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     

Plasmid transformation in Bacillus subtilis: effects of insertion of Bacillus subtilis DNA into plasmid pC194

Summary We have constructed a hybrid plasmid, pBC1, which consists of plasmid pC194 with an insert of B. subtilis DNA at its HindIII restriction site. This plasmid is stably maintained in B. subtilis. In contrast with pC194, monomeric ccc forms of pBC1 are active in transformation. Transformations with these monomeric molecules of pBC1 have a stringent requirement for recombination proficieny., as defined by recE in the recipient cell. The extent of dependence of the transforming activity of oligomeric pBC1 DNA on the recombination proficiency of the recipient cell decreases with increasing oligomer size. A model of DNA proccssing during plasmid transformation of B. subtilis is presented.     

In vitro genetic labeling of Bacillus subtilis cryptic plasmid pHV400.

A DNA segment which encodes resistance to tetracycline, and cannot replicate autonomously, was excised by HindIII endonuclease from plasmid pT127 and joined to the cryptic Bacillus subtilis plasmid pHV400. The analysis of resulting chimerae has allowed us to identify a 1.8 × 10⁶ segment of pHV400 which carried the replication functions of the cryptic plasmid. Another DNA segment, designated pHV32, which can replicate in Escherichia coli but not in B. subtilis has also been used for genetic labeling of the replication region of pHV400. pHV32 is convenient for use in isolating cryptic replicons active in B. subtilis because (1) it can be prepared in large quantities, free from any interferring B. subtilis replicons, from an appropriate E. coli strain; (2) it carries unique sites for various restriction endonucleases; (3) the chloramphenicol resistance gene which it specifies can transform B. subtilis at a high efficiency (10⁶–10⁷ transformants/μg of DNA).     

Plasmid transformation in Bacillus subtilis: Fate of plasmid DNA

Summary Only multimeric, and not monomeric forms of B. subtilis plasmids can transform B. subtilis cells (Canosi et al. 1978). This finding prompted us to study the physico-chemical fate of plasmid DNA in transformation. Competent cells of B. subtilis were exposed to either unfractionated preparations or to preparations of multimeric plasmid DNA. Plasmid DNA was re-extracted from such cells and then analyzed by sedimentation and isopycnic centrifugation and also defined by its sensitivity to nuclease S1 degradation. No double-stranded plasmid DNA could be recovered from cells transformed with unfractionated plasmid preparations which contained predominantly monomeric covalently closed circular (CCC) DNA, Re-extracted plasmid DNA was single-stranded, had a molecular weight considerably smaller than monomer length DNA and had been subject to degradation to acid soluble products. However, when transformations were performed with multimeric DNA (constructed by in vitro ligation of linearized pC194 DNA), both double-stranded and partially double-stranded DNA could be recovered in addition to single-stranded DNA.We assume that plasmid DNA is converted to a single-stranded form in transformation, irrespective of its molecular structure. Double-stranded and partially double-stranded DNAs found in transformation with multimeric DNA would be the products of intramolecular annealing.Some of these results were presented at the 5th European Meeting on Bacterial Transformation and Transfection, September 1980, Florence     

Restriction and modification in Bacillus subtilis Marburg 168: target sites and effects on plasmid transformation

Summary The effects of the restriction system of Bacillus subtilis strain M on plasmid transformation were studied. Plasmid pHV1401 DNA prepared from B. subtilis transformed the restriction-proficient M strain 100 times more efficiently than the DNA prepared from Escherichia coli, while the two DNA preparations transformed restriction-deficient derivatives of that strain with similar efficiencies. This indicates that transformation with pHV1401 is sensitive to the M restriction system. pHV1401 contains three CTCGAG (XhoI sites). Successive removal of these abolished the effect of restriction. This indicates that the XhoI sites are the targets for the M restriction system.Abbreviations used Ap^r resistance to ampicillin - Cm^r resistance to chloramphenicol - R/M restriction and modification - Tc^r resistance to tetracycline     

