Purification, Kinetic Properties, and Intracellular Concentration of SpoIIE, an Integral Membrane Protein That Regulates Sporulation in Bacillus subtilis

SpoIIE is a bifunctional protein which controls sigmaF activation and formation of the asymmetric septum in sporulating Bacillus subtilis. The spoIIE gene of B. subtilis has now been overexpressed in Escherichia coli, and SpoIIE has been purified by anion-exchange chromatography and affinity chromatography. Kinetic studies showed that the rate of dephosphorylation of SpoIIAA-P by purified SpoIIE in vitro was 100 times greater, on a molar basis, than the rate of phosphorylation of SpoIIAA by SpoIIAB. The intracellular concentrations of SpoIIE and SpoIIAB were measured by quantitative immunoblotting between 0 and 4 h after the beginning of sporulation. The facts that these concentrations were very similar at hour 2 and that SpoIIE could be readily detected before asymmetric septation suggest that SpoIIE activity may be strongly regulated.     

The Bacillus SpoIIGA protein is targeted to sites of spore septum formation in a SpoIIE-independent manner

The process of bacterial cell division involves the assembly of a complex of proteins at the site of septation that probably provides both the structural and the cytokinetic functions required for elaboration and closure of the septal annulus. During sporulation in Bacillus subtilis , this complex of proteins is modified by the inclusion of a sporulation-specific protein, SpoIIE, which plays a direct role in gene regulation and also has a genetically separable role in determining the gross structural properties of the specialized sporulation septum. We demonstrate by both green fluorescent protein (GFP) fusions and indirect immunofluorescence microscopy that SpoIIGA, a protein required for proteolytic cleavage of pro-σ^E, is also targeted to the sporulation septum. Septal localization of SpoIIGA–GFP occurred even in the structurally abnormal septum formed by a SpoIIE null mutant. We also report the isolation of a spoIIGA homologue from Bacillus megaterium , a species in which the cells are significantly larger than those of B . subtilis . We have exploited the physical dimensions of the B . megaterium sporangium, in conjunction with wide-field deconvolution microscopy, to construct three-dimensional projections of sporulating cells. These projections indicate that SpoIIGA–GFP is initially localized in an annulus at the septal periphery and is only later localized uniformly throughout the septa. Localization was also detected in a B . subtilis spo0H null strain that fails to construct a spore septum. We propose that SpoIIGA is sequestered in the septum by an interaction with components of the septation machinery and that this interaction begins before the construction of the asymmetric septum.     

Use of lacZ gene fusions to determine the dependence pattern of the sporulation gene spoIID in spo mutants of Bacillus subtilis

The spoIID gene, which is involved in Bacillus subtilis sporulation, was fused to the beta-galactosidase gene, lacZ, of Escherichia coli so that the expression of beta-galactosidase would be under the control of the spoIID locus. When the fused product was inserted into the B. subtilis chromosome, production of beta-galactosidase indicated that the spoIID gene was expressed 1.5 h after the start of sporulation. When the spoIID::lacZ fusion was inserted into the chromosome of sporulation mutants, all strains carrying spo0 lesions and those with mutations in spoIIA, spoIIE and spoIIG loci failed to make beta-galactosidase. The proposed provisional order of expression of operons governing stage II is spoIIA----[spoIIG, spoIIE]----[spoIID, spoIIB, spoIIF].     

SpoIIQ anchors membrane proteins on both sides of the sporulation septum in Bacillus subtilis

During the process of spore formation in Bacillus subtilis, many membrane proteins localize to the polar septum where they participate in morphogenesis and signal transduction. The forespore membrane protein SpoIIQ plays a central role in anchoring several mother-cell membrane proteins in the septal membrane. Here, we report that SpoIIQ is also responsible for anchoring a membrane protein on the forespore side of the sporulation septum. Co-immunoprecipitation experiments reveal that SpoIIQ resides in a complex with the polytopic membrane protein SpoIIE. During the early stages of sporulation, SpoIIE participates in the switch from medial to polar division and co-localizes with FtsZ at the polar septum. We show that after cytokinesis, SpoIIE is released from the septum and transiently localizes to all membranes in the forespore compartment. Upon the initiation of engulfment, it specifically re-localizes to the septal membrane on the forespore side. Importantly, the re-localization of SpoIIE to the engulfing septum requires SpoIIQ. These results indicate that SpoIIQ is required to anchor membrane proteins on both sides of the division septum. Moreover, our data suggest that forespore membrane proteins can localize to the septal membrane by diffusion-and-capture as has been described for membrane proteins in the mother cell. Finally, our results raise the intriguing possibility that SpoIIE has an uncharacterized function at a late stage of sporulation.     

