Siderophore-Mediated Aluminum Uptake by Bacillus megaterium ATCC 19213

The bacterium Bacillus megaterium ATCC 19213 is known to produce two hydroxamate siderophores, schizokinen and N-deoxyschizokinen, under iron-limited conditions. In addition to their high affinity for ferric ions, these siderophores chelate aluminum. Aluminum was absorbed by B. megaterium ATCC 19213 through the siderophore transport receptor, providing an extra pathway for aluminum accumulation into iron-deficient bacteria. At low concentrations of the metal, siderophore-mediated uptake was the dominant process for aluminum accumulation. At high concentrations of aluminum, passive transport dominated and siderophore production slowed the passive transport of aluminum into the cell. Siderophore production was affected by the aluminum content in the media. High concentrations of aluminum increased production of siderophores in iron-limited cultures, and this production continued into stationary phase. Aluminum did not stimulate siderophore production in iron-replete cultures. The production of siderophores markedly affected aluminum uptake. This has direct implications on the toxicity of heavy metals under iron-deficient conditions.     

Ultrastructure of the capsule of Bacillus megaterium ATCC 19213.

The ultrastructure of the firmly adherent capsule produced by Bacillus megaterium cultured on fructose mineral salts medium was examined using thin sectioning, freeze-etching, and critical point drying by transmission and scanning electron microscopy. The capsule material was shown to be fibrillar, with most fibrils containing bulbous protrusions. Two types of fibres were resolved. These were termed primary and cross-linking fibres. Primary fibres originated at the cell wall and had a diameter of 34-50 nm. They also contained bulbous protrusions and enlarged areas where branching occurred. Cross-linking fibres connected the primary fibres. The cross-linking fibres were much smaller, usually 15 micro m in diameter, and contained few enlarged areas. The primary fibres originated at sites on the cell wall approximately equidistant and 0.26 micro m apart.     

Hydroperoxide inactivation of enzymes within spores of Bacillus megaterium ATCC19213

Abstract Hydroperoxide inactivation of the protoplast enzymes enolase, aldolase and glucose-6-phosphate dehydrogenase in intact spores of Bacillus megaterium ATCC19213 was assessed by first treating the cells with lethal levels of H₂O₂, then germinating them in the presence of chloramphenicol prior to permeabilization and enzyme assays. Glucose-6-phosphate dehydrogenase proved to be more sensitive to H₂O₂than enolase or aldolase, in agreement with findings for isolated enzymes. Average D values (time for 90% inactivation) for spores treated with 0.50% H₂O₂ were 173 min for enolase, 67 min for aldolase and 32 min for glucose-6-phosphate dehydrogenase, compared with a D value of 34 min for spore killing. H₂O₂ killing of spores was found to be conditional in that recoveries of survivors were greater on complex medium than on minimal medium. Overall, it appeared that oxidative inactivation of enzymes may be important for hydroperoxide killing of spores.     

Bacteriocin from Bacillus megaterium ATCC 19213: comparative studies with megacin A-216

A bacteriocin produced by Bacillus megaterium ATCC 19213 was identified, purified, and compared with megacin A from B. megaterium 216. The ATCC 19213 bacteriocin was inducible with mitomycin C and showed phospholipase A activity. Both megacin A-216 and megacin A-19213 contained two dissimilar polypeptide subunits. Megacin A-216 contains a 30,000-dalton alpha subunit and a 15,000-dalton beta subunit. Megacin A-19213 is composed of an alpha subunit 18,000 daltons in mass and a beta subunit about 7,500 daltons in mass. No sequence similarities between alpha and beta subunits of either megacin were detected. The two megacins were further distinguished by quantitative differences in activity spectra and by immunodiffusion analyses.     

Role of the capsule produced by Bacillus megaterium ATCC 19213 in the accumulation of metallic cations

A study was undertaken to determine if the capsule produced by Bacillus megaterium ATCC 19213 was capable of binding metallic ions. For non-toxic metallic ions, this was accomplished by determining the relative concentrations of Fe2+, Ca2+, Zn2+, Mg2+, and Mn2+ removed from a chemically defined medium by the normally capsulated parent strain and two mutants with much smaller capsules. For toxic metals, the rates of respiration of the parent strain and a small capsule mutant in the presence of Cu2+, Hg2+, and Ag1+ were compared. It was found that the parent strain accumulated more Ca2+, Mg2+, and Mn2+. Accumulation of Fe2+ and Zn2+ was similar for the parent strain and the small capsule mutants. Respiration of the parent strain was less inhibited by Cu2+, Hg2+, and Ag1+, indicating that these metals are also bound to the capsule.     

