Insertional mutagenesis in Bacillus subtilis: mechanism and use in gene cloning

The plasmid pHV32, which replicates in Escherichia coli but not in Bacillus subtilis, transformed B. subtilis-competent cells efficiently when linked in vitro to EcoRI B. subtilis DNA segments. The transformed clones carried pHV32 inserted in their chromosomes, and often displayed a mutant phenotype. One of the transformed clones carried pHV32 inserted close to the thyB gene. We cleaved the DNA extracted from this clone with BglII restriction endonuclease, for which no sites exist on pHV32, ligated the released segments and used them to transform E. coli selecting for pHV32-carried genetic markers. The transformants harbored a hybrid plasmid which carried the B. subtilis thyB gene. Circular molecules composed of pHV32 joined to B. subtilis DNA inserted into the chromosome by a Campbell-like recombination event. Linear molecules, in which pHV32 was flanked by two non-adjacent DNA segments, underwent a double cross-over recombination with the chromosome. In this case the chromosomal sequences between the non-adjacent segments were deleted, and replaced by pHV32 sequences.     

Bacillus subtilis (natto) plasmid pLS20 mediates interspecies plasmid transfer.

The 55-kilobase plasmid, pLS20, of Bacillus subtilis (natto) 3335 promotes transfer of the tetracycline resistance plasmid pBC16 from B. subtilis (natto) to the Bacillus species B. anthracis, B. cereus, B. licheniformis, B. megaterium, B. pumilus, B. subtilis, and B. thuringiensis. Frequency of pBC16 transfer ranged from 2.3 x 10(-6) to 2.8 x 10(-3). Evidence for a plasmid-encoded conjugationlike mechanism of genetic exchange includes (i) pLS20+ strains, but not pLS20- strains, functioned as donors of pBC16; (ii) plasmid transfer was insensitive to the presence of DNase; and (iii) cell-free filtrates of donor cultures did not convert recipient cells to Tcr. Cotransfer of pLS20 and pBC16 in intraspecies matings and in matings with a restriction-deficient B. subtilis strain indicated that pLS20 was self-transmissible. In addition to mobilizing pBC16, pLS20 mediated transfer of the B. subtilis (natto) plasmid pLS19 and the Staphylococcus aureus plasmid pUB110. The fertility plasmid did not carry a selectable marker. To facilitate direct selection for pLS20 transfer, plasmid derivatives which carried the erythromycin resistance transposon Tn917 were generated. Development of this method of genetic exchange will facilitate the introduction of plasmid DNA into nontransformable species by use of transformable fertile B. subtilis or B. subtilis (natto) strains as intermediates.     

recE4-Independent recombination between homologous deoxyribonucleic acid segments of Bacillus subtilis plasmids.

A plasmid (pLS104) carrying a tandem repetition of the leu region of the Bacillus subtilis chromosome arose spontaneously from pLS103, which carried a single copy of the leu region. Plasmid preparations from strains harboring pLS104 also contained the original plasmid, pLS103, and, in some preparations, plasmids carrying three or four repetitions of the leu region. These plasmids were shown to be generated by recombination between homologous deoxyribonucleic acid (DNA) segments in the tandemly repeated DNA regions on the plasmids, but not by recombinations between specific DNA sites. These phenomena were observed in a recE4-Independent background, showing that recombination of the homologous DNA sequences does not require the recE-Independent gene product(s).     

Construction of a recombinant plasmid composed of B. subtilis leucine genes and a B. subtilis (natto) plasmid: its use as cloning vehicle in B. subtilis 168.

