Unrelatedness of Bacillus amyloliquefaciens and Bacillus subtilis

Eight strains of highly amylolytic, sporeforming bacilli (hereafter referred to as Bacillus amyloliquefaciens) were compared with respect to their taxonomic relationship to B. subtilis. The physiological-biochemical properties of these two groups of organisms showed that B. amyloliquefaciens differed from B. subtilis by their ability to grow in 10% NaCl, characteristic growth on potato plugs, increased production of alpha-amylase, and their ability to ferment lactose with the production of acid. The base compositions of the deoxyribonucleic acid (DNA) of the B. subtilis strains consistently fell in the range of 41.5 to 43.5% guanine + cytosine (G + C), whereas that of the B. amyloliquefaciens strains was in the 43.5 to 44.9% G + C range. Hybrid formation between B. subtilis W23 and B. amyloliquefaciens F DNA revealed only a 14.7 to 15.4% DNA homology between the two species. Transducing phage, SP-10, was able to propagate on B. subtilis W23 and B. amyloliquefaciens N, and would transduce B. subtilis 168 (indole(-)) and B. amyloliquefaciens N-10 (arginine(-)) to prototrophy with a frequency of 3.9 x 10(-4) and 2.4 x 10(-5) transductants per plaque-forming unit, respectively. Attempts to transduce between the two species were unsuccessful. These data show that Bacillus amyloliquefaciens is a valid species and should not be classified as a strain or variety of B. subtilis.     

Temperature-Sensitive Induction of Bacteriophage in Bacillus subtilis 168

In a temperature-sensitive mutant of Bacillus subtilis 168, induction of the defective phage PBSX occurred at 48 C. Cell lysis began after 90 min of growth at 48 C, and cell viability began to decrease after 10 to 30 min. The loss in viability at the nonpermissive temperature was prevented by azide or cyanide. Deoxyribonucleic acid (DNA), ribonucleic acid, and protein synthesis were not inhibited at 48 C. Temperature induction of the temperate phage SPO2 also occurred in this mutant. The temperature-sensitive mutation, designated tsi-23, was linked by transduction to purB6 and pig, the order being purB6 pig tsi-23. Mutation tsi-23 was transformable to wild type by B. subtilis 168 DNA but not by DNA from the closely related strains W23 or S31. DNA from the latter two strains transformed auxotrophic markers of strain 168 at frequencies close to those found with 168 donor DNA. Upon temperature induction, cellular DNA was broken to a size of 22S, characteristic of DNA in PBSX particles. The DNA isolated from temperature-induced PBSX did not give an increased Ade(+)/Met(+) transformant ratio relative to cellular DNA nor contain preferential break points as determined by transformation of four closely linked markers.     

Death of Bacillus subtilis Auxotrophs Due to Deprivation of Thymine, Tryptophan, or Uracil

Pritikin, William B. (University of California, Los Angeles), and W. R. Romig. Death of Bacillus subtilis auxotrophs due to deprivation of thymine, tryptophan, or uracil, J. Bacteriol. 92:291-296. 1966.-Auxotrophic mutants of Bacillus subtilis 168 that require either tryptophan, uracil, or thymine died rapidly when deprived of any of these compounds. Phage PBS1 was produced by infected B. subtilis 168 (thy try-2) deprived of thymine. Phage PBS1 was not produced by infected B. subtilis 168 (try-2) deprived of tryptophan or infected B. subtilis 168-15 (try-2 ura) deprived of uracil. B. subtilis 168 thy try-2 and 168-15 could be transduced by phage PBS1 after prolonged deprivation of tryptophan or uracil, respectively. When B. subtilis 168-15 was transduced to uracil independence by phage PBS1, the uracil-independent transductants became immune to uracil-less death within 10 min of exposure to phage, and began to multiply within 2 hr after exposure to phage at an incubation temperature of 46 C.     

Suppressor system in Bacillus subtilis 168

Multiple auxotrophic strains of Bacillus subtilis 168 were tested for joint one-step reversion of two or more auxotrophic markers to the wild-type phenotype. Mu8u5u5, a strain requiring leucine, methionine, and threonine, yielded revertants that grew without added methionine or threonine and proved to have a suppressor gene. When transferred by transformation with deoxyribonucleic acid, this suppressor gene also suppressed the adenine mutation in another strain, Mu8u5u6. The one-step double revertants fell into two distinct classes: strains of class su(+) (I) grow well in broth; strains of class su(+) (II) grow poorly. Strains su(+) (II) tend to revert frequently to the su(+) (I) or su(-) state. Conditional lethal mutants of phage phie were isolated which can grow on the su(+) and not on the su(-) strains.     

