is believed to be required for synthesis of the peptidoglycan-like cortex layer of the spore. The structural gene (dacB) for PBP 5* was insertionally mutagenized by integration of a plasmid bearing an internal fragment of the gene, and the phenotype of the null mutant was characterized. The mutant had no apparent vegetative growth or germination defect, but it produced extremely heat-sensitive spores. This property is consistent with a defect in the amount or assembly of the cortex and supports the hypothesis that PBP 5* is required for synthesis of this structure. Analysis of the progeny after spontaneous excision of the integrated plasmid led to the conclusion that expression of the dacB gene was required only in the mother cell compartment during sporulation, which is also consistent with a role for PBP 5* in cortex synthesis and with its location in the outer forespore membrane. Genetic mapping located dacB midway between aroC (206 degrees) and lys (210 degrees) on the B. subtilis chromosome. This is a region where there are no other known spo, ger, or PBP genes. In related studies, we found that a null mutant of dacA, the structural gene for vegetative PBP 5, produced normal heat-resistant spores, which suggests that this PBP is not essential for cortex synthesis. In addition, a candidate for another sporulation-specific PBP was revealed on gels at approximately the same position as PBP 5*. The two PBPs could be distinguished by immunoassays.

Use of a new integrational vector to investigate compartment-specific expression of the Bacillus subtilis spollM gene

The product of the spollM gene of Bacillus subtilis is required for complete septum migration and forespore engulfment during sporulation. To investigate whether expression of spollM is required in the forespore compartment of the sporangium, we have constructed a new integrational vector, pKSV7, which contains temperature-sensitive replication functions derived from pE194ts. The presence of the conditionally defective replication origin greatly stimulates plasmid excision when sporulation occurs at the permissive temperature. This facilities the use of a genetic technique employed by Illing et al [1] to distinguish genes whose expression must occur in the forespore from genes that may be expressed exclusively in the mother cell compartment. The results of the integration/excision experiments using pKSV7 support the conclusion that spollM must be expressed in the mother cell. The conditional integration analysis of porespore and mother cell fractions suggests that spollM is also expressed in the mother cell. The conditional integration vector pKSV7 replicates at high copy number in E coli and allows the identification of inserts in the polylinker cluster by disruption of α-complementation and thus should be useful other kinds of genetic manipulations in B subtilis.

Evidence that recombination between reiterated sequences in the Bacillus subtilis chromosome does not occur via unequal crossing over

An experimental system was designed to permit the detection of recombination events occurring via unequal crossing over between sister bacterial chromosomes in Bacillus subtilis. It exploits the fact that during spore development, genetic and metabolic cooperation occurs between two different cell types, only one of which survives. During the early stages of sporulation, the two chromosomes of the developing sporangiole lie in the same cell and recombination between them is possible, in principle. Internal duplications flanking a selectable antibiotic-resistance gene have been introduced into the spoIIIC, spoIVA and spoVJ genes, whose correct expression in the mother cell (non-surviving compartment) is necessary for completion of spore development. After incubation in a sporulation-inducing medium in the absence of selective pressure, these strains sporulate at a low frequency and up to 30% of the progeny are Spo-. They result from mosaic sporangioles, in which only the chromosome segregated into the mother cell compartment of the developing sporangiole contains a reconstituted spo gene. In mosaic sporangioles generated by unequal crossing over between sister bacterial chromosomes, the insertionally inactivated spo gene, segregated into the pre-spore compartment, would carry an extra copy of the duplication initially present. Analysis of the products of 124 independent recombination events giving rise to mosaic sporangioles provided no evidence for the occurrence of unequal crossing over.

Establishment of cell-specific transcription during sporulation in Bacillus subtilis.

One of the most intriguing questions posed by bacterial spore formation concerns the establishment of cell-specific gene expression in the prespore and mother cell. Recent results now suggest that sigma factors, in addition to their temporal roles in the control of gene expression, may also be the key determinants of differential gene expression during sporulation in Bacillus subtilis. The genes encoding two sporulation-specific sigma factors, sigma E and sigma F, are expressed soon after the initiation of sporulation, before the formation of the spore septum that separates the prespore and mother cell compartments. It now appears that sigma E and sigma F direct transcription only after septation and then in a specific cell type, suggesting that the segregation of the sigma activities after septation is a key event in the establishment of differential gene expression. The mechanism responsible for this segregation is complex, involving at least seven other gene products. We discuss possible models for the interactions between the sigma factors and the establishment of cell-specific transcription.

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 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.

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.