Host-controlled modification and restriction in Bacillus subtilis: Bsu 168-system and BsuR-system in B. subtilis 168.

Summary A Bsu168-specific restriction deficient (r ₁₆₈ ^- ) mutant of Bacillus subtilis Marburg 168 was transformed to be BsuR-specific restriction proficient (r _R ⁺ ) with B. subtilis R DNA as efficiently as the Bsu168-specific restriction proficient (r ₁₆₈ ⁺ ) parental strain (hsrM ⁺, hsdR ^-).We constructed r _R ⁺ m _R ⁺ r ₁₆₈ ⁺ m ₁₆₈ ⁺ strain (ISMR 4), r _R ⁺ m _R ⁺ r ₁₆₈ ^- m ₁₆₈ ⁺ strain (ISR 11) and r _R ⁺ m _R ⁺ r ₁₆₈ ^- m ₁₆₈ ^- strain (ISR 6) from strain 101 (r ₁₆₈ ⁺ m ₁₆₈ ⁺ ), strain 1012 (r ₁₆₈ ^- m ₁₆₈ ⁺ ) and strain RM125 (r ₁₆₈ ^- m ₁₆₈ ^- ), respectively by transformation with B. subtilis R DNA, and tested their restriction and modification activities on phage 105C. The results show that the sites recognized by Bsu168-specific restriction and modification enzymes and the sites recognized by BsuR-specific ones are not overlapping.We conclude that the Bsu168-modification and restriction system and the BsuR-modification and restriction system are controlled independently by two distinct sets of genes in the r _R ⁺ m _R ⁺ transformant of r ₁₆₈ ⁺ m ₁₆₈ ⁺ strain B. subtilis 168.     

Introduction of host-controlled modification and restriction systems of Bacillus subtilis IAM1247 into Bacillus subtilis 168.

Bacillus subtilis IAM1247 had two modification and restriction systems (Bsu1247I and Bsu1247II), the former producing an isoschizomer of PstI endonuclease. A transformant clone was isolated which had Bsu 168, BsuR, and Bsu1247I systems coexisting within a genome.     

Restriction of plasmid-mediated transformation in Bacillus subtilis 168.

Summary When plasmids carrying leucine genes of Bacillus subtilis 168 were isolated from a restriction and modification deficient (r^-m^-) strain and used for transformation of a restricting strain B. subtilis 168 leu recE4, the number of transformants was greatly reduced. Transformation of a rec ⁺ strain (transformation by integration of the donor DNA into the chromosome) with the plasmids was not affected irrespective of whether the recipient carried the r⁺ or r^- phenotype. These results show that the plasmid-mediated transformation is subject to the host controlled restriction and suggest that r^-m^- strains should be used for construction of recombinant DNA molecules in B. subtilis 168.     

The effect of restriction on shotgun cloning and plasmid stability in Bacillus subtilis Marburg

Summary Using the bifunctional cloning vehicle pHP13, which carries the replication functions of the cryptic Bacillus subtilis plasmid pTA1060, the effects of BsuM restriction on the efficiency of shotgun cloning of heterologous Escherichia coli DNA were studied. In a restriction-deficient but modification-proficient mutant of B. subtilis, clones were obtained at a high frequency, comparable to frequencies normally obtained in E. coli (10⁴ clones per g target DNA). Large inserts were relatively abundant (26% of the clones contained inserts in the range of 6 to 15 kb), which resulted in a high average insert length (3.6 kb). In the restriction-proficient B. subtilis strain, the class of large inserts was underrepresented. Transformation of B. subtilis with E. coli-derived individual recombinant plasmids was affected by BsuM restriction in two ways. First, the transforming activities of recombinant plasmids carrying inserts larger than 4 kb, were, in comparison with the vector pHP13, reduced to varying degrees in the restricting host. The levels of the reduction increased with insert length, resulting in a 7800-fold reduction for the largest plasmid used (pC23; insert length 16 kb). Second, more than 80% of the pC23 transformants in the restricting strain contained a deleted plasmid. In the non-restricting strain, the transforming activities of the plasmids were fairly constant as a function of insert length (in the range of 0–16 kb), and no structural instability was observed. It is concluded that for shotgun cloning in B. subtilis, the use of restriction-deficient strains is highly preferable. Evidence is presented that in addition to XhoI other sequences are involved in BsuM restriction. It is postulated that AsuII sites are additional target sites for BsuM restriction.     