Temperature adaptation of Bacillus subtilis by chromosomal groEL replacement

We investigated a temperature adaptation of Bacillus subtilis 168 in which chromosomal groEL was replaced with a psychrophilic groEL. This strain can grow at 50 degrees C but not at 51 degrees C, a temperature at which wild-type B. subtilis can grow. Using in vivo random mutagenesis by the B. subtilis mutator strain (mutS, mutM, mutY), two thermo-adaptants were isolated from the groEL substituted strain at 52 degrees C. They contained novel amino acid alterations in their ATP binding motif (T93I) and the inter-monomer contact (R285H) region of GroEL. These results suggest that GroEL participates in bacterial temperature adaptation.     

Soil strain of Bacillus subtilis harboring a large plasmid that mediates high-frequency conjugal mobilization

The ability of a soil strain of Bacillus subtilis harboring a large plasmid, p19, to mobilize a small staphylococcus plasmid, pUB110, was studied. The latter plasmid was transferred to the recipient cells of Bacillus subtilis 168 at a high frequency (about 10(-2) per recipient cell) both on filter surface and in liquid medium. Mobilization was initiated 40 to 50 min after the beginning of the contact between donor and recipient cells.     

Potassium Requirement for Synthesis of Macromolecules in Bacillus subtilis Infected with Bacteriophage 2C

A mutant of Bacillus subtilis 168 (strain 168 KW), defective in its ability to concentrate K(+) from low levels in the growth medium, was used to study the role of K(+) in the development of phage 2C. Both the final burst size and the duration of the rise period depended on the K(+) concentration in the medium. During normal infection (in the presence of K(+)), host deoxyribonucleic acid (DNA) synthesis stopped. The synthesis of host messenger ribonucleic acid (RNA) continued throughout infection, albeit at a steadily decreasing rate. The synthesis of ribosomal RNA and its subsequent incorporation into mature ribosomes also proceeded. In contrast to these findings, host DNA and messenger RNA synthesis were not inhibited in cells infected in the absence of K(+). Only "early" phage messenger RNA was synthesized under these conditions of infection. Phage DNA synthesis was dependent on K(+) irrespective of the requirement for this cation in protein synthesis.     

Survival of a plasmid-bearing strain of Bacillus subtilis introduced into compost

Survival of Bacillus subtilis strain 168 containing plasmid pAB224, which carries a gene for tetracycline resistance, was studied in mushroom compost under mesophilic and thermophilic conditions. Stable populations of B. subtilis were maintained as spores in both sterile and fresh mushroom compost incubated at 37 degrees C. At 65 degrees C, the introduced B. subtilis populations declined during incubation but spores were still detectable after 28 d. Survival at the higher temperature was greater in fresh than in sterile compost. There was no apparent loss of plasmid pAB224 or plasmid-determined phenotype from the introduced B. subtilis population at either incubation temperature. The frequency of tetracycline resistance in the indigenous Bacillus population was very low (10(-5), but some tetracycline-resistant isolates contained plasmid DNA. Four plasmid DNA profiles were found associated with five Bacillus phenotypes, and some evidence for homology with pAB224 was found. However, pAB224 was found to be a suitable marker for release studies because it was easily recovered, readily distinguished from indigenous plasmids on agarose gels, and was maintained in compost-grown B. subtilis 168 in the absence of any selective pressure.     

Transfer of liposome-encapsulated plasmid DNA toBacillus subtilis protoplasts and calcium-treatedEscherichia coli cells

Protoplasts of Bacillus subtilis 168 trpC2 str and cells of Escherichia coli SK 1590 after treatment with calcium chloride were transformed to tetracycline resistance with the recombinant plasmid pUN82 entrapped in the reverse phase evaporation liposomes. Frequency of transfer was 4 X 10(-4)% in B. subtilis and 8 X 10(-6)% in E. coli.     

