Dynamic patterns of subcellular protein localization during spore coat morphogenesis in Bacillus subtilis

Endospores of Bacillus subtilis are encased in a thick, proteinaceous shell known as the coat, which is composed of a large number of different proteins. Here we report the identification of three previously uncharacterized coat-associated proteins, YabP, YheD, and YutH, and their patterns of subcellular localization during the process of sporulation, obtained by using fusions of the proteins to the green fluorescent protein (GFP). YabP-GFP was found to form both a shell and a ring around the center of the forespore across the short axis of the sporangium. YheD-GFP, in contrast, formed two rings around the forespore that were offset from its midpoint, before it eventually redistributed to form a shell around the developing spore. Finally, YutH-GFP initially localized to a focus at one end of the forespore, which then underwent transformation into a ring that was located adjacent to the forespore. Next, the ring became a cap at the mother cell pole of the forespore that eventually spread around the entire developing spore. Thus, each protein exhibited its own distinct pattern of subcellular localization during the course of coat morphogenesis. We concluded that spore coat assembly is a dynamic process involving diverse patterns of protein assembly and localization.     

Formaldehyde kills spores of Bacillus subtilis by DNA damage and small, acid-soluble spore proteins of the ααααααα/βββββββ-type protect spores against this DNA damage

Killing of wild-type spores of Bacillus subtilis with formaldehyde also caused significant mutagenesis; spores (termed α⁻β⁻) lacking the two major α/β-type small, acid-soluble spore proteins (SASP) were more sensitive to both formaldehyde killing and mutagenesis. A recA mutation sensitized both wild-type and α⁻β⁻ spores to formaldehyde treatment, which caused significant expression of a recA - lacZ fusion when the treated spores germinated. Formaldehyde also caused protein–DNA cross-linking in both wild-type and α⁻β⁻ spores. These results indicate that: (i) formaldehyde kills B. subtilis spores at least in part by DNA damage and (b) α/β-type SASP protect against spore killing by formaldehyde, presumably by protecting spore DNA.     

Dynamics of the assembly of a complex macromolecular structure--the coat of spores of the bacterium Bacillus subtilis

The coat is the outermost layer of spores of many Bacillus species, and plays a key role in these spores' resistance. The Bacillus subtilis spore coat contains > 70 proteins in four distinct layers: the basement layer, inner coat, outer coat and crust. In this issue of Molecular Microbiology, McKenney and Eichenberger study the dynamics of spore coat assembly using GFP-fusions to 41 B. subtilis coat proteins. A key finding in the work is that formation of the spore coat is initiated by the apparently simultaneous assembly of foci of proteins from all four coat layers on the developing spore just as forespore engulfment by the mother cell begins. The expansion of these foci before completion of forespore engulfment then sets up the scaffold to which coat proteins added later in sporulation are added. This study provides new understanding of the mechanism of the assembly of a multi-protein, multi-lamellar structure.     

Functional regions of the Bacillus subtilis spore coat morphogenetic protein CotE

The Bacillus subtilis spore is encased in a resilient, multilayered proteinaceous shell, called the coat, that protects it from the environment. A 181-amino-acid coat protein called CotE assembles into the coat early in spore formation and plays a morphogenetic role in the assembly of the coat's outer layer. We have used a series of mutant alleles of cotE to identify regions involved in outer coat protein assembly. We found that the insertion of a 10-amino-acid epitope, between amino acids 178 and 179 of CotE, reduced or prevented the assembly of several spore coat proteins, including, most likely, CotG and CotB. The removal of 9 or 23 of the C-terminal-most amino acids resulted in an unusually thin outer coat from which a larger set of spore proteins was missing. In contrast, the removal of 37 amino acids from the C terminus, as well as other alterations between amino acids 4 and 160, resulted in the absence of a detectable outer coat but did not prevent localization of CotE to the forespore. These results indicate that changes in the C-terminal 23 amino acids of CotE and in the remainder of the protein have different consequences for outer coat protein assembly.     

