Participation of the antibiotics of Bac. pumilus and Bac. subtilis in the regulation of bacterial spore formation]

Sporulation and antibiotic production, as well as the effect of exogenic antibacterial substances on bacterial sporogenesis were studied in various strains of Bac. pumilus and Bac. pumilus and Bac. subtilis. The bacteria were grown on a solid sporulation medium with and without the antibiotics. After 5-day incubation the presence of refractyl spores was determined with a phase-contrast method. It was found that in the strains of Bac. pumilus producing antibacterial substances the sporulation was normal. The loss of the capacity for synthesizing such substances resulted in asporegenicity or oligosporogenicity. This allowed a conclusion on existence of phenomenological connection between sporulation and antibiotic production. The study of the antibiotic effect on bacterial sporogenesis showed negative results which are discussed in the paper along two directions: (1) the antibiotics did not probably participate in regulation of the bacteria cell differentiation, (2) the antibiotics regulated the bacterial sporogenesis though their effect was not as yet detected because of methodical difficulties. Therefore, the problem of the antibiotic participation in regulation of sporulation in Bac. pumilus and Bac. subtilis remains open.     

Genetic instability of sporulation-associated characters in a Bacillus subtilis mutant: analysis of the segregation pattern and genetic studies.

A Bacillus subtilis mutant which formed dark-brown 'medusa' (M) colonies was obtained. It sporulated at a high frequency, overproduced extracellular protease during sporulation and possessed a high genetic instability with a complex segregation pattern. Segregation was maintained after repeated re-isolation of single M colonies. The major wild-type-like class of segregants (B) was stable, sporulated normally and produced normal amounts of protease. Occasionally segregants were obtained which produced extremely high amounts of protease, sporulated poorly, formed transparent colonies and were either highly unstable (TD) or stable (TDst). Rarely B(D) (stable, normal sporulation and protease overproduction) and W and T (both stable and asporogenous) segregants were produced. The M phenotype was transmitted as a single factor by transformation but not by transduction. The results of transduction experiments suggest the presence of two mutations, ScoC and ScoD. It is proposed that this new segregating system in B. subtilis may result from tandem duplication of part of the bacterial chromosome.     

Characterization of sporulation histidine kinases of Bacillus anthracis

The initiation of sporulation in Bacillus species is regulated by the phosphorelay signal transduction pathway, which is activated by several histidine sensor kinases in response to cellular and metabolic signals. Comparison of the protein components of the phosphorelay between Bacillus subtilis and Bacillus anthracis revealed high homology in the phosphorelay orthologs of Spo0F, Spo0B, and Spo0A. The sensor domains of sensor histidine kinases are poorly conserved between species, making ortholog recognition tenuous. Putative sporulation sensor histidine kinases of B. anthracis were identified by homology to the HisKA domain of B. subtilis sporulation sensor histidine kinases, which interacts with Spo0F. Nine possible kinases were uncovered, and their genes were assayed for complementation of kinase mutants of B. subtilis, for ability to drive lacZ expression in B. subtilis and B. anthracis, and for the effect of deletion of each on the sporulation of B. anthracis. Five of the nine sensor histidine kinases were inferred to be capable of inducing sporulation in B. anthracis. Four of the sensor kinases could not be shown to induce sporulation; however, the genes for two of these were frameshifted in all B. anthracis strains and one of these was also frameshifted in the pathogenic pXO1-bearing Bacillus cereus strain G9241. It is proposed that acquisition of plasmid pXO1 and pathogenicity may require a dampening of sporulation regulation by mutational selection of sporulation sensor histidine kinase defects. The sporulation of B. anthracis ex vivo appears to result from any one or a combination of the sporulation sensor histidine kinases remaining.     