Ribonucleic Acid and Protein Synthesis in a Mutant of Bacillus subtilis Defective in Potassium Retention

A mutant of Bacillus subtilis 168 (strain 168 KL), which had lost its normal capacity to accumulate K(+), was used to explore the interrelationship between protein and ribonucleic acid (RNA) synthesis. In contrast to the wild type, the growth rate of strain 168 KL was markedly dependent on the K(+) concentration in the medium. K(+) uptake in the mutant strain was identical to that in the parent, but the mutant was unable to retain and accumulate K(+). Protein synthesis was markedly dependent on the K(+) concentration in the medium, whereas RNA synthesis was relatively unaffected by changes in the level of K(+). Most of the RNA synthesized during K(+) depletion was ribosomal RNA; it appeared in crude extracts in the form of ribonucleoproteins particles with sedimentation values between 4S and 30S. These particles were converted into mature ribosomes when growth was allowed to resume by the addition of K(+). Simultaneous synthesis of RNA and protein was necessary for the quantitative conversion of the ribonucleoprotein particles into ribosomes. During recovery from K(+) depletion, ribosomal protein was synthesized in preference to the other proteins of the cell.     

Productive Infection of Bacillus subtilis 168, with Bacteriophage SP-10, Dependent upon Inducing Treatments

Strains of Bacillus that harbor defective phage PBSX were found to be insensitive to SP-10(C), although the phage adsorbed to these insensitive strains. Strains that did not carry the phage were sensitive to SP-10(C). B. subtilis 168 ind(-), which can be tranduced by SP-10(C) but is nonpermissive for the phage, was rendered phage-sensitive after treatment with ultraviolet (UV) light or mitomycin C. After induction with UV light, maximal sensitivity to SP-10(C) was obtained at a multiplicity of infection (MOI) of approximately 14; with mitomycin C induction, an MOI of approximately 1.0 was required. Phage maturation in sensitized cells was followed by plating infected streptomycin-sensitive cells in the presence of streptomycin at various stages during phase development. The latent period was estimated at 60 to 75 min. We suggest that the resistance of B. subtilis 168 to SP-10 is controlled, at least in part, by the presence of a defective prophage.     

A Bacteriophage of Bacillus subtilis Which Forms Plaques Only at Temperatures Above 50 C I. Physical and Chemical Characteristics of TSP-1

Bacteriophage TSP-1 was isolated from soil in a search for phage which would form plaques on Bacillus subtilis W168 at 53 C. It forms clear plaques only at temperatures from 50 to 55 C. Approximately 95% of the free phage adsorb after 2 min at 53 C. The lytic cycle is between 55 and 60 min long with a burst size of about 55 particles per infected bacterium. The phage was shown to contain double-stranded deoxyribonucleic acid with a base composition of 44.7% guanine plus cytosine. This deoxyribonucleic acid does not contain a base analogue for thymine and has a molecular weight estimated at 56 x 10(6) daltons.     

Bacteria of the genus Bacillus have a hydrolase stereospecific to the D isomer of benzoyl-arginine-p-nitroanilide.

A stereospecific enzyme activity capable of cleaving the amide bond of the synthetic substrate N-benzoyl-D-arginine-p-nitroanilide (D-BAPA) has been found in all aerobic and anaerobic members of the family Bacillaceae tested by us. Cells of nonsporeforming gram-positive or gram-negative bacteria contain a hydrolase activity stereospecific to N-benzoyl-L-arginine-p-nitroanilide. The D-BAPA-hydrolyzing enzymes (D-BAPAases) of mid-logarithmic-phase cells of Bacillus subtilis 168 and B. cereus T were compared. These enzymes had the same molecular weight of approximately 66,000 in gel filtration and the same electrophoretic mobility after electrophoresis on polyacrylamide gels. The D-BAPAases of B. subtilis 168 and B. cereus T differed in the effect of inhibitors on enzymatic activity. While both hydrolases were inhibited by tosyl-L-lysine chloromethyl ketone and tosyl-L-arginine-methyl ester as well as leupeptin, only the D-BAPAase of B. cereus T was inhibited by p-chloromercuribenzene sulfonic acid. The D-BAPAases of B. subtilis and B. cereus T had a Michaelis constant for D-BAPA of 2.9 x 10(-5) M and 1.4 x 10(-4) M, respectively. D-BAPAase is an intracellular enzyme localized in the protoplast (80 to 90% in soluble form in the cytoplasm). The ability to cleave D-BAPA is suggested as an additional chemotaxonomic characteristic of sporeforming bacteria of the genera Bacillus and Clostridium.     

