Bacillus subtilis spore coat assembly requires cotH gene expression.

Endospores of Bacillus subtilis are encased in a protein shell, known as the spore coat, composed of a lamella-like inner layer and an electron-dense outer layer. We report the identification and characterization of a gene, herein called cotH, located at 300 degrees on the B. subtilis genetic map between two divergent cot genes, cotB and cotG. The cotH open reading frame extended for 1,086 bp and corresponded to a polypeptide of 42.8 kDa. Spores of a cotH null mutant were normally heat, lysozyme, and chloroform resistant but were impaired in germination. The mutant spores were also pleiotropically deficient in several coat proteins, including the products of the previously cloned cotB, -C, and -G genes. On the basis of the analysis of a cotE cotH double mutant, we infer that CotH is probably localized in the inner coat and is involved in the assembly of several proteins in the outer layer of the coat.     

Regulatory studies on the promoter for a gene governing synthesis and assembly of the spore coat in Bacillus subtilis

gerE is a regulatory gene of Bacillus subtilis that governs the synthesis and assembly of the spore coat and is required for the production of spores that are lysozyme-resistant and germination-proficient. We report the identification of the promoter for gerE and studies on the regulation of its expression. We show that gerE is switched on at the fourth hour of sporulation (stage-V) and that this expression is restricted to the mother-cell chamber of the sporangium. Dependency studies in which the level of gerE expression was measured in 36 different developmental mutants indicate that efficient expression of gerE requires the products of almost all spo0-IV genes tested as well as certain spoV genes. On the basis of its time of induction, compartmentalization of expression and pattern of dependence on other spo genes, gerE is inferred to be regulated co-ordinately with the previously studied spore coat protein gene cotA. gerE and cotA may be members of a developmental regulon of genes whose products are involved in the assembly of the spore coat.     

Nucleotide sequence and insertional inactivation of a Bacillus subtilis gene that affects cell division, sporulation, and temperature sensitivity.

Located at 135 degrees on the Bacillus subtilis genetic map are several genes suspected to be involved in cell division and sporulation. Previously isolated mutations mapping at 135 degrees include the tms-12 mutation and mutations in the B. subtilis homologs of the Escherichia coli cell division genes ftsA and ftsZ. Previously, we cloned and sequenced the B. subtilis ftsA and ftsZ genes that are present on an 11-kilobase-pair EcoRI fragment and found that the gene products and organization of these two genes are conserved between the two bacterial species. We have since found that the mutation in the temperature-sensitive filamenting tms-12 mutant maps upstream of the ftsA gene on the same 11-kilobase-pair EcoRI fragment in a gene we designated dds. Sequence analysis of the dds gene and four other open reading frames upstream of ftsA revealed no significant homology to other known genes. It was found that the dds gene is not absolutely essential for viability since the dds gene could be insertionally inactivated. The dds null mutants grew slowly, were filamentous, and exhibited a reduced level of sporulation. Additionally, these mutants were extremely temperature sensitive and were unable to form colonies at 37 degrees C. Another insertion, which resulted in the elimination of 103 C-terminal residues, resulted in a temperature-sensitive phenotype less severe than that in the dds null mutant and similar to that in the known tms-12 mutant. The tms-12 mutation was cloned and sequenced, revealing a nonsense codon that was predicted to result in an amber fragment that was about 65% of the wild-type size (elimination of 93 C-terminal residues).     

An additional GerE-controlled gene encoding an abundant spore coat protein from Bacillus subtilis.

We describe the identification and characterization of a gene, herein designated cotG, encoding an abundant coat protein from the spores of Bacillus subtilis. The cotG open reading frame is 195 codons in length and is capable of encoding a polypeptide of 24 kDa that contains nine tandem copies of the 13-amino-acid long, approximately repeated sequence H/Y-K-K-S-Y-R/C-S/T-H/Y-K-K-S-R-S. cotG is located at 300 degrees on the genetic map close to another coat protein gene, cotB. The cotG and cotB genes are in divergent orientation and are separated by 1.3 kb. Like the promoter for cotB, the cotG promoter is induced at a late stage of sporulation under the control of the RNA polymerase sigma factor sigma K and the DNA-binding protein GerE. The -10 and -35 nucleotide sequences of the cotG promoter resemble those of other promoters recognized by sigma K-containing RNA polymerase, and centered 70 bp upstream of the apparent start site is a sequence that matches the consensus binding site for GerE. Spore coat proteins from a newly constructed cotG null mutant lack not only CotG but also CotB, a finding that suggests that CotG may be a morphogenetic protein that is required for the incorporation of CotB into the coat.     