Cloning and expression of Bacillus subtilis spore genes

Summary Two spore genes, spoOB and spoIIG have been cloned from the B. subtilis genome library, constructed by ligating Sau3A partially digested DNA to the dephosphorylated pHV33 plasmid vector at its BamH1 site.An hybrid plasmid pGsOB2, carrying a 1.7 Kb insert of B. subtilis DNA amplifiable in E. coli was cloned. This recombinant plasmid was capable of transforming the appropriate B. subtilis Rec⁺ and Rec^- recipients to Spo⁺ at very high efficiency. The pGsOB2 was further subcloned and four hybrid plasmids, pGsOB8, pGsOB9, pGsOB10 and pGsOB11 were selected and their restriction enzyme maps established. The four subcloned hybrid plasmids retained their entire transforming activity in both Rec⁺ and Rec^- recipients although two of them carry the insert in an inverse orientation, indicating thus, that the spoOB gene in these plasmids is being transcribed by the B. subtilis RNA polymerase using an internal promotor of the cloned DNA fragment. The adjacent genes spoIVF and pheA, mapped respectively to the right and left of the spoOB locus, that normally show 90% cotransformation, are absent on the cloned DNA fragments. The cloned hybrid plasmids have been expressed in E. coli minicells and it was shown that the spoOB locus encoded a polypeptide of 24 K.We have also cloned the spoIIG gene in two hybrid plasmids, pGsIIG24 and pGsIIG26, carrying respectively inserts of 2 and 3 Kb. From the transforming activity and the endonuclease cleavage maps it was shown that these two hybrid plasmids do not carry the entire spoIIG locus. The use of these plasmids for further cloning of this gene is discussed.     

Release of transforming plasmid and chromosomal DNA from two cultured soil bacteria

The release of chromosomal and plasmid DNA from Acinetobacter calcoaceticus and Bacillus subtilis cultivated in minimal medium and broth over a period of 50 h was monitored and related to growth phase, autolysis, DNase production and natural competence. The released DNAs were biologically active in natural transformation. In addition, the circular integrity of a released B. subtilis shuttle vector (pHV14) was demonstrated by artificial transformation of Escherichia coli. In cultures of both strains high molecular weight DNA accumulated, particularly during the stationary and death phase (up to 30 g ml^-1). Generally, despite the presence in culture fluids of DNase activity (and of an intracellular enzyme, catalase, indicating some cell lysis) there was high transforming activity of chromsomal and plasmid DNA even 40 h after the cultures reached the stationary phase. In cultures of B. subtilis in minimal medium a presumably active release of intact plasmids and chromsomal DNA occurred during the competence phase. The release of biologically functional DNA during essentially all growth phases of a gram-positive and a gram-negative member of soil bacteria might facilitate horizontal gene transfer by transformation in natural habitats.     

Cloning and expression inEscherichia coli of the sucrase gene fromBacillus subtilis

Summary A recombinant cosmid carrying the sucrase gene (sacA) was obtained from a colony bank ofE. coli harboring recombinant cosmids representative of theB. subtilis genome. It was shown that thesacA gene is located in a 2 kbEcoRI fragment and that the cloned sequence is homologous to the corresponding chromosomal DNA fragment. A fragment of 2 kb containing the gene was subcloned in both orientations in the bifunctional vector pHV33 and expression was further looked for inB. subtilis andE. coli. Complementation of asacA mutation was observed in Rec⁺ and Rec^- strains ofB. subtilis. Expression of sucrase was also demonstrated inE.coli, which is normally devoid of this activity, by SDS-polyacrylamide gel electrophoresis, specific immunoprecipitation and assay of the enzyme in crude extracts. The specific activity of the enzyme depended on the orientation of the inserted fragment. The saccharolytic activity was found to be cryptic inE. coli since the presence of the recombinant plasmids did not allow the transport of [U¹⁴C] sucrose and the growth of the cells.It was shown also that the recombinant cosmid contained part of the neighboring locus (sacP) which corresponds to a component of the PEP-dependent phosphotransferase system of sucrose transport ofB. subtilis.     