Identification and molecular characterization of a novel Bacillus strain capable of degrading Tween-80

A Tween-80-degrading novel marine Bacillus strain, N10, has recently been isolated in Alexandria University, Egypt. The taxonomic position of this endospore forming bacterium was investigated on the basis of fatty acid analysis and 16S rRNA gene sequencing. Comparative computer database analyses revealed that the bacterium is a Bacillus subtilis strain. The gene encoding the small acid-soluble protein gamma-type (SASP-B), sspE, was successfully utilized in this study as a tool for discrimination between the two B. subtilis subspecies W23 and 168. Based on the alignment of 16S rRNA sequences and analysis of SASP-B relatedness, it has been demonstrated that the novel marine B. subtilis strain N10 is more closely related to the B. subtilis reference strain W23 than to 168. The strain, N10, has been deposited in the Bacillus Genetic Stock Center (BGSC) and assigned the accession number 3A17.     

Effect of Bacillus subtilis BsuM restriction-modification on plasmid transfer by polyethylene glycol-induced protoplast fusion

Polyethylene glycol (PEG)-induced cell fusion is a promising method to transfer larger DNA from one cell to another than conventional genetic DNA transfer systems. The laboratory strain Bacillus subtilis 168 contains a restriction (R) and modification (M) system, BsuM, which recognizes the sequence 5'-CTCGAG-3'. To study whether the BsuM system affects DNA transfer by the PEG-induced cell fusion between R(+)M(+) and R(-)M(-) strains, we examined transfer of plasmids pHV33 and pLS32neo carrying no and eight BsuM sites, respectively. It was shown that although the transfer of pLS32neo but not pHV33 from the R(-)M(-) to R(+)M(+) cells was severely restricted, significant levels of transfer of both plasmids from the R(+)M(+) to R(-)M(-) cells were observed. The latter result shows that the chromosomal DNA in the R(-)M(-) cell used as the recipient partially survived restriction from the donor R(+)M(+) cell, indicating that the BsuM R(-)M(-) strain is useful as a host for accepting DNA from cells carrying a restriction system(s). Two such examples were manifested for plasmid transfer from Bacillus circulans and Bacillus stearothermophilus strains to a BsuM-deficient mutant, B. subtilis RM125.     

Two types of Bacillus subtilis tetA(L) deletion strains reveal the physiological importance of TetA(L) in K(+) acquisition as well as in Na(+), alkali, and tetracycline resistance

The chromosomally encoded TetA(L) protein of Bacillus subtilis is a multifunctional tetracycline-metal/H(+) antiporter that also exhibits monovalent cation/H(+) antiport activity and a net K(+) uptake mode. In this study, B. subtilis mutant strains JC112 and JC112C were found to be representative of two phenotypic types of tetA(L) deletion strains that are generated in the same selection. Both strains exhibited increased sensitivity to low tetracycline concentrations as expected. The mutants also had significantly reduced ability to grow in media containing low concentrations of K(+), indicating that the net K(+) uptake mode is of physiological consequence; the deficit in JC112 was greater than in JC112C. JC112 also exhibited (i) greater impairment of Na(+)- or K(+)-dependent growth at pH 8.3 than JC112C and (ii) a greater degree of Co(+2) as well as Na(+) sensitivity. Studies were initiated to explore the possibility of two different patterns of compensatory changes in other ion-translocating transporters in these mutants. Increased expression of two loci has thus far been shown. Increased expression of czcD-trkA, a locus with a proposed involvement in K(+) uptake, occurred in both mutants. The increase was highest in the presence of Co(2+) and was higher in JC112 than in JC112C. Deletion of czcD-trkA resulted in diminished growth of the wild-type and both mutant strains at low [K(+)], supporting a significant role for this locus in K(+) uptake. Expression of yheL, which is a homologue of the Na(+)/H(+) antiporter-encoding nhaC gene from Bacillus firmus OF4, was also increased in both tetA(L) deletion strains, again with higher up-regulation in JC112. The phenotypes resulting from deletion of yheL were consistent with a modest role for YheL in Na(+)-dependent pH homeostasis in the wild type. No major role for YheL was indicated in the mutants in spite of the overexpression. The studies underscore the multiple physiological functions of TetA(L), including tetracycline, Na(+), and alkali resistance and K(+) acquisition. The studies also reveal and begin to detail the complexity of the response to mutational loss of these functions.     