Chromosomal integration of sfp gene in Bacillus subtilis to enhance bioavailability of hydrophobic liquids

Bacillus subtilis C9 effectively degrades aliphatic hydrocarbons up to a chain length of C₁₉ and produces a lipopeptide-type biosurfactant, surfactin, yet it has no genetic competency. Therefore, to obtain a transformable surfactin producer, the sfp gene cloned from B. subtilis C9 was integrated into the chromosome of B. subtilis 168, a non-surfactin producer, by homologous recombination. The transformants reduced the surface tension of the culture broth from 70.0 mN/m to 28.0 mN/m, plus the surface-active compound produced by the transformants exhibited the same R_f value as that from B. subtilis C9 and authentic surfactin in a thin-layer chromatographic analysis. The integration of the sfp gene into the chromosome of B. subtilis 168 was confirmed by Southern hybridization. Like B. subtilis C9, the transformants readily degraded n-hexadecane, although the original strain did not. It was also statistically confirmed that the hydrocarbon degradation of the transformants was highly correlated to their surfactin production by the determination of the correlation coefficient (r²=0.997, P<0.01). Therefore, these results indicate that the surfactin produced from B. subtilis enhances the bioavailability of hydrophobic liquids.     

Restriction on Conjugational Transfer of pLS20 in Bacillus subtilis 168

Conjugational transfer of pLS20 in Bacillus subtilis Marburg 168 is restricted by the BsuM restriction-modification system. Restriction efficiency was measured using pLS20 derivatives possessing various numbers of XhoI sites, which are known to be recognized by BsuM. An increase in XhoI sites clearly reduced the conjugational efficiency of pLS20 as compared with that of pUB110 plasmid lacking XhoI.     

Restriction of hemimethylated DNA by the Bacillus subtilis R system

Summary The effects of restriction by the BsuR system on hemimethylated SPP1 DNA were investigated. In vitro, single-stranded nicks were introduced in the nonmodified strand of the hemimethylated DNA at the same sites as recognized in nonmodified homoduplex DNA. Transfection with BsuR-treated hemimethylated DNA was severely reduced.In vivo, transfection with hemimethylated DNA was also severely reduced in competent B. subtilis R cells. In contrast, transfection of protoplasts of the R strain with this DNA was not affected. The apparent restriction by competent cells was attributed to the special mode of processing of transfecting DNA.     

On the appearance of Bacillus subtilis intracellular serine protease in the cell membrane and culture medium

While about 80% of the cell-bound intracellular serine protease of Bacillus subtilis A-50 have been recovered in the soluble fraction upon disruption of cells, the rest of the enzyme was found to be associated with the membrane fraction. Soluble cytoplasmic intracellular serine protease, as well as membrane-bound serine protease liberated by nonionic detergent treatment, have been isolated in a pure state and shown to be identical. The same protease might also be found extracellularly, due presumably to cell lysis or altered membrane permeability. Intracellular serine protease of Bacillus subtilis A-50 was clearly related to Bacillus subtilis serine proteases W1 and bacillopeptidase F described as extracellular enzymes.Abbreviations ISP intracellular serine protease - ISP-A-Bsu A-50 and ISP-B-Bsu A-50 molecular forms A and B of B. subtilis A-50 intracellular serine protease, respectively - SDS sodium dodecyl sulfate - PMSF phenylmethyl sulfonylfluoride - pNA p-nitroanilide - Buffer A 50 mM Tris-(hydroxymethyl)aminomethane-1 mM CaCl₂ adjusted to pH 8.5 with HCl     

Mapping by interspecies transformation experiments of several ribosomal protein genes near the replication origin of Bacillus subtilis chromosome.

Summary Bacillus subtilis 168 was transformed with DNAs from B. amyloliquefaciens K or B. licheniformis IAM 11054. These two species show a considerable difference in ribosomal proteins from B. subtilis. Analyses of the transformants indicated that the genes for 16 proteins, S3, S5, S8, S12, S17, S19, BL4, BL5, BL6, BL8, BL14, BL16, BL17, BL22, BL23 and BL25 are located in the cysA-str-spc region on B. subtilis chromosome. The genes for 10 proteins, S4, S6, S13, S16, S20, BL15, BL18, BL20, BL24 and BL28 could not be found in this region in the prsent experiments.     