Altered sporulation and respiratory patterns in mutants of Bacillus subtilis induced by acridine orange

Bott, K. F. (The University of Chicago, Chicago, Ill.), and R. Davidoff-Abelson. Altered sporulation and respiratory patterns in mutants of Bacillus subtilis induced by acridine orange. J. Bacteriol. 92:229-240. 1966.-The addition of acridine orange to vegetative cultures of Bacillus subtilis induces the formation of sporulation mutants at a frequency of 20% or greater. These mutants are grouped into seven categories which reflect their different morphological properties. They are altered in their vegetative metabolism, as indicated by abnormal growth on synthetic media. Sporulation of these mutants is impaired at several levels, all of which are stable upon repeated subculturing. The initial stages of sporulation which require no increased metabolic activity (proteolytic enzyme activity and antibiotic production) are functional in all strains, but glucose dehydrogenase activity, an enzyme associated with early synthetic functions in spore synthesis, is significantly reduced. Reduced nicotinamide adenine dinucleotide oxidase is slightly depressed. It is suggested that acridine orange interacts with a cellular constituent controlling respiration and consequently prevents an increased metabolic activity that may be associated with normal spore synthesis.     

Green marker for colonies of Bacillus subtilis

A Bacillus subtilis plasmid encoding a green fluorescence protein gene (gfp) was constructed. The fluorescence of B. subtilis colonies having this plasmid on agar plates was so high that they could be readily discerned visually under UV light. The fluorescence could be effectively expressed in three ways (i) through use of a strong bsr promoter (blasticidin S resistance gene), (ii) by efficient translation with the bsr translation system, and (iii) through increase in the copy number per cell. The high stability of the GFP plasmid was demonstrated by using more complicated growth conditions without any antibiotic for selection.     

Genetic instability of sporulation-associated characters in a Bacillus subtilis mutant: relationship between sporulation, segregation and the synthesis of extracellular enzymes (kinetic studies).

In the genetically unstable, protease-overproducing 'medusa (M) strains of Bacillus subtilis, segregation of stable, wild-type-like B cells occurred mainly during sporulation. After the end of the exponential growth phase, a small fraction of M cells sporulated quickly and formed M spores, while the majority of the cells, after a 'critical period', gave rise to B segregants which sporulated after a delay. Segregation occurred without cell division. Delayed sporulation, segregation and protease overproduction are related. Similar but more complex results were obtained with the highly unstable TD strains. Sporulation and the kinetics of protease overproduction were also followed in several stable segregants. Depending on the strain, either the rate of protease production or both the rate and time course were affected. The results are interpreted in terms of sequential activation and de-activation of sporulation genes. The production of the alkaline and the neutral proteases was, in general, under common genetic control. In some strains alpha-amylase was also overproduced.     

The extracytoplasmic function sigma factor SigY is important for efficient maintenance of the Spβ prophage that encodes sublancin in Bacillus subtilis

Many strains of the soil bacterium Bacillus subtilis are capable of producing and being resistant to the antibiotic sublancin because they harbor the Spβ prophage. This 135?kb viral genome is integrated into the circular DNA chromosome of B. subtilis, and contains genes for the production of and resistance to sublancin. We investigated the role of SigY in sublancin production and resistance, finding that it is important for efficient maintenance of the Spβ prophage. We were unable to detect the prophage in mutants lacking SigY. Additionally, these mutants were no longer able to produce sublancin, were sensitive to killing by this factor, and displayed a delay in sporulation. Wild-type cells with normal SigY activity were found to partially lose the Spβ prophage during growth and early sporulation, suggesting a mechanism for the bistable outcome of sibling cells capable of killing and of being killed. The appropriate regulation of SigY appears to be essential for growth as evidenced by the inability to disrupt the gene for its putative antisigma. Our results confirm a role for SigY in antibiotic production and resistance, as has been found for other members of the extracytoplasmic function sigma factor family in B. subtilis, and shows that this role is achieved by affecting maintenance of the Spβ prophage.     

Conditional dihydrostreptomycin resistance in Bacillus subtilis

Mutants resistant to dihydrostreptomycin were isolated and genetically analyzed in Bacillus subtilis. Two new classes of mutants distinct from the ribosomal strA locus were found. One class, strB, was located between metC3 and ura-1 on the chromosome. The second class, strC, mapped in the spore gene region close to the spoA locus. Both mutant classes were resistant to dihydrostreptomycin during growth but sensitive to the antibiotic during sporulation. Resuspension sporulation experiments with a strB mutant showed that sensitivity to the antibiotic was acquired early in the sporulation process. The germination and outgrowth of strB spores was sensitive to the antibiotic until growth commenced, whereupon the culture was resistant. Thus the mutants are sensitive to dihydrostreptomycin during both sporulation and germination but resistant during the growth phase.     