Initial Characterization of a Temperature-Sensitive Rod− Mutant of Bacillus subtilis

The general biological properties of a temperature-sensitive morphological mutant of Bacillus subtilis (168ts-200B) are described. At the restrictive temperature (45 C), cells grow as spheres which divide irregularly to form grapelike clusters. At the permissive temperature (30 C), the mutant grows as typical B. subtilis rods in short chains. A log-phase culture of rods (30 C) may be converted to spheres by transfer to 45 C. Reversion of spheres to rods occurs when the alternate temperature shift is made. Growth curves, deoxyribonucleic acid replication kinetics, and the morphology of mutant 168ts-200B are described.     

Construction and characterization of recombinant Bacillus subtilis JY123 able to transport xylose efficiently

It has been known that wild type Bacillus subtilis cannot grow rapidly in a minimal medium containing xylose as a sole carbon source because it does not have a xylose-specific transporter. In this study, the arabinose:H(+) symporter, AraE protein from B. subtilis was expressed in B. subtilis 168 in order to transport xylose efficiently. The AraE expression cassette was constructed to contain the xylose-inducible xylA promoter, araE gene and fba terminator, and integrated into the chromosomal amyE gene in B. subtilis 168. Batch cultures in a defined medium with xylose only or a mixture of xylose and glucose showed that expression of AraE led to fast and complete consumption of initially added xylose and hence a considerable increase in cell growth of the recombinant B. subtilis JY123 expressing AraE. Considering the systematic analysis of cell growth, sugar consumption, respiratory quotient and xylulokinase activity, it was certain that AraE protein could transport xylose into B. subtilis efficiently.     

Ribosomal ribonucleic acid synthesis in Bacillus subtilis

The mode of biosynthesis of the 16S and 23S ribosomal ribonucleic acids (rRNA) was studied in Bacillus subtilis 168thy(-). Three criteria were used to define the characteristics of the rRNA species: (i) the time required at 37 degrees C to synthesize 16S and 23S rRNA chains de novo in growing cultures; (ii) the degree of reactivity of the 3'-terminal groups of the rRNA molecules with periodate and [carbonyl-(14)C]isonicotinic acid hydrazide; and (iii) the reactivity of the 5'-terminal regions of the rRNA molecules with the bacterial exonuclease purified by Riley (1969). The 16S and 23S chains of B. subtilis were synthesized at rates of 22+/-2 and 21+/-2 nucleotides added/s. The periodate-[(14)C]isonicotinic acid hydrazide and the exonuclease techniques for estimating apparent chain lengths of RNA indicated that the chain length of the 23S rRNA was 1.8 times that of the 16S fraction. The apparent chain lengths of each rRNA species were: 16S rRNA, 1650+/-50 nucleotide residues; 23S rRNA, 3050+/-90 nucleotide residues. It appears that, the 16S and 23S rRNA molecules in B. subtilis are synthesized in the expected manner, by simple polymerization of the final products on independent cistrons.     

Isolation of thermophilic mutants of Bacillus subtilis and Bacillus pumilus and transformation of the thermophilic trait to mesophilic strains

Thermophilic mutants were isolated from mesophilic Bacillus subtilis and Bacillus pumilus by plating large numbers of cells and incubating them for several days at a temperature about 10 degrees C above the upper growth temperature limit for the parent mesophiles. Under these conditions we found thermophilic mutant strains that were able to grow at temperatures between 50 degrees C and 70 degrees C at a frequency of less than 10(-10). The persistence of auxotrophic and antibiotic resistance markers in the thermophilic mutants confirmed their mesophilic origin. Transformation of genetic markers between thermophilic mutants and mesophilic parents was demonstrated at frequencies of 10(-3) to 10(-2) for single markers and about 10(-7) for two unlinked markers. With the same procedure we were able to transfer the thermophilic trait from the mutant strains of Bacillus to the mesophilic parental strains at a frequency of about 10(-7), suggesting that the thermophilic trait is a phenotypic consequence of mutations in two unlinked genes.