A bifunctional plasmid carrying the recA gene of E. coli

Summary To investigate the effect of an active, plasmid-carried recA gene on the stability and/or the expression of plasmid genes in different genetic backgrounds, we have constructed a bifunctional plasmid (able to replicate in Escherichia coli and in Bacillus subtilis). Chimeric plasmids were obtained by inserting pC194 (Ehrlich 1977) into pDR1453 (Sancar and Rupp 1979). pDR1453 is a 12.9 Kbp plasmid constructed by inserting an E. coli chromosome fragment carrying the recA gene into pBR322. The expected bifunctional recombinant (pMR22/1) (15.7 Kbp) was easily obtained but surprisingly the Cm resistance was expressed only at a very low level in E. coli (as compared, for example, to pHV14, pHV15). We attribute this effect to the presence of multiple recA genes in the cell. On the contrary, Cm^r E. coli transformants bear a recombinant plasmid (pMR22/n) containing tandemly repeated copies of pC194 in equilibrium with excised free pC194. Such amplification has never been observed in a Rec^- background and is therefore mediated by the recA genes. Growth of these clones in the absence of Cm causes the loss of the extra copies, yielding a plasmid with a single copy of pC194, indistingishable from pMR22/1. Interestingly, we have observed that deletions occur at high frequency in pC194, which drastically increase Cm^r in E. coli containing plasmids with a single copy of pC194. Two types of such deletions were detected: (a) large 1050 bp deletions covering about onethird of pC194 and (b) small 120–150 bp deletions (near the MspI site) in the region containing the replicative functions of pC194 (Horinouchi and Weisblum 1982). Both types of deletion render the recombinant plasmid unable to replicate in B. subtilis. pM22/1 replicates, although with a low copy-number, and is stable in B. subtilis wild type; the recA gene of E. coli does not complement any of the rec ^- mutations of B. subtilis. A strong instability, mainly of the E. coli and pBR322 sequences, was observed in many dna and rec mutants of B. subtilis yielding smaller plasmid with a much higher copy-number.     

Characterization of plasmid transformation in Bacillus subtilis: kinetic properties and the effect of DNA conformation.

Summary Transformation of competent cells of Bacillus subtilis with antibiotic resistance plasmid DNA has shown that (a) competence for plasmid and chromosomal DNA develops with similar kinetics; (b) DNA linearized with a variety of restriction endonucleases does not transform; (c) CCC plasmid DNA is inactivated for transformation by a single nick; (d) T4 ligase restores transforming activity to both nicked and linearized DNA; (e) CCC relaxed DNA is fully active in transformation; (f) the DNA concentration-dependence of plasmid transformation is first order; and (g) plasmid transformation proceeds with a low efficiency, requiring the uptake of 10³ to 10⁴ DNA molecules per transformant.Based on this information, a model for the processing of chromosomal, plasmid and transfecting DNA is proposed.Abbreviations Cm Chloramphenicol - Em erythromycin - Km kanamycin - Sm streptomycin - CCC covalently closed circular - TBAB tryptose blood agar base - NCE nicking and closing enzyme In partial fulfillment of the requirements for the doctoral degree in the Department of Microbiology at the New York University School of Medicine, for S.C.     

Transformation of Bacillus subtilis by DNA bound on clay in non-sterile soil

Abstract Chromosomal DNA from Bacillus subtilis and different forms of plasmid pHV14 (covalently closed circular (CCC), linear monomer (M), and linear multimer (LM)) were adsorbed and bound on the clay mineral montmorillonite. After extensive washing of the clay-DNA complexes with DNA buffer (pH 7.5), approx. 25% of the chromosomal DNA, and approx. 30, 90, and 5%, respectively, of the CCC, M and LM form remained bound. Chromosomal and plasmid DNA bound on clay were capable of transforming competent cells, with different specific activities. The clay-DNA complexes persisted in non-sterile soil and retained transforming ability up to 15 days after their addition to the soil. DNA bound on montmortillonite was protected from the activity of Eco RI, supporting the evidence that DNA adsorbed on soil components was resistant to degradation by nucleases.     

A quantitative analysis of shotgun cloning in Bacillus subtilis protoplasts

Summary We used the Escherichia coli-Bacillus subtilis shuttle vector pHP13, which carries the replication functions of the cryptic B. subtilis plasmid pTA1060, to study the effects of BsuM restriction, plasmid size and DNA concentration on the efficiency of shotgun cloning of heterologous E. coli DNA in B. subtilis protoplasts. In a restriction-deficient strain, clones were obtained with low frequency (19% of the transformants contained a recombinant plasmid) and large inserts (>6 kb) were relatively rare (12% of the clones contained inserts in the range of 6–9 kb). The efficiency of shotgun cloning was severely reduced in restricting protoplasts: the class of large inserts (>6 kb) was under-represented in the clone bank (4% of the clones contained inserts in the range of 6–6.1 kb). Furthermore, BsuM restriction caused structural instability of some recombinant plasmids. Transformation of protoplasts with individual recombinant plasmids showed that plasmid size and transforming activity were negatively correlated. The size effect was most extreme with cut and religated plasmid DNA. The yield of clones was independent of the DNA concentration during transformation. It is therefore unlikely that clones were not detected because of simultaneous uptake of more than one plasmid. It is concluded that shotgun cloning in B. subtilis protoplasts is inferior to that in competent cells.     