Summary Recombinant plasmids composed of Bacillus subtilis 168 leucine genes and a B. subtilis (natto) plasmid have been constructed in a recombination deficient (recE4) mutant of Bacillus subtilis 168. The process involved EcoRI fragmentation and ligation of a B. subtilis (natto) plasmid and a composite plasmid RSF2124-B · leu in which B. subtilis 168 leucine genes are linked to the R-factor RSF2124. A constructed plasmid (pLS102) was found to be composed of an EcoRI fragment derived from the vector plasmid and two tandemly repeated EcoRI fragments carrying the leucine genes. A derivative plasmid (pLS101 or pLS103) consisting of one molecule each of the EcoRI fragments was obtained by in vivo intramolecular recombination between the repeated leucine gene fragments in pLS102. pLS103 was cleaved once with BamNI, SmaI and HpaI. Insertion of foreign DNA (Escherichia coli plasmid pBR322) into the BamNI site inactivated leuA but not the leuC function which thus can serve as selective marker if the plasmid is used as vector in molecular cloning. The penicillin resistance carried in pBR322 was not functionally expressed in B. subtilis cells. By partial digestion of pLS103 with HindIII followed by ligation with T4-induced ligase, pLS107 was obtained which contained only one EcoRI site. However, insertion of exogenous DNA (pBR322) into this EcoRI site inactivated both leuA and leuC functions.     

Experimental basis for a stable plasmid, pLS30, to shuttle between Bacillus subtilis species by conjugational transfer

The use of Bacillus subtilis 168 as the initial host for molecular cloning and subsequent delivery of the engineered DNA to other Bacillus hosts appears attractive, and would lead to an efficient DNA manipulation system. However, methods of delivery to other Bacillus species are limited due to their inability to develop natural competence. An alternative, unexplored conjugational transfer method drew our attention and a B. subtilis native plasmid, pLS30, isolated from B. subtilis (natto) strain IAM1168 was characterized for this aim. The nucleotide sequence (6,610 bp) contained the mob gene and its recognition sequence, oriT, that features pLS30 as a mobile plasmid between Bacillus species on conjugational transfer. Plasmid pLS3001, a chimera with a pBR322-based plasmid prepared in Escherichia coli to confer an antibiotic resistance marker, showed apparent mobilizing activity in the pLS20-mediated conjugational transfer system recently established. The rep gene and associated palT1-like sequence common to all other pLS plasmids previously sequenced indicated that pLS30 is a typical rolling circle replicating (RCR) type plasmid. Due to the significant stability of pLS30 in IAM1168, application of a mobile plasmid would allow quick propagation to Bacillus species.     

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.     

Studies on transfection and transformation of protoplasts of Bacillus larvae, Bacillus subtilis, and Bacillus popilliae.

Protoplasts of Bacillus larvae NRRL b-3555 and Bacillus subtilis RM125 (restrictionless, modificationless mutant) were transfected with DNA from the B. larvae bacteriophage PBL1c in the presence of polyethylene glycol. B. subtilis 168 and Bacillus popilliae NRRL B-2309M protoplasts could not be transfected with PBL1c DNA. Protoplasts of B larvae NRRL B-3555 were transformed with plasmids pC194 and pHV33 in the presence of polyethylene glycol. The frequency of transformation was much higher when the plasmids were isolated from B. larvae NRRL B-3555 transformants than when they were isolated from B. subtilis 168. These results indicate that the restriction-modification systems found in B. larvae NRRL B-3555 and B. subtilis 168 may be different. Conditions for protoplast formation and cell wall regeneration were developed for B. popilliae NRRL B-2309S. However, no transformation occurred with plasmids pC194 and pHV33 (isolated from B. subtilis 168).     

Studies on transfection and transformation of protoplasts of Bacillus larvae, Bacillus subtilis, and Bacillus popilliae

Protoplasts of Bacillus larvae NRRL b-3555 and Bacillus subtilis RM125 (restrictionless, modificationless mutant) were transfected with DNA from the B. larvae bacteriophage PBL1c in the presence of polyethylene glycol. B. subtilis 168 and Bacillus popilliae NRRL B-2309M protoplasts could not be transfected with PBL1c DNA. Protoplasts of B larvae NRRL B-3555 were transformed with plasmids pC194 and pHV33 in the presence of polyethylene glycol. The frequency of transformation was much higher when the plasmids were isolated from B. larvae NRRL B-3555 transformants than when they were isolated from B. subtilis 168. These results indicate that the restriction-modification systems found in B. larvae NRRL B-3555 and B. subtilis 168 may be different. Conditions for protoplast formation and cell wall regeneration were developed for B. popilliae NRRL B-2309S. However, no transformation occurred with plasmids pC194 and pHV33 (isolated from B. subtilis 168).     