Spore coat protein synthesis in cell-free systems from sporulating cells of Bacillus subtilis.

Cell-free systems for protein synthesis were prepared from Bacillus subtilis 168 cells at several stages of sporulation. Immunological methods were used to determine whether spore coat protein could be synthesized in the cell-free systems prepared from sporulating cells. Spore coat protein synthesis first occurred in extracts from stage t2 cells. The proportion of spore coat protein to total proteins synthesized in the cell-free systems was 2.4 and 3.9% at stages t2 and t4, respectively. The sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis patterns of immunoprecipitates from the cell-free systems showed the complete synthesis of an apparent spore coat protein precursor (molecular weight, 25,000). A polypeptide of this weight was previously identified in studies in vivo (L.E. Munoz, Y. Sadaie, and R.H. Doi, J. Biol. Chem., in press). The synthesis in vitro of polysome-associated nascent spore coat polypeptides with varying molecular weights up to 23,000 was also detected. These results indicate that the spore coat protein may be synthesized as a precursor protein. The removal of proteases in the crude extracts by treatment with hemoglobin-Sepharose affinity techniques may be preventing the conversion of the large 25,000-dalton precursor to the 12,500-dalton mature spore coat protein.     

Cyanide-resistant electron transport in sporulating Bacillus megaterium KM.

The NADH oxidase activity of stage V mother-cell membranes, isolated from sporulating Bacillus megaterium KM, shows a greater inhibition by cyanide and displays this response at lower concentrations of cyanide than the stage V forespore inner membrane. Comparison of the effects of various respiratory inhibitors reveals that the difference in cyanide sensitivity between these membranes is located on the oxidase side of the 2-heptyl-4-hydroxyquinoline N-oxide-sensitive step. Both membranes contain cytochromes a+a3, b-562, b-555, c and d, with three potential oxidases: cytochromes a+a3, o and d. Cyanide difference spectra suggest that cytochromes b-562 and d may be the components involved in the cyanide-resistant electron transport pathway. Membrane ascorbate-N,N,N',N'-tetramethylphenylenediamine and ascorbate 2,6-dichlorophenolindophenol oxidase activities are highly sensitive to cyanide. Evidence is presented for terminal branching of the respiratory chain with branches differing in cyanide sensitivity. The cyanide sensitivity of the NADH oxidase of membranes prepared from various stages of sporulation is compared. Morphogenesis of the mother-cell plasma membrane to a cyanide-sensitive form during stages II and III of sporulation is postulated.     

Morphogenesis of the membrane-bound electron-transport system in sporulating Bacillus megaterium KM.

The properties of electron transport systems present in soluble and particulate fractions of spores of Bacillus megaterium KM?HAVE BEEN COMPARED WIth those of similar fractions prepared from exponential-phase vegetative cells of this organism. The timing and localization of modifications of the electron transport system occurring during sporulation have been investigated by using a system for separating forespores from mother cells at all stages during development [8]. Spore membranes contained cytochromes a + a3, and o at lower concentrations than in vegetative membranes, and in addition cytochrome c, which was not found in exponential-phase vegetative membranes. An NADH oxidase activity of similar specific activity was found in both spore and vegetative membranes but DL-glycerol 3-phosphate and L-malate oxidase activities were found only in vegetative membranes. A soluble NADH oxidase of low specific activity was found in spores and vegetative cells which probably involves a flavoprotein reaction with oxygen because the activity was stimulated by FAD or FMN and difference spectra of concentrated soluble fractions showed spectra typical of a flavoprotein. Particulate NADH oxidase was sensitive to all classical inhibitors of electron transport tested whereas soluble NADH oxidase was insensitive to many of these inhibitors. Cytochrome c was formed between stage I and II of sporulation and this coincided with a five-fold increase in NADH-cytochrome c reductase activity. Forespore membranes had lower contents of cytochromes than sporangial cell membranes but similar levels of NADH and L-malate oxidases; DL-glycerol 3-phosphate oxidase activity could not be detected in either membranes by stage III of sporulation. This characterization of spore electron transport systems provides a basis for suggestions concerning initial metabolic events during spore germination and the effect of a number of germination inhibitors.     

