L-Proline site for triggering Bacillus megaterium spore germination

Role of chromosomal and plasmid-borne receptor homologues in the response of Bacillus megaterium QM B1551 spores to germinants

Spores of Bacillus megaterium QM B1551 germinate in response to a number of trigger compounds, including glucose, proline, leucine, and inorganic salts. An approximate 6-kb region of the 165-kb plasmid was found to harbor a tricistronic receptor operon, gerU, and a monocistronic receptor component, gerVB. The gerU operon was observed to complement the germination response in plasmidless strain PV361 to glucose and leucine, with KBr acting as a cogerminant. Proline recognition is conferred by the monocistronic gerVB gene, the presence of which also improves the germination response to other single-trigger compounds. A chimeric receptor, GerU*, demonstrates interchangeability between receptor components and provides evidence that it is the B protein of the receptor that determines germinant specificity. Introduction of the gerU/gerVB gene cluster to B. megaterium KM extends the range of germinants recognized by this strain to include glucose, proline, and KBr in addition to alanine and leucine. A chromosomally encoded receptor, GerA, the B component of which is predicted to be truncated, was found to be functionally redundant. Similarly, the plasmid-borne antiporter gene, grmA, identified previously as being essential for germination in QM B1551, did not complement the germination defect in the plasmidless variant PV361. Wild-type spores carrying an insertion-deletion mutation in this cistron germinated normally; thus, the role of GrmA in spore germination needs to be reevaluated in this species.

Characterization of Bacillus anthracis germinant receptors in vitro

Bacillus anthracis begins its infectious cycle as a metabolically dormant cell type, the endospore. Upon entry into a host, endospores rapidly differentiate into vegetative bacilli through the process of germination, thus initiating anthrax. Elucidation of the signals that trigger germination and the receptors that recognize them is critical to understanding the pathogenesis of B. anthracis. Individual mutants deficient in each of the seven putative germinant receptor-encoding loci were constructed via temperature-dependent, plasmid insertion mutagenesis and used to correlate these receptors with known germinant molecules. These analyses showed that the GerK and GerL receptors are jointly required for the alanine germination pathway and also are individually required for recognition of either proline and methionine (GerK) or serine and valine (GerL) as cogerminants in combination with inosine. The germinant specificity of GerS was refined from a previous study in a nonisogenic background since it was required only for germination in response to aromatic amino acid cogerminants. The gerA and gerY loci were found to be dispensable for recognition of all known germinant molecules. In addition, we show that the promoter of each putative germinant receptor operon, except that of the gerA locus, is active during sporulation. A current model of B. anthracis endospore germination is presented.

Amino acid- and purine ribonucleoside-induced germination of Bacillus anthracis DeltaSterne endospores: gerS mediates responses to aromatic ring structures

Specific combinations of amino acids or purine ribonucleosides and amino acids are required for efficient germination of endospores of Bacillus anthracis DeltaSterne, a plasmidless strain, at ligand concentrations in the low-micromolar range. The amino acid L-alanine was the only independent germinant in B. anthracis and then only at concentrations of >10 mM. Inosine and L-alanine both play major roles as cogerminants with several other amino acids acting as efficient cogerminants (His, Pro, Trp, and Tyr combining with L-alanine and Ala, Cys, His, Met, Phe, Pro, Ser, Trp, Tyr, and Val combining with inosine). An ortholog to the B. subtilis tricistronic germination receptor operon gerA was located on the B. anthracis chromosome and named gerS. Disruption of gerS completely eliminated the ability of B. anthracis endospores to respond to amino-acid and inosine-dependent germination responses. The gerS mutation also produced a significant microlag in the aromatic-amino-acid-enhanced-alanine germination pathways. The gerS disruption appeared to specifically affect use of aromatic chemicals as cogerminants with alanine and inosine. We conclude that efficient germination of B. anthracis endospores requires multipartite signals and that gerS-encoded proteins act as an aromatic-responsive germination receptor.

Identification of germination gene of Bacillus megaterium

Glucose, KNO3, proline and leucine initiate the spore germination of B. megaterium ATCC 12872, but not of B. megaterium ATCC 19213. In order to isolate the gene concerning germination of B. megaterium ATCC 12872, we constructed its gene library in plasmid vector, and introduced into B. megaterium ATCC 19213. We obtained a transformant whose spores differed from those of the wild type strain with respect to germinability. Spores of this transformant could be germinated by glucose, proline or leucine. The recombinant plasmid prepared from this transformant was found to carry 2 kilobase pairs fragment of B. megaterium ATCC 12872 DNA. This fragment may contain the gene encoding the protein which plays an important role in germination.