Role of the spore coat layers in Bacillus subtilis spore resistance to hydrogen peroxide, artificial UV-C, UV-B, and solar UV radiation

Spores of Bacillus subtilis possess a thick protein coat that consists of an electron-dense outer coat layer and a lamellalike inner coat layer. The spore coat has been shown to confer resistance to lysozyme and other sporicidal substances. In this study, spore coat-defective mutants of B. subtilis (containing the gerE36 and/or cotE::cat mutation) were used to study the relative contributions of spore coat layers to spore resistance to hydrogen peroxide (H(2)O(2)) and various artificial and solar UV treatments. Spores of strains carrying mutations in gerE and/or cotE were very sensitive to lysozyme and to 5% H(2)O(2), as were chemically decoated spores of the wild-type parental strain. Spores of all coat-defective strains were as resistant to 254-nm UV-C radiation as wild-type spores were. Spores possessing the gerE36 mutation were significantly more sensitive to artificial UV-B and solar UV radiation than wild-type spores were. In contrast, spores of strains possessing the cotE::cat mutation were significantly more resistant to all of the UV treatments used than wild-type spores were. Spores of strains carrying both the gerE36 and cotE::cat mutations behaved like gerE36 mutant spores. Our results indicate that the spore coat, particularly the inner coat layer, plays a role in spore resistance to environmentally relevant UV wavelengths.     

Interactions among CotB, CotG, and CotH during assembly of the Bacillus subtilis spore coat

Spores formed by wild-type Bacillus subtilis are encased in a multilayered protein structure (called the coat) formed by the ordered assembly of over 30 polypeptides. One polypeptide (CotB) is a surface-exposed coat component that has been used as a vehicle for the display of heterologous antigens at the spore surface. The cotB gene was initially identified by reverse genetics as encoding an abundant coat component. cotB is predicted to code for a 43-kDa polypeptide, but the form that prevails in the spore coat has a molecular mass of about 66 kDa (herein designated CotB-66). Here we show that in good agreement with its predicted size, expression of cotB in Escherichia coli results in the accumulation of a 46-kDa protein (CotB-46). Expression of cotB in sporulating cells of B. subtilis also results in a 46-kDa polypeptide which appears to be rapidly converted into CotB-66. These results suggest that soon after synthesis, CotB undergoes a posttranslational modification. Assembly of CotB-66 has been shown to depend on expression of both the cotH and cotG loci. We found that CotB-46 is the predominant form found in extracts prepared from sporulating cells or in spore coat preparations of cotH or cotG mutants. Therefore, both cotH and cotG are required for the efficient conversion of CotB-46 into CotB-66 but are dispensable for the association of CotB-46 with the spore coat. We also show that CotG does not accumulate in sporulating cells of a cotH mutant, suggesting that CotH (or a CotH-controlled factor) stabilizes the otherwise unstable CotG. Thus, the need for CotH for formation of CotB-66 results in part from its role in the stabilization of CotG. We also found that CotB-46 is present in complexes with CotG at the time when formation of CotB-66 is detected. Moreover, using a yeast two-hybrid system, we found evidence that CotB directly interacts with CotG and that both CotB and CotG self-interact. We suggest that an interaction between CotG and CotB is required for the formation of CotB-66, which may represent a multimeric form of CotB.     

Cloning and characterization of a cluster of genes encoding polypeptides present in the insoluble fraction of the spore coat of Bacillus subtilis.

The Bacillus subtilis spore coat is composed of at least 15 polypeptides plus an insoluble protein fraction arranged in three morphological layers. The insoluble fraction accounts for about 30% of the coat protein and is resistant to solubilization by a variety of reagents, implying extensive cross-linking. A dodecapeptide was purified from this fraction by formic acid hydrolysis and reverse-phase high-performance liquid chromatography. This peptide was sequenced, and a gene designated cotX was cloned by reverse genetics. The cotX gene encoding the dodecapeptide at its amino end was clustered with four other genes designated cotV, cotW, cotY, and cotZ. These genes were mapped to 107 degrees between thiB and metA on the B. subtilis chromosome. The deduced amino acid sequences of the cotY and cotZ genes are very similar. Both proteins are cysteine rich, and CotY antigen was present in spore coat extracts as disulfide cross-linked multimers. There was little CotX antigen in the spore coat soluble fraction, and deletion of this gene resulted in a 30% reduction in the spore coat insoluble fraction. Spores produced by strains with deletions of the cotX, cotYZ, or cotXYZ genes were heat and lysozyme resistant but readily clumped and responded more rapidly to germinants than did spores from the wild type. In electron micrographs, there was a less densely staining outer coat in spores produced by the cotX null mutant, and those produced by a strain with a deletion of the cotXYZ genes had an incomplete outer coat. These proteins, as part of the coat insoluble fraction, appear to be localized to the outer coat and influence spore hydrophobicity as well as the accessibility of germinants.     