Sporulation of Tricarboxylic Acid Cycle Mutants of Bacillus subtilis

A mutant of Bacillus subtilis 168 lacking aconitase (EC 4.2.1.3) was found to be blocked at stage 0 or I of sporulation. Although adenosine triphosphate levels, which normally decrease in tricarboxylic acid cycle mutants at the completion of exponential growth, could be maintained at higher levels by feeding metabolizable carbon sources, this did not permit the cells to progress further into the sporulation sequence. When post-exponential-phase cells of mutants blocked in the first half of the tricarboxylic acid cycle were resuspended with an energy source in culture fluid from post-exponential-phase wild-type B. subtilis or Escherichia coli, good sporulation occurred. The spores produced retained the mutant genotype and were heat stable but lost refractility and heat stability several hours after their production.     

枯草芽孢杆菌微生态制剂发酵研究进展

微生态制剂是饲用抗生素的绿色有效替代品。枯草芽孢杆菌在逆境中可形成抗逆性强的芽孢,在生产和应用过程中保持高活性,是一种高效的微生态制剂菌种。提高枯草芽孢杆菌活菌数及芽孢率是保证微生态制剂产品质量的关键。本文综述了枯草芽孢杆菌芽孢形成的分子生物学机制及影响芽孢形成的重要因素,进一步比较枯草芽孢杆菌微生态制剂不同发酵方式的特点,重点阐述了提高枯草芽孢杆菌有效生物量的工艺优化,最后介绍了枯草芽孢杆菌微生态制剂的应用,并对将来研究思路进行了讨论。     

Survival of lux-lac-marked biosurfactant-producing Pseudomonas aeruginosa UG2L in soil monitored by nonselective plating and PCR.

Two reporter systems, lacZY and luxAB, were stably integrated into the chromosome of Pseudomonas aeruginosa UG2, a biosurfactant-producing strain. Growth and rhamnolipid production of the UG2 wild-type and reporter gene-bearing UG2L strains were similar in liquid culture. A spontaneous rifampin-resistant detecting UG2Lr, allowed antibiotic selection. Phenotypic characteristics were compared for usefulness in detecting UG2Lr colonies: morphology, fluorescent pigment production, light emission (lux), X-Gal (5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside) cleavage (lac), and rifampin resistance. Survival patterns of UG2, UG2L, and UG2Lr strains were similar in sandy loam soil microcosms over 12 12 weeks. The lac marker was not suitable for monitoring P. aeruginosa UG2Lr in soil since 20 to 42% of cultured, aerobic, heterotrophic soil microorganisms formed blue, lactose-positive colonies. The lux genes provided a stable and unequivocal reporter system, as effective as conventional antibiotic plating, for tracking microorganisms nonselectively at 10(3) CFU/g of soil. Three months after inoculation into oil-contaminated and uncontaminated soil microcosms, UG2Lr cells were recovered at 10(7) and 10(4) cells per g (dry weight) of soil, respectively. Detection by PCR amplification of part of the luxA gene confirmed a decrease in UG2Lr cell numbers in uncontaminated soil. In combination, antibiotic resistance, bioluminescence, and PCR analyses provided sensitive detection and quantitative enumeration of P. aeruginosa UG2Lr in soil.     

Survival of Pseudomonas fluorescens and Bacillus subtilis introduced into two soils of different texture in field microplots

Abstract Antibiotic-resistant strains of Pseudomonas fluorescens and Bacillus subtilis , produced by transposon Tn5 mutagenesis and transformation with plasmid pFT30, respectively, were characterized. Both strains grew at a rate comparable to that of the wild-type strains, and the antibiotic resistance remained stable for over 50 generations without selective pressure. During the growing season, the survival of these strains was studied in two soils of different texture cropped with wheat. The B. subtilis populations declined rapidly in both soils and then stabilized at the levels of added spores. P. fluorescens showed a slow, steady decline in both soils; survival was better in the finer-textured soil, a silt loam, than in the coarser loamy sand. For both bacteria, some translocation to deeper soil layers was observed. No significant rhizosphere effects were detected in either of the two soils.     

Elimination of plasmid-linked polyglutamate production by Bacillus subtilis (natto) with acridine orange.