Generation of deletions through a cis-acting mutation in plasmid pC194

Summary When plasmid pC194-1 is ligated to pBR322 to generate plasmid pHV15-1, deletions occur with high frequency within the joined pBR322 DNA. Generation of deletions is recE4 independent, and occurs in B. subtilis with a 1,000-fold higher frequency than in Escherichia coli. In the hybrid plasmid pVH15-1, deletion end-points are not at random, but at defined locations within pBR322. We propose that the base alteration, characterizing pC194-1, has stabilized within the plasmid a stem/loop structure, which acts as a deletion generator.     

Direct plasmid transfer from replica-plated E. coli colonies to competent B. subtilis cells. Identification of an E. coli clone carrying the hisH and tyrA genes of B. subtilis

Summary We have cloned the hisH tyrA wild-type genes of Bacillus subtilis with the aid of the chimeric plasmid pBJ194, which replicates both in B. subtilis and Escherichia coli. Primary cloning was done in E. coli. The original E. coli clone, carrying the recombinant plasmid (pGR1) which complements hisH tyrA mutants of B. subtilis, was selected directly from a mixture of plated E. coli clones by replicaplating these clones onto minimal agar plates without tyrosine spread just before with competent B. subtilis cells. After overnight incubation clusters of small colonies had developed exclusively in the E. coli [pGR1] colony prints.The Tyr⁺ minicolonies were shown to be B. subtilis carrying pGR1 because (i) their appearance depended linearly on the number of B. subtilis cells plated, (ii) they produced extracellular protease and amylase and (iii) plasmids could be reisolated from the minicolonies and used to transform B. subtilis recE4 tyrA1 both to Cm^r and Tyr⁺.Plasmid pGR1 transfer through replica plating was compared with plasmid transfer in liquid. Both systems depended on transformable B. subtilis strains and were sensitive to DNAseI. However, whereas integration of the tyrA ⁺ gene into the chromosome and concomittant loss of plasmids occurred frequently during regular plasmid transformation of Rec⁺ B. subtilis, this was a rare event during plasmid transfer through replica plating.     

Across Genus Plasmid Transformation Between <Emphasis Type="Italic">Bacillus subtilis</Emphasis> and <Emphasis Type="Italic">Escherichia coli</Emphasis> and the Effect of <Emphasis Type="Italic">Escherichia coli</Emphasis> on the Transforming Ability of Free Plasmid DNA

The results presented in this article show that direct plasmid transfer from Escherichia coli carrying shuttle plasmid to Bacillus subtilis occurred when close contact between the two species was established by mixing E. coli and B. subtilis onto selective agar plates. The data demonstrate that the production of resistant colonies by plasmid transformation through cell contact was DNase I sensitive and dependent on transformable B. subtilis strains. Furthermore, another observation indicated that the E. coli strain is able to affect the transformation capability of B. subtilis. It is assumed that the donor strain is a momentous factor for taking up plasmid DNA. This conclusion is significant in the assessment of both the possibility of intercellular DNA transfer in natural habitats of micro-organisms and the risk of the application of genetically engineered micro-organisms.     

Segregational instability of pUB110-derived recombinant plasmids in Bacillus subtilis

To study plasmid instability in Bacillus subtilis the pUB110-derived hybrid plasmid pLB2 (3.6 kb) and the bifunctional replicon pLB5 (5.9 kb), able to replicate in B. subtilis and Escherichia coli, were constructed. In both vectors homologous B. subtilis, or heterologous E. coli DNA fragments of various lengths were inserted. Irrespective of the source of the cloned DNA, the segregational stability of the recombinant plasmids in B. subtilis was severely affected by the DNA inserts. In contrast, no instability was observed in E. coli. In B. subtilis a steep inverse relationship existed between the size of the inserts and the level of stability. Increased size of the pLB plasmids resulted in strongly reduced copy numbers. This seems to be the primary cause of the size-dependent segregational instability.     

Recombinant plasmids capable to replication in B. subtilis and E. coli.