Altered arrangement of proteins in the spore coat of a germination mutant of Bacillus subtilis

Spores produced by a mutant of Bacillus subtilis were slow to develop their resistance properties during sporulation, and were slower to germinate than were wild-type spores. The coat protein composition of the mutant spores, as analysed by SDS-PAGE, was similar to that of the wild-type spores. However, one of the proteins (mol. wt 12000) which is normally present in the outer-most layers of mature wild-type spores and which is surface-exposed, was assembled abnormally into the coat of the mutant spores and not surface-exposed. The mutation responsible for this phenotype (spo-520) has been mapped between pheA and leuB on the B. subtilis chromosome, and was 47% cotransformable with leuB16. This mutation, and three others closely linked to it, define a new sporulation locus, spoVIB, which is involved in spore coat assembly. The phenotype of the mutant(s) supports the contention that spore germination and resistance properties may be determined by the assembly of the coat.     

Electron microscopic examination of the dormant spore and the sporulation of Paenibacillus motobuensis strain MC10

We previously reported a new species Paenibacillus motobuensis. The type strain MC10 was stained gram-negative, but had a gram-positive cell wall structure and its spore had a characteristic star shape. The spore and sporulation process of P. motobuensis strain MC10 were examined by electron microscopy using the technique of freeze-substitution in thin sectioning. The structure of the dormant spore was basically the same as that of the other Bacillus spp. The core of the spore was enveloped with two main spore components, the cortex and the spore coat. In thin section, the spore showed a star-shaped image, which was derived from the structure of the spore coat, which is composed of three layers, namely the inner, middle and outer spore coat. The middle coat was an electron-dense thick layer and had a characteristic ridge. By scanning electron microscopic observation, the ridges were seen running parallel to the long axis of the oval-shaped spore. The process of sporulation was essentially the same as that of the other Bacillus spp. The forespore was engulfed by the mother cell membrane, then the spore coat and the cortex were accumulated in the space between the mother cell membrane and forespore membrane. The mother cell membrane seemed to participate in the synthesis of the spore coat. MC10 strain showed almost identical heat resistance to that of B. subtilis.     

Peptide anchoring spore coat assembly to the outer forespore membrane in Bacillus subtilis

Spore formation in Bacillus subtilis involves the formation of a thick, proteinaceous shell or coat that is assembled around a specialized membrane known as the outer forespore membrane. Here we present evidence that the assembling coat is tethered to the outer forespore membrane by a 26-amino-acid peptide called SpoVM, which is believed to form an amphipathic helix. We show that proper localization of SpoVM is dependent on SpolVA, a morphogenetic protein that forms the basement layer of the spore coat, and conversely, that proper localization of SpoIVA is dependent on SpoVM. Genetic, biochemical and cytological evidence indicates that this mutual dependence is mediated in part by contact between an amino acid side-chain located near the extreme C-terminus of SpoIVA and an amino acid side-chain on the hydrophilic face of the SpoVM helix. Evidence is also presented that SpoVM adheres to the outer forespore membrane via hydrophobic, amino acid side-chains on the hydrophobic face of the helix. The results suggest that the SpoVM helix is oriented parallel to the membrane with the hydrophobic face buried in the lipid bilayer.     

Presence of proteins derived from the vegetative cell membrane in the dormant spore coat of Bacillus subtilis

To confirm the presence of the outer spore membrane in dormant spore coats of Bacillus subtilis, the proteins from vegetative cell membrane and dormant spore coat fractions were compared by immunoblot assay with antibodies prepared against both preparations. The spore coat fraction contained at least 11 proteins antigenically identical to those in the vegetative cell membranes. Further, the cytochemical localization of the proteins derived from vegetative cell membrane in dormant spores was examined by an immunoelectron microscopy method with a colloidal gold-immunoglobulin G complex. The colloidal gold particles were observed in the coat region and around the core region of dormant spore. These results have provided evidence that some proteins from vegetative cell membrane remain in the dormant spore coat region of B. subtilis, although it is not clear whether the outer membrane persists as an intact functional entity or not.     