Treatment of Bacillus subtilis (natto) strains Asahikawa, F, and M with acridine orange resulted in the conversion of approximately 64.2% of the Asahikawa population, 22.4% of the F population, and 9.2% of the M population to polyglutamate-nonproducing colonies. Such curing is suggestive of the involvement of plasmid DNA. Samples of cleared lysates of both parental and their cured strains were subjected to agarose gel electrophoresis to determine the plasmid composition. Parental strains were found to possess a plasmid, but polyglutamate-nonproducing derivatives were missing the plasmid. The plasmid-linked polyglutamate production, which was originally isolated from B. subtilis (natto), could be transformed in B. subtilis.     

Elimination of plasmid-linked polyglutamate production by Bacillus subtilis (natto) with acridine orange

Treatment of Bacillus subtilis (natto) strains Asahikawa, F, and M with acridine orange resulted in the conversion of approximately 64.2% of the Asahikawa population, 22.4% of the F population, and 9.2% of the M population to polyglutamate-nonproducing colonies. Such curing is suggestive of the involvement of plasmid DNA. Samples of cleared lysates of both parental and their cured strains were subjected to agarose gel electrophoresis to determine the plasmid composition. Parental strains were found to possess a plasmid, but polyglutamate-nonproducing derivatives were missing the plasmid. The plasmid-linked polyglutamate production, which was originally isolated from B. subtilis (natto), could be transformed in B. subtilis.     

Synthesis of Ribosomal Ribonucleic Acid During Sporulation of Bacillus subtilis

The incorporation of radioactive uracil into 50s and 30s ribosomal subunits and ribosomal ribonucleic acid (rRNA) was studied during the growth cycle of different sporogenic and asporogenic strains of Bacillus subtilis. It was found that partially synchronized cultures of the strains examined incorporated labeled uracil into the two ribosomal subunit species and rRNA during sporulation and during the stationary phase of the asporogenic strains. Kinetic studies have shown that, compared to vegetative cells, the percentage of uracil incorporated into the ribosomal subunits of cells taken 30 min after the end of exponential growth was decreased by about 25 to 35%. This decrease, however, appeared to be a general characteristic of stationary-phase cells and seems to depend on the nature of the sporulation medium and to some extent on the nature of the strain but not on the sp(+) or sp(-) phenotype of the strain. Moreover, by use of actinomycin D it was shown that the labeled uracil incorporated, in the presence of the drug, during the sporulation period was located in the ribosomal subunits (stable RNA). Based on these results, we concluded that during sporulation ribosomal genes are transcribed and consequently rRNA continues to be synthesized, although to a lesser extent than during vegetative growth. These results are discussed in the light of those obtained by Hussey et al.     

Cloning of an unstable spoIIA-tyrA fragment from Bacillus subtilis

A recombinant cosmid clone was isolated from a library created from cosmid pQB79-1 and Bacillus subtilis DNA, and a 15 kb BamHI fragment derived from the cloned insert was transferred to the vector pHV33. The recombinant clone, pRC12, was capable of complementing eight auxotrophic markers in the spoIIA-tyrA region of the B. subtilis chromosome (map positions 205-210). It also complemented eight of nine markers in the spoIIA locus. The exception, spoIIA176, is the most distal marker from lysine. Although pRC12 failed to complement sporulation defects in spoVA or spoIVA (spoIIA+) strains, subclones of pRC12, lacking a functional spoIIA gene, did complement these mutations. pRC12 inhibited sporulation in a spo+ recE strain, possibly due to the presence of multiple functional spoIIA genes. Both the original cosmid and pRC12 were unstable in Escherichia coli and B. subtilis. Antibiotic selection of the vector resulted in extensive deletion of the insert, while selection for insert function in B. subtilis invariably led to loss of the chloramphenicol resistance vector function.     

Genetic heterogeneity in the cysA-fus region of the Bacillus subtilis chromosome: identification of the hos gene.

We identified a new gene, hos, which exerts different sporulation phenotypes in Bacillus subtilis strains with different genetic backgrounds. The hos+ gene showed normal sporulation in the genetic background of JH642 but showed temperature-sensitive sporulation in that of the Tano-oka W. The hos gene was mapped between cysA and rpoB.