Pulling the trigger: the mechanism of bacterial spore germination

In spite of displaying the most extreme dormancy and resistance properties known among living systems, bacterial endospores retain an alert environment-sensing mechanism that can respond within seconds to the presence of specific germinants. This germination response is triggered in the absence of both germinant and germinant-stimulated metabolism. Genes coding for components of the sensing mechanism in spores of Bacillus subtilis have been cloned and sequenced. However, the molecular mechanism whereby these receptors interact with germinants to initiate the germination response is unknown. Recent evidence has suggested that in spores of Bacillus megaterium KM, proteolytic activation of an autolytic enzyme constitutes part of the germination trigger reaction.

The nucleotide sequence and gene organization of the gerA spore germination operon of Bacillus subtilis 168

The nucleotide sequence of the second and third genes in the Bacillus subtilis spore germination locus, gerA, has been determined and the amino acid (aa) sequence was derived. Two open reading frames (ORFs), corresponding to genes II and III, encode 364-aa residue and 373-aa residue polypeptides, respectively. The gene II product, Mr 41,257, would contain long stretches of hydrophobic aa residues and may be a membrane protein; the gene III product, Mr 42,363, is relatively hydrophilic but possesses an apparent signal peptide for transfer across, and perhaps localisation on, a membrane. The ORFs for genes I and II overlap by eleven codons and the termination codon of gene II overlaps the initiation codon of gene III. Insertional inactivation experiments using integrational plasmids have indicated that the gerA locus is a single transcriptional unit. The expression of the gerA genes has been studied using a lacZ transcriptional fusion; they constitute a developmentally regulated operon.

The use of inhibitors to identify early events during Bacillus megaterium KM spore germination

The germination response of spores of Bacillus megaterium KM, as measured by loss of A600, is more than 95% inhibited by 1 mM-HgCl2. Two Hg2+-sensitive sites (referred to as 'sites I and II') have been identified during germination. Site I represents a pre-commitment event and can be protected from HgCl2 by 50 mM-D-alanine, whereas site II represents a post-commitment event and is not D-alanine-protectable. At 1 mM-HgCl2, 25% of the spore population becomes committed to germinate, but an A600 loss of less than 5% occurs. In this system, loss of heat resistance was associated with commitment, whereas selective cortex hydrolysis, release of pyridine-2,6-dicarboxylic acid, Zn2+ and soluble peptidoglycan, as well as loss of refractility, were identified as post-commitment events. The commitment event was reversibly inhibited by several proteinase inhibitors and a membrane bulking agent. A model of spore germination based on these results is presented.

Genetics of leucine biosynthesis in Bacillus megaterium QM B1551

Genes involved in the biosynthesis of leucine have been mapped in Bacillus megaterium QM B1551, using transducing phage MP13. Mutations were designated leuA, leuB, or leuC on the basis of enzyme assays. Two mutant strains were deficient in the enzyme activities of leuA (alpha-isopropylmalate synthase) and leuC (beta-isopropylmalate dehydrogenase) and so may contain polar mutations. Fine-structure transduction mapping established the gene order leuC-leuB-leuA-ilv-hem-phe. The orientation of the leu genes to the ilv gene is the same as in Bacillus subtilis, but the relationship in respect to two other linked markers, hem and phe, differs.

Interaction between a Bacillus cereus spore hexosaminidase and specific germinants

A purified coat-associated hexosaminidase from spores of Bacillus cereus was studied to determine whether it could promote germination of dormant spores. Spores of a coat-deficient mutant as well as chemically extracted spores were used as substrate. Both of these spore preparations responded poorly to most germinants. However, absorbance loss was accelerated when the hexosaminidase was added in the presence of L-alanine. Enzyme alone was not effective. The addition of D-alanine inhibited completely the absorbance loss caused by hexosaminidase and L-alanine. Calcium dipicolinate and L-alpha-aminobutyric acid activated the hexosaminidase to some extent, but these chemicals were much less effective than L-alanine. In addition to the absorbance loss, the spores treated with enzyme and germinants released hexosamine and lost heat resistance and phase whiteness. The results suggest that this particular enzyme might have a role in germination.

Isolation and properties of membranes from Bacillus megaterium spores

Membranes from dormant and heat-activated spores of Bacillus megaterium QM B1551 were isolated and purified by gentle lysis procedures followed by differential and sucrose density gradient centrifugations. The purified membranes were enriched for inner membranes and were characterized by their density and content of proteins, phospholipids, enzymes, cytochromes, and carotenoids. These purified spore membranes could be used to investigate their role in the triggering of germination.