Cloning vehicles for the homologous Bacillus subtilis host-vector system

A series of Bacillus subtilis plasmids was constructed which carry either the leu region or both the leu and the dihydrofolate reductase (DHFR) regions of the B. subtilis chromosome. The DHFR-coding gene was derived from a trimethoprim resistant (Tmpr) B. subtilis strain, and cells harboring the DHFR plasmid showed resistance to trimethoprim (Tmp). One such leu+tmpr plasmid, pTL12, was found to be useful for cloning DNA fragments at the BamHI, EcoRI, BglII and XmaI sites. It was also shown that insertion of DNA fragments at the BamHI and XmaI sites of pTL12 inactivated the leuA gene function (insertional inactivation) but not tmpr, indicating that cells carrying recombinant plasmids can be detected easily by selecting Leu-Tmpr colonies. Combination of B. subtilis 168 and plasmid pTL12 should serve as an efficient homologous cloning system in B. subtilis.     

Recombinational transfer of 100-kilobase genomic DNA to plasmid in Bacillus subtilis 168

Transformation of Bacillus subtilis by a plasmid requires a circular multimeric form. In contrast, linearized plasmids can be circularized only when homologous sequences are present in the host genome. A recombinational transfer system was constructed with this intrinsic B. subtilis recombinational repair pathway. The vector, pGETS103, a derivative of the theta-type replicating plasmid pTB19 of thermophilic Bacillus, had the full length of Escherichia coli plasmid pBR322. A multimeric form of pGETS103 yielded tetracycline-resistant transformants of B. subtilis. In contrast, linearized pGETS103 gave tetracycline-resistant transformants only when the recipient strain had the pBR322 sequence in the genome. The efficiency and fidelity of the recombinational transfer of DNAs of up to 90 kb are demonstrated.     

Protoplast transformation of Bacillus stearothermophilus NUB36 by plasmid DNA

An efficient protoplast transformation system was established for Bacillus stearothermophilus NUB3621 using thermophilic plasmid pTHT15 Tcr (4.5 kb) and mesophilic plasmid pLW05 Cmr (3 kb), a spontaneous deletion derivative of pPL401 Cmr Kmr. The efficiency of transformation of NUB3621 with pLW05 and pTHT15 was 2 x 10(7) to 4 x 10(8) transformants per micrograms DNA. The transformation frequency (transformants per regenerant) was 0.5 to 1.0. Chloramphenicol-resistant and tetracycline-resistant transformants were obtained when competent cells of Bacillus subtilis were transformed with pLW05 [2.5 x 10(5) transformants (microgram DNA)-1] and pTHT15 [1.8 x 10(5) transformants (micrograms DNA)-1], respectively. Thus, these plasmids are shuttle vectors for mesophilic and thermophilic bacilli. Plasmid pLW05 Cmr was not stably maintained in cultures growing at temperatures between 50 and 65 degrees C but the thermostable chloramphenicol acetyltransferase was active in vivo at temperatures up to 70 degrees C. In contrast, thermophilic plasmid pTHT15 Tcr was stable in cultures growing at temperatures up to 60 degrees C but the tetracycline resistance protein was relatively thermolabile at higher temperatures. The estimated copy number of pLW05 in cells of NUB3621 growing at 50, 60, and 65 degrees C was 69, 18, and 1 per chromosome equivalent, respectively. The estimated copy number of pTHT15 in cells of NUB3621 growing at 50 or 60 degrees C was about 41 to 45 per chromosome equivalent and 12 in cells growing at 65 degrees C.     

双抗性质粒pSC33、pSC48的构建及其特性研究

截短的短小芽孢杆菌质粒pCJ3与去除了复制功能的金黄色葡萄球菌质粒PUB110经EcoRI酶切,DNA连接酶连接后组建T_o~r及K_m~r的双抗性的重组质粒pSC33和和PSC48。根据电泳迁移率估算pSC33及pSC48的大小分别为6.7及6.27Kb。具有BamHⅠ、AVaⅠ、XbaⅠ及BgLⅡ等限制酶的单切点,其中BgLⅡ切点位于卡那霉素抗性基因内。pSC33及pSC48能转化枯草杆菌各种突变体的感受态细胞,转化率比亲本质粒高一个数量级,也能转化枯草杆菌的原生质体。pSC33及pSC48在枯草杆菌BR151中表现稳定,以PSC48和载体克隆了滑鼠蛇肝线粒体DNA片段。     

Recombination between compatible plasmids containing homologous segments requires the Bacillus subtilis recE gene product.