Analysis of the properties of spores of Bacillus subtilis prepared at different temperatures

AIMS: To determine the effect of sporulation temperature on Bacillus subtilis spore resistance and spore composition. METHODS AND RESULTS: Bacillus subtilis spores prepared at temperatures from 22 to 48 degrees C had identical amounts of dipicolinic acid and small, acid-soluble proteins but the core water content was lower in spores prepared at higher temperatures. As expected from this latter finding, spores prepared at higher temperatures were more resistant to wet heat than were spores prepared at lower temperatures. Spores prepared at higher temperatures were also more resistant to hydrogen peroxide, Betadine, formaldehyde, glutaraldehyde and a superoxidized water, Sterilox. However, spores prepared at high and low temperatures exhibited nearly identical resistance to u.v. radiation and dry heat. The cortex peptidoglycan in spores prepared at different temperatures showed very little difference in structure with only a small, albeit significant, increase in the percentage of muramic acid with a crosslink in spores prepared at higher temperatures. In contrast, there were readily detectable differences in the levels of coat proteins in spores prepared at different temperatures and the levels of at least one coat protein, CotA, fell significantly as the sporulation temperature increased. However, this latter change was not due to a reduction in cotA gene expression at higher temperatures. CONCLUSIONS: The temperature of sporulation affects a number of spore properties, including resistance to many different stress factors, and also results in significant alterations in the spore coat and cortex composition. SIGNIFICANCE AND IMPACT OF THE STUDY: The precise conditions for the formation of B. subtilis spores have a large effect on many spore properties.     

ExsY and CotY are required for the correct assembly of the exosporium and spore coat of Bacillus cereus

The exosporium-defective phenotype of a transposon insertion mutant of Bacillus cereus implicated ExsY, a homologue of B. subtilis cysteine-rich spore coat proteins CotY and CotZ, in assembly of an intact exosporium. Single and double mutants of B. cereus lacking ExsY and its paralogue, CotY, were constructed. The exsY mutant spores are not surrounded by an intact exosporium, though they often carry attached exosporium fragments. In contrast, the cotY mutant spores have an intact exosporium, although its overall shape is altered. The single mutants show altered, but different, spore coat properties. The exsY mutant spore coat is permeable to lysozyme, whereas the cotY mutant spores are less resistant to several organic solvents than is the case for the wild type. The exsY cotY double-mutant spores lack exosporium and have very thin coats that are permeable to lysozyme and are sensitive to chloroform, toluene, and phenol. These spore coat as well as exosporium defects suggest that ExsY and CotY are important to correct formation of both the exosporium and the spore coat in B. cereus. Both ExsY and CotY proteins were detected in Western blots of purified wild-type exosporium, in complexes of high molecular weight, and as monomers. Both exsY and cotY genes are expressed at late stages of sporulation.     

Properties of Bacillus cereus temperature-sensitive mutants altered in spore coat formation.

Three conditional Bacillus cereus mutants altered in the assembly or formation of spore coat layers were analyzed. They all grew as well as the wild type in an enriched or minimal medium but produced lysozyme and octanol-sensitive spores at the nonpermissive temperature (35 to 38 degrees C). The spores also germinated slowly when produced at 35 degrees C. Temperature-shift experiments indicated that the defective protein or regulatory signal is expressed at the time of formation of the outer spore coat layers. Revertants regained all wild-type spore properties at frequencies consistent with initial point mutations. Spore coat defects were evident in thin sections and freeze-etch micrographs of mutant spores produced at 35 degrees C. In addition, one mutant contained an extra surface deposit, perhaps unprocessed spore coat precursor protein. A prevalent band of about 65,000 daltons (the same size as the presumptive precursor) was present in spore coat extracts of this mutant and may be incorrectly processed to mature spore coat polypeptides. Another class of mutants was defective in the late uptake of half-cystine residues into spore coats. Such a defect could lead to improper formation of the outer spore coat layers.     

Identification and characterization of genes for a second anthranilate synthase in Pseudomonas aeruginosa: interchangeability of the two anthranilate synthases and evolutionary implications.

Two anthranilate synthase gene pairs have been identified in Pseudomonas aeruginosa. They were cloned, sequenced, inactivated in vitro by insertion of an antibiotic resistance gene, and returned to P. aeruginosa, replacing the wild-type gene. One anthranilate synthase enzyme participates in tryptophan synthesis; its genes are designated trpE and trpG. The other anthranilate synthase enzyme, encoded by phnA and phnB, participates in the synthesis of pyocyanin, the characteristic phenazine pigment of the organism. trpE and trpG are independently transcribed; homologous genes have been cloned from Pseudomonas putida. The phenazine pathway genes phnA and phnB are cotranscribed. The cloned phnA phnB gene pair complements trpE and trpE(G) mutants of Escherichia coli. Homologous genes were not found in P. putida PPG1, a non-phenazine producer. Surprisingly, PhnA and PhnB are more closely related to E. coli TrpE and TrpG than to Pseudomonas TrpE and TrpG, whereas Pseudomonas TrpE and TrpG are more closely related to E. coli PabB and PabA than to E. coli TrpE and TrpG. We replaced the wild-type trpE on the P. aeruginosa chromosome with a mutant form having a considerable portion of its coding sequence deleted and replaced by a tetracycline resistance gene cassette. This resulted in tryptophan auxotrophy; however, spontaneous tryptophan-independent revertants appeared at a frequency of 10(-5) to 10(6). The anthranilate synthase of these revertants is not feedback inhibited by tryptophan, suggesting that it arises from PhnAB. phnA mutants retain a low level of pyocyanin production. Introduction of an inactivated trpE gene into a phnA mutant abolished residual pyocyanin production, suggesting that the trpE trpG gene products are capable of providing some anthranilate for pyocyanin synthesis.