Restriction and modification in Bacillus subtilis 168. Regulation of hsrM(nonB) expression in spoOA mutants and effects on permissiveness for phi15 and phi105 phages

Summary Gene hsrM (nonB) of Bacillus subtilis 168, causing non-permissiveness to phage SP10 (Saito et al. 1979) and reduced plating efficiency of unmodified phage 105, is responsible for non-permissiveness of B. subtilis 168 for phages 15 and PZA. Upon transformation to sporulation deficiency (allele spoOA) B. subtilis 168 becomes permissive for 15 and PZA and loses the ability to restrict 105. spoOA str-1 double transformants of B. subtilis 168, however, retain the restriction 168 and non-permissiveness for 15 and PZA phages, in spite of their Spo^– phenotype. Therefore it appears that a functional product of the spoOA gene is required for expression of gene hsrM in wild-type bacteria, but is not essential in streptomycin-resistant bacteria. Phage genomes (PZA) were trapped in spores of the restriction deficient strain with much higher efficiency than in the wild-type.     

Restriction and modification in B. subtilis

Summary The effects of restriction in vivo by competent B. subtilis R cells and in vitro by purified endonuclease BsuR on transformation and transfection with native and denatured DNA were investigated.The results show that transformation by either native, or denatured DNA is not affected by restriction, whereas transfection both with native and denatured SPP1 DNA is severely restricted.In contrast to the results obtained in vivo, the biological activity of native and denatured transforming DNA is destroyed by BsuR in vitro, as is the transfecting activity of native and denatured SPP1 DNA. The sensitivity of denatured DNA, either with mixtures of the complementary strands or with separated single strands¹ alone, is significantly lower than that of native DNA.The results are discussed in the context of possible mechanisms underlying the different responses of transforming and transfecting DNA to in vivo restriction by B. subtilis R cells.Abbreviations EGTA ethyleneglycolbis-(aminoethylether)tetraacetic acid - m⁺ modified - m^- non-modified - moi multiplicity of infection - r⁺ m⁺ restricting and modifying - r^- m^- mon-restricting and non-modifying - SSC 0.15M NaCl+0.015 M trisodium citrate - SDS sodium dodecyl sulphate     

Erythromycin resistant mutants of Bacillus subtilis

Summary Erythromycin resistant (ery ^r) mutants were isolated from Bacillus subtilis ATCC 6633. The composition of ribosomal proteins were analyzed for thirteen such ery ^r-mutants with chromatography on a carboxymethyl cellulose (CMC) column. The 50s subunit from all of the ery ^r-mutants was found to contain the altered 50d protein. The ribosomes prepared from the ery ^r-mutants did not show in vitro alteration of the ability to combine with erythromycin.     

Involvement of etfA gene during CaCO3 precipitation in Bacillus subtilis biofilm

The eftA gene in Bacillus subtilis has been suggested to be involved in the oxidation/reduction reactions during fatty acid metabolism. Interestingly etfA deletion in B. subtilis results in impairment in CaCO₃ precipitation on the biofilm. Comparisons between the wild type B. subtilis 168 and its etfA mutant during in vitro CaCO₃ crystal precipitation (calcite) revealed changes in phospholipids membrane composition with accumulation of up to 10% of anteiso-C_17:0 and 11% iso-C_17:0 long fatty acids. Ca²⁺ nucleation sites such as dipicolinic acid and teichoic acids seem to contribute to the CaCO₃ precipitation. etfA mutant strain showed up to 40% less dipicolinic acid accumulation compared with B. subtilis 168, while a B. subtilis mutant impaired in teichoic acids synthesis was unable to precipitate CaCO₃. In addition, B. subtilis etfA mutant exhibited acidity production leading to atypical flagella formation and inducing extensive lateral growth on the biofilm when grown on 1.4% agar. From the ecological point of view, this study shows a number of physiological aspects that are involved in CaCO₃ organomineralization on biofilms.     