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

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

Characterization of a morphological checkpoint coupling cell-specific transcription to septation in Bacillus subtilis

Early in the process of spore formation in Bacillus subtilis, asymmetric cell division produces a large mother cell and a much smaller prespore. Differentiation of the prespore is initiated by activation of an RNA polymerase sigma factor, sigmaF, specifically in that cell. sigmaF is controlled by a regulatory cascade involving an anti-sigma factor, SpoIIAB, an anti-anti-sigma factor, SpoIIAA, and a membrane-bound phosphatase, SpoIIE, which converts the inactive, phosphorylated form of SpoIIAA back to the active form. SpoIIE is required for proper asymmetric division and much of the protein is sequestered into the prespore during septation. Importantly, activation of sigmaF is dependent on formation of the asymmetric septum. We have now characterized this morphological checkpoint in detail, using strains affected in cell division and/or spoIIE function. Surprisingly, we found that significant dephosphorylation of SpoIIAA occurred even in the absence of septation. This shows that the SpoIIE phosphatase is at least partially active independent of the morphological event and also that cells can tolerate significant levels of unphosphorylated SpoIIAA without activating sigmaF. We also describe a spoIIE mutant in which the checkpoint is bypassed, probably by an increase in the dephosphorylation of SpoIIAA. Taken together, the results support the idea that sequestration of SpoIIE protein into the prespore plays an important role in the control of sigmaF activation and in coupling this activation to septation.     

The SpoIIE phosphatase, the sporulation septum and the establishment of forespore-specific transcription in Bacillus subtilis: a reassessment

Making a spore in Bacillus subtilis requires the formation of two cells, the forespore and the mother cell, which follow dissimilar patterns of gene expression. Cell specificity is first established in the forespore under the control of the sigma F factor, which is itself activated through the action of the SpoIIE serine phosphatase, an enzyme targeted to the septum between the two cells. Deletion of the 10 transmembrane segments of the SpoIIE protein leads to random distribution of SpoIIE in the cytoplasm. Activation of sigma F is slightly delayed and less efficient than in wild type, but it remains restricted to the forespore in a large proportion of cells and the bacteria sporulate with 30% efficiency. Overexpression of the complete SpoIIE protein in a divIC mutant leads to significant sigma F activity, indicating that the septum requirement for activating sigma F can be bypassed. In contradiction to current models, we propose that genetic asymmetry is not created by unequal distribution of SpoIIE within the sporangium, but by exclusion of an inhibitor of SpoIIE from the forespore. This putative inhibitor would be a cytoplasmic molecule that interacts with SpoIIE and shuts off its phosphatase activity until it disappears specifically from the forespore.     

Cloning and expression of an entomocidal protein gene from Bacillus thuringiensis galleriae toxic to both lepidoptera and diptera

Abstract A gene encoding a 61 kDa entomocidal (P2) protein from Bacillus thuringiensis galleriae was cloned in Escherichia coli using oligonucleotide probes corresponding to N- and C-terminal DNA sequences of a Kurstaki P2 gene. When the gene of a 5.8 kb Hin dIII fragment was transformed into B. subtilis on a shuttle vector, sporulation was completely inhibited and expression could not be detected. When B. megaterium was transformed with the same plasmid, only 10% of the cells sporulated and a 61 kDa P2 protein which cross-reacted with kurstaki P2 antiserum was synthesised. Cell lysates of the transformed B. megaterium were found to be toxic to both lepidopteran and dipteran larvae.     

Expression of a Bacillus megaterium sporulation-specific gene during sporulation of Bacillus subtilis

The gene for the Bacillus megaterium spore C protein, a sporulation-specific gene, has been transferred into Bacillus subtilis. The B. megaterium gene was expressed little, if at all, during log-phase and early-stationary-phase growth, but was expressed during sporulation with the same kinetics as and at a level similar to that of the analogous B. subtilis genes. This finding is most consistent with the regulation of this class of genes by a mechanism of positive control.     

Cloning, nucleotide sequencing, and genetic mapping of the gene for small, acid-soluble spore protein gamma of Bacillus subtilis.

The Bacillus subtilis gene (sspE) which codes for small acid-soluble spore protein gamma (SASP-gamma) was cloned, and its chromosomal location (65 degrees, linked to glpD) and nucleotide sequence were determined. The amino acid sequence of SASP-gamma is similar to that of SASP-B of Bacillus megaterium, but these sequences are not as highly conserved across species as are those of other SASPs. The SASP-gamma gene is transcribed only in sporulation in parallel with other SASP genes and gives a single mRNA that is approximately 340 nucleotides long. The results of hybridization of an sspE gene probe to Southern blots of B. subtilis DNA suggested that there is only a single gene coding for the SASP-gamma type of protein in B. subtilis. This was confirmed by introducing a deletion mutation into the cloned sspE gene and transferring the deletion into the B. subtilis chromosome, with concomitant loss of the wild-type gene. This sspE deletion strain sporulated well, but lacked the SASP-gamma type of protein.