Plasmid pSL103 was previously constructed by cloning a Trp fragment (approximately 2.3 X 10(6) daltons) from restriction endonuclease EcoRI-digested chromosome DNA of Bacillus pumilus using the neomycin-resistance plasmid pUB110 (approximately 2.8 X 10(6) daltons) as vector and B. subtilis as transformation recipient. In the present study the EcoRI Trp fragment from pSL103 was transferred in vitro to EcoRI fragments of the Bacillus plasmid pPL576 to determine the ability of the plasmid fragments to replicate in B. subtilis. Endonuclease EcoRI digestion of pPL576 (approximately 28 X 10(6) daltons) generated three fragments having molecular weights of about 13 X 13(6) (the A fragment), 9.5 X 10(6) (B fragment, and 6.5 X 10(6) (C fragment). Trp derivatives of pPL576 fragments capable of autonomous replication in B. subtilis contained the B fragment (e.g., pSL107) or both the B and C fragments (e.g., pSL108). Accordingly, the B fragment of pPL576 contains information essential for autonomous replication. pSL107 and pSL108 are compatible with pUB110. Constructed derivatives of the compatible plasmids pPL576 and pUB110, harboring genetically distinguishable EcoRI-generated Trp fragments cloned from the DNA of a B. pumilus strain, exhibited relatively high frequency recombination for a trpC marker when the plasmid pairs were present in a recombination-proficient strain of B. subtilis. No recombination was detected when the host carried the chromosome mutation recE4. Therefore, the recE4 mutation suppresses recombination between compatible plasmids that contain homologous segments.     

Extrachromosomal Recombination Is Deranged in the Rec2 Mutant of Ustilago Maydis

Transformation of a leu1 auxotroph of Ustilago maydis to prototrophy with an autonomously replicating plasmid containing the selectable LEU1 gene was found to be efficient regardless of whether the transforming DNA was circular or linear. When pairs of autonomously replicating plasmids bearing noncomplementing leu1 alleles were used to cotransform strains deleted entirely for the genomic copy of the LEU1 gene, Leu+ transformants were observed to arise by extrachromosomal recombination. The frequency of recombination increased severalfold when one plasmid of the pair was made linear by cleavage at one end of the leu1 gene, but increased 10-100-fold when both plasmids were first made linear. The increase in recombination noted in wild-type and rec1 strains was not apparent in the rec2 mutant unless the members of the pair of plasmids were cut at opposite ends of the leu1 gene to yield linear molecules offset in only one of the two possible configurations. Use of a pair of plasmid substrates designed to measure nonreciprocal and multiple exchange events revealed only a minor fraction of the total events arise through these modes, and further that no stimulation occurred when the plasmid DNA was linear. It is unlikely that the defect in rec2 lies in a mismatch correction step since a high yield of Leu+ recombinants was obtained from the rec2 mutant when it was transformed with heteroduplex DNA constructed from plasmids with the two different leu1 alleles.     

Cloning and structure of the gene for the subunits of aspartokinase II from Bacillus subtilis