Construction of a colony bank of E. coli containing hybrid plasmids representative of the Bacillus subtilis 168 genome. Expression of functions harbored by the recombinant plasmids in B. subtilis.

Summary A collection of about 2500 clones containing hybrid plasmids representative of nearly the entire genome of B. subtilis 168 was established in E. coli SK1592 by using the poly(dA)·poly(dT) joining method with randomly sheared DNA fragments and plasmid pHV33, a bifunctional vector which can replicate in both E. coli and B. subtilis. Detection of cloned recombinant DNA molecules was based on the insertional inactivation of the Tc gene occurring at the unique BamHI cleavage site present in the vector plasmid.Thirty individual clones of the collection were shown to hybridize specifically with a B. subtilis rRNA probe. CCC-recombinant plasmids extracted from E. coli were pooled in lots of 100 and used to transform auxotrophic mutants of B. subtilis 168. Complementation of these auxotrophic mutations was observed for several markers such as thr, leuA, hisA, glyB and purB. In several cases, markers carried by the recombinant plasmids were lost from the plasmid and integrated into the chromosomal DNA. Loss of genetic markers from the hybrid plasmids did not occur when a rec ^- recipient strain of B. subtilis was used.Abbreviations Ap^R resistance to ampicillin - Tc^R resistance to tetracycline - Cm^R resistance to chloramphenicol - CCC covalently closed circular duplex - Mdal magadalton     

Expression of sfp gene and hydrocarbon degradation by Bacillus subtilis

Bacillus subtilis C9 produces a lipopeptide-type biosurfactant, surfactin, and rapidly degrades alkanes up to a chain length of C₁₉. The nucleotide sequence of the sfp gene cloned from B. subtilis C9 was determined and its deduced amino acid sequence showed 100% homology with the sfp gene reported before [Nakano et al. (1992) Mol. Gen. Genet. 232: 313–321]. To transform a non-surfactin producer, B. subtilis 168, to a surfactin producer, the sfp gene cloned from B. subtilis C9 was expressed in B. subtilis 168. The transformed B. subtilis SB103 derivative of the strain 168 was shown to produce surfactin measured by its decrease in surface tension, emulsification activity, and TLC analysis of the surface active compound isolated from the culture broth. Like B. subtilis C9, B. subtilis SB103 containing sfp gene readily degraded aliphatic hydrocarbons (C_10–19), though its original strain did not. The addition of surfactin (0.5%, w/v) to the culture of B. subtilis 168 significantly stimulated the biodegradation of hydrocarbons of the chain lengths of 10–19; over 98% of the hydrocarbons tested were degraded within 24 h of incubation. These results indicate that the lipopeptide-type biosurfactant, surfactin produced from B. subtilis enhances the bioavailability of hydrophobic hydrocarbons.     

Effects of DNA Topology on Transformation Efficiency of Bacillus subtilis ISW1214 by Electroporation

We report an investigation of electrotransformation by three different topological isomers, circular supercoiled (sc DNA), circular relaxed (cr DNA), and linearized (In DNA) forms of the plasmids pUB110 (4.5 kbp) and pBDR331T (12.6 kbp), of a Gram-positive bacterium, Bacillus subtilis ISW1214. Treatment of the sc DNA with calf thymus topoisomerase I removed the superhelicity and the DNA assumed the relaxed circular form. Treatment of sc DNA with restriction endonuclease linearized the DNA. The transformation with the sc DNA of pUB110 resulted in the maximum efficiency of (2.6±0.6) × 10⁵ transformants per μg DNA higher than that ((2.0±0.3) × 10⁴ transformants per μg DNA) for the cr DNA, using the DNA concentration of 20 μg/ml at an electric field strength of 7kV/cm and a capacitance of 10 μF with a single decayed pulse. The transformation efficiency (TE) for the In DNA was zero. The variations of TE for different topological forms of DNA reflected their relative stability in the host cells. The molecular efficiency (ME, transformants per molecule) for sc DNA was nearly one order of magnitude greater for the lower molecular size of pUB110 DNA than that for the higher molecular size of pBDR331T DNA.     