Transglutaminase-mediated cross-linking of GerQ in the coats of Bacillus subtilis spores

The spores of Bacillus subtilis show remarkable resistance to many environmental stresses, due in part to the presence of an outer proteinaceous structure known as the spore coat. GerQ is a spore coat protein essential for the presence of CwlJ, an enzyme involved in the hydrolysis of the cortex during spore germination, in the spore coat. Here we show that GerQ is cross-linked into higher-molecular-mass forms due in large part to a transglutaminase. GerQ is the only substrate for this transglutaminase identified to date. In addition, we show that cross-linking of GerQ into high-molecular-mass forms occurs only very late in sporulation, after mother cell lysis. These findings, as well as studies of GerQ cross-linking in mutant strains where spore coat assembly is perturbed, lead us to suggest that coat proteins must assemble first and that their cross-linking follows as a final step in the spore coat formation pathway.     

The effect of hypochlorite on spores of Bacillus subtilis lacking small acid-soluble proteins

M.Z.H. SABLI, P. SETLOW AND W.M. WAITES. 1996. α/β-Type small acid-soluble proteins (SASP) bind to spore DNA and protect it against ultraviolet light, heat, hydrogen peroxide and freeze drying, making the spores much more resistant than vegetative cells to these agents. Spores of a mutant of Bacillus subtilis lacking the two major α/β-type SASP were almost 30 000-fold less resistant to hypochlorite than were wild-type spores. After treatment with hypochlorite, surviving spores of the mutant, but not those of the wild type, showed higher levels of mutation, suggesting that SASP contribute to hypochlorite resistance by protecting spore DNA.     

Spore coat protein of Bacillus subtilis. Structure and precursor synthesis.

The coat protein of Bacillus subtilis spores comprises about 10% of the total dry weight of spores and 25% of the total spore protein. One protein with a molecular weight of 13,000 to 15,000 comprises a major portion of the spore coat. This mature spore coat protein has histidine at its NH2 terminus and is relatively rich in hydrophobic amino acids. Netropsin, and antibiotic which binds to A-T-rich regions of DNA and inhibits sporulation, but not growth, decreased the synthesis of this spore coat protein by 75%. A precursor spore coat protein with a molecular weight of 25,000 is made initially at t1 of sporulation and is converted to the mature spore coat protein with a molecular weight of 13,500 at t2 - t3. These data indicate that the spore coat protein gene is expressed very early in sporulation prior to the modifications of RNA polymerase which have been noted.     

Appearance of spore coat protein in the cell extracts of Bacillus subtilis asporogenic mutants.

By use of the antigen-antibody techniques we have studied whether asporogenic mutants of Bacillus subtilis can synthesize the spore coat protein. Antibody specific to spore coat protein was prepared and used to demonstrate that the spore coat protein was synthesized at the early stage of sporulation. We report here that asporogenic mutants synthesize the spore coat protein.     

Interactions between Bacillus subtilis early spore coat morphogenetic proteins

When challenged by stresses such as starvation, the soil bacterium Bacillus subtilis produces an endospore surrounded by a proteinaceous coat composed of >70 proteins that are organized into three main layers: an amorphous undercoat, lightly staining lamellar inner coat and electron-dense outer coat. This coat protects the spore against a variety of chemicals or lysozyme. Mutual interactions of the coat's building blocks are responsible for the formation of this structurally complex and extraordinarily resistant shell. However, the assembly process of spore coat proteins is still poorly understood. In the present work, the main focus is on the three spore coat morphogenetic proteins: SpoIVA, SpoVID and SafA. Direct interaction between SpoIVA and SpoVID proteins was observed using a yeast two-hybrid assay and verified by coexpression experiment followed by Western blot analysis. Coexpression experiments also confirmed previous findings that SpoVID and SafA directly interact, and revealed a novel interaction between SpoIVA and SafA. Moreover, gel filtration analysis revealed that both SpoIVA and SpoVID proteins form large oligomers.