Summary The plasmid pBC16 (4.25 kbases), originally isolated from Bacillus cereus, determines tetracycline resistance and can be transformed into competent cells of B. subtilis. A miniplasmid of pBC16 (pBC16-1), 2,7 kb) which has lost an EcoRI fragment of pBC16 retains the replication functions and the tetracycline resistance. This plasmid which carries only one EcoRI site has been joined in vitro to pBS1, a cryptic plasmid previously isolated from B. subtilis and shown to carry also a single EcoRI site (Bernhard et al., 1978). The recombinant plasmid is unstable and dissociates into the plasmid pBS161 (8.2 kb) and the smaller plasmid pBS162 (2.1 kb). Plasmid pBS161 retains the tetracycline resistance. It possesses a single EcoRI site and 6 HindIII sites. The largest HindIII fragment of pBS161 carries the tetracycline resistance gene and the replication function. After circularization in vitro of this fragment a new plasmid, pBS161-1 is generated, which can be used as a HindIII and EcoRI cloning vector in Bacillus subtilis.Hybrid plasmids consisting of the E. coli plasmids pBR322, pWL7 or pAC184 and different HindIII fragments of pBS161 were constructed in vitro. Hybrids containing together with the E. coli plasmid the largest HindIII fragment of pBS161 can replicate in E. coli and B. subtilis. In E. coli only the replicon of the E. coli plasmid part is functioning whereas in B. subtilis replication of the hybrid plasmid is under the control of the Bacillus replicon. The tetracycline resistance of the B. subtilis plasmid is expressed in E. coli, but several antibiotic resistances of the E. coli plasmids (ampicillin, kanamycin and chloramphenicol) are not expressed in B. subtilis. The hybrid plasmids seem to be more unstable in B. subtilis than in E. coli.     

Structure and function of the region of the replication origin of the Bacillus subtilis chromosome

Summary A BamHI restriction endonuclease fragment, B7, which is replicated first among all other fragments derived from the Bacillus subtilis chromosome, was cloned in Escherichia coli using as vector a hybrid plasmid pMS102 that can replicate both in E. coli and B. subtilis. Digestion of pMS102 with BamHI produced two fragments and the smaller one was replaced by the B7 fragment.The cloned plasmid pMS102-B7 exhibited some peculiar properties that were not observed with plasmids containing other fragments from the B. subtilis chromosome. (1) E. coli cells harboring this plasmid stuck to each other and to glass. This property was more apparent when cells were grown in poor media. (2) E. coli cells tended to lose the plasmid spontaneously when they were grown without the selective pressure favorable to the plasmid. (3) The frequency of transformation of B. subtilis by pMS102-B7 was less than 1/1,000 of that by the vector plasmid pMS102. The number of copies of pMS102-B7 present in the transformants was also markedly reduced, although the pUB110 origin of replication on the vector was intact and should be functional in B. subtilis. This inhibitory effect of the B7 fragment on plasmid replication was confirmed more directly by developing a semi in vitro replication system using protoplasts.Both in E. coli and B. subtilis the B7 fragment affected replication of its own molecule but not that of the coexisting plasmid with an identical replication system. The implication of the function of the B7 fragment in the initiation of the B. subtilis chromosome will be discussed.     

Expression of the larvicidal gene of Bacillus sphaericus 1593M in the cyanobacterium Anacystis nidulans R2

Summary A 3.6 kb HindIII DNA fragement from Bacillus sphaericus 1593M was cloned and expressed in Escherichia coli and B. subtilis using pHV33 as shuttle vector and in the cyanobacterium Anacystis nidulans R2 with pUC303 as shuttle vector. The level of toxin activity of the respective recombinant plasmids pGsp04 and pGsp12 against Culex mosquito larvae was found to be the same in Escherichia coli and in the cyanobacterium.     

Inhibitory effects of soluble MD‐2 and soluble CD14 on bacterial growth

The effects of the soluble forms of the endotoxin receptor molecules sMD‐2 and sCD14 on bacterial growth were studied. When Escherichia coli and Bacillus subtilis were incubated at 37°C for 18 hr with either sMD‐2 or sCD14, growth of these bacteria was significantly inhibited as evaluated by viable cell counts and NADPH/NADH activity. A mutant of sCD14 (sCD14d57‐64) lacking a region essential for LPS binding did not inhibit the growth of E. coli, whereas this mutant did inhibit the growth of B. subtilis. Addition of excess PG to the bacterial culture reversed the inhibitory effect of sMD‐2 on the growth of B. subtilis, but not on the growth of E. coli. Furthermore, when evaluated by ELISA, both sMD‐2 and sCD14 bound specifically to PG. Taken together, these results indicate that sMD‐2 and sCD14 inhibit the growth of both Gram‐positive and Gram‐negative bacteria and further suggest that binding to PG and LPS is involved in the inhibitory effect of sMD‐2 on Gram‐positive bacteria and of sCD14 on Gram‐negative bacteria, respectively.