Relationship between rates of respiratory proton extrusion and ATP synthesis in obligately alkaliphilic Bacillus clarkii DSM 8720T

To elucidate the energy production mechanism of alkaliphiles, the relationship between the rate of proton extrusion via the respiratory chain and the corresponding ATP synthesis rate was examined in obligately alkaliphilic Bacillus clarkii DSM 8720^T and neutralophilic Bacillus subtilis IAM 1026. The oxygen consumption rate of B. subtilis IAM 1026 cells at pH 7 was approximately 2.5 times higher than that of B. clarkii DSM 8720^T cells at pH 10. The H⁺/O ratio of B. clarkii DSM 8720^T cells was approximately 1.8 times higher than that of B. subtilis IAM 1026 cells. On the basis of oxygen consumption rate and H⁺/O ratio, the rate of proton translocation via the respiratory chain in B. subtilis IAM 1026 is expected to be approximately 1.4 times higher than that in B. clarkii DSM 8720^T. Conversely, the rate of ATP synthesis in B. clarkii DSM 8720^T at pH 10 was approximately 7.5 times higher than that in B. subtilis IAM 1026 at pH 7. It can be predicted that the difference in rate of ATP synthesis is due to the effect of transmembrane electrical potential (Δψ) on protons translocated via the respiratory chain. The Δψ values of B. clarkii DSM 8720^T and B. subtilis IAM 1026 were estimated as −192 mV (pH 10) and −122 mV (pH 7), respectively. It is considered that the discrepancy between the rates of proton translocation and ATP synthesis between the strains used in this study is due to the difference in ATP production efficiency per translocated proton between the two strains caused by the difference in Δψ.     

Regulation of Poly glutamate Production in Bacillus subtilis (natto): Transformation of High PGA Productivity

Bacillus subtilis (natto) produces a considerable amount of polyglutamate (PGA). The genetic character of high PGA productivity of B. subtilis (natto) was transferred by DNA-mediated transformation to B. subtilis Marburg 168 which cannot produce PGA. The enzyme activity of γ-glutamyltranspeptidase (γ-GTP) of the three transformants, 3F1, F1-9 and M5B4, was 124, 233 and 147 mU/ml, which is about 25, 250 and 100% of that of the donor strains, respectively. However, other enzyme activities such as those of alanine racemase or transaminase among the parental strains and representative transformants were almost the same.

These results suggested that γ-GTP activity might mainly participate in the biosynthesis of PGA in B. subtilis (natto).     

Expression of the cloned xylanases from an alkalophilic,thermophilic Bacillus in Bacillus subtilis

A recombinant plasmid construct, pLPX6.5, harbouring a 6.5 kb Hind III fragment of genomic DNA, from an alkalophilic, thermophilic Bacillus NCIM 59 and coding for xylanase activity, was electroporatically transformed into Bacillus subtilis MI 111. The expression of the recombinant xylanases was confirmed by cross-reactivity with antibodies raised against purified xylanase II (M _r 15,800) from NCIM 59. However, as there were different xylan hydrolysis products from NCIM 59 and the host B. subtilis, the two xylanases appear to have different modes of action. Xylanase expression in the transformants was 6-fold higher than in the host. There was no significant enhancement in the expression of recombinant xylanases by adding xylan to the growth medium.The authors are with the Division of Biochemical Sciences, National Chemical Laboratory, Pune-411008, India     

Characterization of pTZ12, a Chloramphenicol-resistance Plasmid in Bacillus subtilis

The chloramphenicol-resistance (CP^r) plasmid pTZ12 (2.55 kb) in Bacillus subtilis was genetically analyzed in detail, and the CP^r determinant and the functional unit of replication were mapped. The plasmids pTZ12 and pBR322 were digested with suitable restriction endonucleases and ligated with T4 ligase. The ligated DNAs were introduced into E. coli by transformation and CP-resistant transformants were selected. In conclusion, the CP^r determinant was mapped between a TaqI site and a BclI site (about 900 base pairs) on pTZ12. A set of pTZ12–pBR322 recombinant plasmids isolated from E. coli was introduced into B. subtilis by transformation to test for ability to replicate in B. subtilis. From the results, the region of the functional unit of pTZ12 replication was mapped. It was also proved that the gene product of this CP^r determinant was chloramphenicol acetyltransferase (CAT) and the native CAT in the cells carrying pTZ12 was a dimeric protein with two identical subunits having a molecular weight of approximately 24,000 (24 K).