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.     

The role of the sporulation gene spollIE in the regulation of prespore-specific gene expression in Bacillus subtilis

The spoIIIG gene encodes a sigma factor that determines prespore-specific gene expression during sporulation in Bacillus subtilis. Correct spatial and temporal expression of the spoIIIG gene depends on a number of other sporulation (spo) genes, but only one of these genes, spoIIIE, has a specific effect on spoIIIG expression and not on gene expression in the other differentiating cell, the mother cell. However, the spoIIIE gene is expressed predominantly before differentiation begins. Thus, its product must play an important role in sensing or determining the spatial localization of prespore-specific gene expression in this system.     

Identification and characterization of genes controlled by the sporulation-regulatory gene spo0H in Bacillus subtilis.

We describe a general strategy for the identification of genes that are controlled by a specific regulatory factor in vivo and the use of this strategy to identify genes in Bacillus subtilis that are controlled by spo0H, a regulatory gene required for the initiation of sporulation. The general strategy makes use of a cloned regulatory gene fused to an inducible promoter to control expression of the regulatory gene and random gene fusions to a reporter gene to monitor expression in the presence and absence of the regulatory gene product. spo0H encodes a sigma factor of RNA polymerase, sigma H, and is required for the extensive reprograming of gene expression during the transition from growth to stationary phase and during the initiation of sporulation. We identified 18 genes that are controlled by sigma H (csh genes) in vivo by monitoring expression of random gene fusions to lacZ, made by insertion mutagenesis with the transposon Tn917lac, in the presence and absence of sigma H. These genes had lower levels of expression in the absence of sigma H than in the presence of sigma H. Patterns of expression of the csh genes during growth and sporulation in wild-type and spo0H mutant cells indicated that other regulatory factors are probably involved in controlling expression of some of these genes. Three of the csh::Tn917lac insertion mutations caused noticeable phenotypes. One caused a defect in vegetative growth, but only in combination with a spo0H mutation. Two others caused a partial defect in sporulation. One of these also caused a defect in the development of genetic competence. Detailed characterization of some of the csh genes and their regulatory regions should help define the role of spo0H in the regulation of gene expression during the transition from growth to stationary phase and during the initiation of sporulation.     

Identification of different sites of expression for spo loci by transformation of Bacillus subtilis.

Asporogenous mutants of Bacillus subtilis were rendered capable of forming heat-resistant spores by transformation with wild-type (spo+) DNA at, or near, the start of sporulation. For several mutants up to about 50% of the colonies derived from heat-resistant spores, formed as a result of the transformation, remained genetically asporogenous (spo). This was thought to indicate that the genome of the mother cell, but not that of the forespore, was transformed to spo+ and that correct expression of the spo locus in the mother cell was sufficient for spore formation. At the end of the process the mother cell was destroyed, leaving a mature heat-resistant spore that was genetically asporogenous. It is concluded that the loci spoIIID, spIVA, spoVB and spoVE are expressed in the mother cell. For one mutant more than 99% of the colonies derived from heat-resistant spores were genetically spo+. It is concluded that the locus involved, spoVA, had to be expressed in the forespore. Thus different sporulation-specific loci are expressed in the mother cell and in the forespore. The loci expressed in the mother cell are expressed in one cell type so that another cell type, the forespore, can develop into a heat-resistant spore. Other unselected donor markers could be introduced into the recipient during transformation provided high concentrations of DNA were used. The frequency of congression was the same for spo survivors as for spo+ survivors. This implies that there was no correlation between the DNA strand into which the selected spo+ and the unselected donor markers integrated.     

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

The product of the spoIIM gene of Bacillus subtilis is required for complete septum migration and forespore engulfment during sporulation. To investigate whether expression of spoIIM 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 facilitates the use of a genetic technique employed by Illing et al 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 spoIIM must be expressed in the forespore. Biochemical analysis of forespore and mother cell fractions suggests that spoIIM is also expressed in the mother cell. The conditional integrational vector pKSV7 replicates at high copy number in E coli and allows the identification of inserts in the polylinker cluster by disruption of alpha-complementation and thus should be useful for 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.     

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.     

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

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