Protease and peptidase activities in growing and sporulating cells and dormant spores of Bacillus megaterium.

Peptidase and protease activities on many different substrates have been determined in several stages of growth of Bacillus megaterium. Extracts of log-phase cells, sporulating cells, and dormant spores of B. megaterium each hydrolyzed 16 different di- and tripeptides. The specific peptidase activity was highest in dormant spores, and the activity in sporulating cells and log-phase cells was about 1.2-fold and 2- to 3-fold lower, respectively. This peptidase acticity was wholly intracellular since extracellular peptidase activity was not detected throughout growth and sporulation. In contrast, intracellular protease activity on a variety of common protein substrates was highest in sporulating cells, and much extracellular activity was also present at this time. The specific activity of intracellular protease in sporulating cells was about 50- and 30-fold higher than that in log-phase cells and dormant spores, respectively. However, the two unique dormant spores proteins known to be the major species degraded during spore germination were degraded most rapidly by extracts of dormant spores, and slightly slower by extracts from log-phase or sporulating cells. The specific activities for degradation of peptides and proteins are compared to values for intracellular protein turnover during various stages of growth.     

Inability of detect cyclic AMP in vegetative or sporulating cells or dormant spores of Bacillus megaterium

Cyclic AMP was not found in vegetative cells or sporulating cells or dormant spores of $\text{Bacillus}\text{megaterium}$ using an assay which would have detected an $\text{in}\text{vivo}$ concentration of 1 – 2 × 10^?9 M. Adenyl cyclase and cyclic AMP phosphodiesterase were also not detected in sonicates of vegetative or sporulating $\text{B.}\text{megaterium}$ cells.     

Transglutaminase in sporulating cells of Bacillus subtilis

We screened various Bacillus species producing transglutaminase (TGase), measured as labeled putrescine incorporated into N,N-dimethylcasein. As a result, we detected TGase activity in sporulating cells of B. subtilis, B. cereus, B. alvei and B. aneurinolyticus, and found TGase activity related to sporulation. TGase activity of Bacillus subtilis was detected in lysozyme-treated sporulating cells during late sporulation, but not in cells without lysozyme treatment or the supernatant of the culture broth. TGase was found to be localized on spores. TGase was preliminarily purified by gel filtration chromatography for characterization. Its activity was eluted in the fractions indicating a molecular weight of approximately 23 kDa. TGase could cross-link and polymerize a certain protein. The enzyme was strongly suggested to form epsilon-(gamma-glutamyl)lysine bonds, which were detected in the spore coat proteins of B. subtilis. The activity was Ca(2+)-independent like the TGases derived from Streptoverticillium or some plants. It is suggested that TGase is expressed during sporulation and plays a role in the assembly of the spore coat proteins of the genus Bacillus.     

Partial purification and characterization of dihydrodipicolinic acid synthetase from sporulating Bacillus megaterium

Sporulation of Bacillus megaterium Km (ATCC 13632) was synchronized by a technique employing three 10% transfers. The culture was harvested when 60% of the cells contained spore forms. Dihydrodipicolinic acid synthetase was purified 150-fold by ammonium sulfate fractionation at pH 6.5, heating for 15 min at 45 C at pH 6.0, ammonium sulfate fractionation at pH 6.0, and subsequent chromatography on diethylaminoethyl cellulose. During the final stage of the purification procedure, the enzyme exhibited sensitivity to refrigeration temperatures. The enzyme had a pH optimum of 7.65 in imidazole buffer. The apparent K(m) values were 4.6 x 10(-4) and 5.0 x 10(-4)m for beta-aspartyl semialdehyde and pyruvate, respectively. All attempts to demonstrate cofactor requirements were unsuccessful. Sulfhydryl inhibiting reagents and lysine did not inhibit the enzymatic reaction. The enzyme exhibited maximal thermal resistance at pH 10.5. The thermal stability of the enzyme at 75 C was increased more than 1,800-fold by the addition of 0.3 m pyruvate. The E(a) was 67,300 cal/mole for the thermal denaturation of the enzyme. At 60 C, the DeltaF, DeltaH, and DeltaS values for the thermal denaturation of the enzyme were 22,250, 66,700, and 133 cal per mole per degree, respectively.     