A library of Bacillus subtilis DNA in lambda Charon 4A (Ferrari, E., Henner, D.J., and Hoch, J.A. (1981) J. Bacteriol. 146, 430-432) was screened by an immunological procedure for DNA sequences encoding aspartokinase II of B. subtilis, an enzyme composed of two nonidentical subunits arranged in an alpha 2 beta 2 structure (Moir, D., and Paulus, H. (1977a) J. Biol. Chem. 252, 4648-4654). A recombinant bacteriophage was identified that harbored an 18-kilobase B. subtilis DNA fragment containing the coding sequences for both aspartokinase subunits. The coding sequence for aspartokinase II was subcloned into bacterial plasmids. In response to transformation with the recombinant plasmids, Escherichia coli produced two polypeptides immunologically related to B. subtilis aspartokinase II with molecular weights (43,000 and 17,000) indistinguishable from those found in enzyme produced in B. subtilis. Peptide mapping by partial proteolysis confirmed the identity of the polypeptides produced by the transformed E. coli cells with the B. subtilis aspartokinase II subunits. The size of the cloned B. subtilis DNA fragment could be reduced to 2.9 kilobases by cleavage with PstI restriction endonuclease without affecting its ability to direct the synthesis of complete aspartokinase II subunits, irrespective of its orientation in the plasmid vector. Further subdivision by cleavage with BamHI restriction endonuclease resulted in the production of truncated aspartokinase subunits, each shortened by the same extent. This suggested that a single DNA sequence encoded both aspartokinase subunits and provided an explanation for the earlier observation that the smaller beta subunit of aspartokinase II was highly homologous or identical with the carboxyl-terminal portion of the alpha subunit (Moir, D., and Paulus, H. (1977b) J. Biol. Chem. 252, 4655-4661). A map of the gene for B. subtilis aspartokinase II is proposed in which the coding sequence for the smaller beta subunit overlaps in the same reading frame the promoter-distal portion of the coding sequence for the alpha subunit.     

Isolation and characterization of a recombinant plasmid carrying a functional part of the Bacillus subtilis spoIIA locus

Plasmid pHM2 consists of a 3.3 kb insert of Bacillus subtilis DNA in the chimeric plasmid pHV33, and can replicate in Escherichia coli and B. subtilis. In B. subtilis, pHM2 complements the defects resulting from mutations spo-42, spo-50, spo-69 and sas-1 in the spoIIA locus. This complementation can occur in recE4 strains where recombination of the plasmid with the chromosome is prevented, and the chromosome retains the mutant allele. Thus the plasmid carries a functional part of the spoIIA locus; it does not contain the complete locus as it cannot complement several other spoIIA mutations. It is likely that the locus is complex, containing at least two genes.     

The mechanism of insertion of a segment of heterologous DNA into the chromosome of Bacillus subtilis

An Escherichia coli plasmid, p1949, that is derived from pMB9 and pC194, and unable to replicate in Bacillus subtilis, can give rise to stable CmR transformants of the latter species if it is inserted into the bacterial chromosome. A purified segment of the B. subtilis chromosome, with transforming activity against pheA1 and nic-38 recipients, was used to direct the insertion of p1949 into the B. subtilis chromosome. Insertion of the ligated DNA segments occurred in the region of the chromosome from which the purified phe-nic segment was derived. Many of the properties of the resulting CmR transformants of B. subtilis are consistent with the occurrence of a Campbell recombination mechanism leading to integration. However, certain of these properties are more easily explained if it is proposed that integration occurs by a reciprocal recombination event involving a linear ligation product. Evidence is presented suggesting that the inserted sequences may be tandemly duplicated. This may effectively vitiate the use of p1949 as a convenient means for complementation analysis of recessive mutations in B. subtilis.     

Random mutagenesis by recombinational capture of PCR products in Bacillus subtilis and Acinetobacter calcoaceticus.

We describe a general method for random mutagenesis of cloned genes by error-prone PCR or DNA shuffling that eliminates the need for post-amplification subcloning following each cycle of mutagenesis. This method exploits the highly efficient and recombinogenic nature of DNA uptake during natural transformation in the Gram-positive bacterium Bacillus subtilis and the Gram-negative bacterium Acinetobacter calcoaceticus. Plasmid systems were designed that allow capture of PCR-amplified DNA fragments by marker-replacement recombination with a structurally similar helper plasmid resident in the transformation recipient. This recombination event simultaneously transfers the amplified sequences into the helper plasmid and restores the integrity of a drug resistance gene, thereby affording a direct selection for fragment capture. Although this strategy was sufficiently effective to permit recovery in B. subtilis of up to 10(3) transformants/microgram of PCR product, equivalent plasmid systems were approximately 100 times more efficient in A.calcoaceticus. Acinetobacter calcoaceticus also offers the advantage of essentially constitutive transformation competence in ordinary complex broth, such as LB, in contrast to two-step growth in semi-synthetic media required for optimal transformation of B.subtilis.