Role of outer coat in resistance of Bacillus megaterium spore

The outer coat fraction (OC-Fr) of Bacillus megaterium ATCC 12872 spore was isolated as a resistant residue after alkali extraction, sonic treatment, and pronase digestion of the spore coat preparation, and its backbone structure was determined by chemical analysis to be composed of galactosamine-6-phosphate (GalN-P) polymers with polypeptides and calcium. OC-Fr was not fully solubilized after ordinary acid hydrolysis. OC-Fr was insensitive to all hexosaminidases tested, and moreover, an isolated fragment, a pentamer of GalN-P, was also resistant to lysozyme and hexosaminidases even after N-acetylation, being sensitive to them to some extent after dephosphorylation. Molecular sieving experiments revealed that the outer coat limited the entry of compounds with a molecular weight of more than 2,000. Exchange of the metal on the spore surface also influenced the heat resistance. Spores of OC-Fr-deficient mutants were less resistant but were still much more resistant than the vegetative cells. These results suggest that the outer coat protects the contents of the spore against chemical, physical and enzymatic treatments owing to the chemical structure itself, composed mainly of GalN-P polymers, and the molecular sieving effect.     

Comparative antigenicity of spore coat proteins from Bacillus species using antibody to spore coat proteins of Bacillus megaterium

Spore coat proteins obtained by extraction with sodium dodecylsulfate/dithiothreitol from six Bacillus spores were compared by immunoblot analysis using antibodies to spore coat proteins from two strains of B. megaterium. Although the extract from spores of each strain had heterogenous proteins with various molecular weights, there were some bands which cross-reacted with specific antibodies from B. megaterium spores. Specific antibody to 48K protein from B. megaterium ATCC 12872 cross-reacted with 17K protein from B. megaterium ATCC 19213, 13K protein from B. cereus and 50K protein from B. subtilis 60015 and B. subtilis NRRL B558. Also, specific antibody to 22K protein from the same strain cross-reacted with 22K and 17K proteins from B. megaterium ATCC 19213 and 13K protein from B. cereus T. Specific antibody to 17K protein from B. megaterium ATCC 19213 reacted with 22K and 19K proteins in addition to 17K protein of own strain, and it was cross-reactive with 16K protein from B. megaterium ATCC 12872, 19K and 27K proteins from B. thiaminolyticus, 13K protein from B. cereus.     

Immunoelectron microscopic studies on spore coat proteins of Bacillus megaterium

An immunochemical staining technique for the spore coat proteins of Bacillus megaterium ATCC 12872 was developed using colloidal gold as a second antibody. For reducing the non-specific immunogold binding and increasing the specific binding, the affinity-purified IgG was used as a first antibody. In sporulating cells at t10, gold particles were found not only in the spore coat but also in the mother cell cytoplasm, suggesting that some coat proteins were synthesized in the cytoplasm. Use of the specific affinity-purified antibody to 48K-protein demonstrated that this protein was one of the components of the outer coat.     

Molecular cloning of structural and immunity genes for megacins A-216 and A-19213 in Bacillus megaterium.

A host-vector system was developed for molecular cloning in Bacillus megaterium and used to clone the structural and immunity genes for megacins A-216 and A-19213. Recombinant clones that expressed immunity only or both immunity to and production of each megacin were obtained. Restriction mapping of native megacinogenic plasmids and recombinant clones was used to construct physical and genetic maps of megacinogenic plasmids pBM309 and pBM113. Limited sequence homology between pBM309 and pBM113 was detected by Southern blot hybridization and was mapped to, at most, a 6.4-kilobase-pair region of pBM309 and a 6.1-kilobase-pair region of pBM113.     

Biotransformation of the Antimelanoma Agent Betulinic Acid by Bacillus megaterium ATCC 13368

Microbial transformation of the antimelanoma agent betulinic acid was studied. The main objective of this study was to utilize microorganisms as in vitro models to predict and prepare potential mammalian metabolites of this compound. Preparative-scale biotransformation with resting-cell suspensions of Bacillus megaterium ATCC 13368 resulted in the production of four metabolites, which were identified as 3-oxo-lup-20(29)-en-28-oic acid, 3-oxo-11α-hydroxy-lup-20(29)-en-28-oic acid, 1β-hydroxy-3-oxo-lup-20(29)-en-28-oic acid, and 3β,7β,15α-trihydroxy-lup-20(29)-en-28-oic acid based on nuclear magnetic resonance and high-resolution mass spectral analyses. In addition, the antimelanoma activities of these metabolites were evaluated with two human melanoma cell lines, Mel-1 (lymph node) and Mel-2 (pleural fluid).