Cold sensitivity in the transfer of a plasmid with a deletion hot spot into recombination deficient B. subtilis cells

Summary Various recombination-deficient mutants of B. subtilis, which are readily transformable by plasmid DNA at 42° C cannot be transformed at 30° C with chimeric plasmid derivatives that contain the deletion hot spot defined previously (Alonso and Trautner 1985a, b). Such interference was also observed in protoplast transformation and SPP1 transduction.     

Cloning of the cyclomaltodextrinase gene fromBacillus subtilis high-temperature growth transformant H-17

The cyclomaltodextrinase gene fromBacillus subtilis high-temperature growth transformant H-17 was cloned on separatePstI,BamHI, andEcoRI fragments into the plasmid vector pUC18, but was expressed in an inactive form in the host,Escherichia coli DH5. High level constitutive expression of the gene product was also detrimental to theE. coli host, which led to structural instability of the recombinant plasmid. The cyclomaltodextrinase gene was cloned on a 3-kbEcoRI fragment into the plasmid vector pPL708, and the fragment was structurally maintained in the hostB. subtilis YB886. The cloned gene product was synthesized in an enzymatically active form in theB. subtilis host; however, expression was at a low level. Subcloning of the 3-kbEcoRI fragment into pUC18 and transformation intoE. coli XL1-Blue (FlacI^q) indicated that the cyclomaltodextrinase gene was cloned with its own promoter, since expression of the gene occurred in the absence of IPTG. Subcloning of the cyclomaltodextrinase gene downstream from theBacillus temperate phage SPO2 promoter of pPL708 may increase expression of this gene.Florida Agricultural Experiment Station Journal Series No. R-02177     

Construction of hybrid plasmid vectors for cloning inEscherichia coli,Bacillus subtilis,and the cyanobacteriumAnacystis nidulans

Two hybrid plasmids capable of acting as shuttle cloning vectors inAnacystis nidulans andBacillus subtilis were constructed by in vitro ligation. One construct, pMG202, consists of theB. subtilis vector pNN101 and the endogenous cyanobacterial plasmid pUH24. This 14.6 kb plasmid confers chloramphenicol resistance in both hosts and tetracycline resistance inB. subtilis. A second vector, pMG101, consists of pNN101 linked to theA. nidulans-Escherichia coli chimeric plasmid pCB4 and is 12.9 kb in size. The pCB4 portion of the vector enables pMG101 to replicate in the third host,E. coli, and confers ampicillin resistance in this bacterium as well as inA. nidulans. Both plasmids possess identical uniqueStu I sites which permit insertional inactivation of the chloramphenicol resistance gene; and, in addition, identical uniqueXho I sites are present on both vectors. Each vector also has a third unique site:Sma I on pMG101 andXba I on pMG202.     

Bacillus stearothermophilus plasmid pSTK1 replicon is functional in Escherichia coli

Summary A kanamycin-resistant plasmid possessing a thermostable replicon derived from Bacillus stearothermophilus cryptic plasmid pSTK1 was constructed. The plasmid could transform not only B. stearothermophilus and Bacillus subtilis, but also Gram-negative Escherichia coli. The behavior of the plasmid in the hosts was examined. The plasmid was stably maintained even at 67°C in B. stearothermophilus without selective pressure. During the plasmid replication, single-stranded DNA (ssDNA) intermediates were found in E. coli, while these were not found in B. subtilis.     

Purification and characterization of a truncatedBacillus subtilis α-amylase produced byEscherichia coli

ABacillus subtilis amylase gene was inserted into a plasmid which transferred toEscherichia coli. During cloning, a 3 region encoding 171 carboxyterminal amino acids was replaced by a nucleotide sequence that encoded 33 amino acid residues not present in the indigenous protein. The transformed cells produced substantial amylolytic activity. The active protein was purified to apparent homogeneity. Its molecular mass (48 kDa), as estimated in sodium dodecyl sulfate/polyacrylamide gel electrophoresis, was lower than the molecular mass values calculated from the derived amino acid sequences of theB. subtilis complete -amylase (57.7 kDa) and the truncated protein (54.1 kDa). This truncated enzyme form hydrolysed starch with aK _m of 3.845 mg/ml. Activity was optimal at pH 6.5 and 50°C, and the purified enzyme was stable at temperatures up to 50°C. While Hg²⁺, Fe³⁺ and Al³⁺ were effective in inhibiting the truncated enzyme Mn²⁺ and Co²⁺ considerably enhanced the activity.     

Characterization of a Theta Plasmid Replicon with Homology to All Four Large Plasmids ofBacillus megateriumQM B1551

A replicon from one of an array of seven indigenous compatible plasmids ofBacillus megateriumQM B1551 has been cloned and sequenced. The replicon hybridized with all four of the large plasmids (165, 108, 71, and 47 kb) of strain QM B1551. The cloned 2374-bpHindIII fragment was sequenced and contained two upstream palindromes and a large (>419-amino-acid) open reading frame (ORF) truncated at the 3′ end. Unlike most plasmid origins, a region of four tandem 12-bp direct repeats was located within the ORF. The direct repeats alone were incompatible with the replicon, suggesting that they are iterons and that the plasmid probably replicates by theta replication. The ORF product was shown to act intrans.A small region with similarity to theB. subtilischromosomal origin membrane binding region was detected as were possible binding sites for DnaA and IHF proteins. Deletion analysis showed the minimal replicon to be a 1675-bp fragment containing the incomplete ORF plus 536 bp upstream. The predicted ORF protein of >48 kDa was basic and rich in glutamate + glutamine (16%). There was no significant amino acid similarity to any gene, nor were there any obvious motifs present in the ORF. The data suggest that this is a theta replicon with an expressedrepgene required for replication. The replicon contains its iterons within the gene and has no homology to reported replicons. It is the first characterization of aB. megateriumreplicon.     

Altered heat resistance in spores and vegetative cells of a mutant fromBacillus subtilis

The relationship between sporulation temperature and spore killing temperature is described.Bacillus subtilis YB886, grown and sporulated at 25°, 30°, 37°, and 45°C, produced spores having D₉₀ values of 63.5, 76.3, 89.0, and 106 min respectively. In addition, the vegetative cells of this strain also demonstrated resistance to heat killing when grown at elevated temperatures (D₅₀ of 26.6, 32.5, 39.0, and >50 min for cells grown at 25°, 30°, 37°, and 45°C). A transposon-generated mutant of strain YB886, designated as BUL786, which is missing a heat shock-induced protein (97 kDa) (Qoronfleh MW and Streips UN, BBRC, 138:526–532, 1986 and FEMS 1987), was tested for thermotolerance under similar conditions. The cells failed to respond to growth at high temperature by producing heat-resistant spores or vegetative cells. For strain BUL786 the D₉₀ of spores generated at 20°, 25°, 30°, 37°, and 45°C was 9.4, 11.3, 12.8, 14.1, and 20 min, respectively. Similarly, the D₅₀ of vegetative cells was 15, 16.8, 17.8, 19.0, and 22.3 min when the cells were grown at 20°, 25°, 30°, 37°, and 45°C. Also, sporulation of YB886 cells in the presence of cadmium chloride increased the D₉₀ values for the resulting spores (5µM CdCl₂ resulted in a D₉₀ of 160 min). Strain BUL786 failed to produce spores with any elevated D₉₀ when grown in the presence of CdCl₂.     

Gene replacement method for determining conditions in which<Emphasis Type="Italic"> Bacillus subtilis</Emphasis> genes are essential or dispensable for cell viability

We describe a method for determining conditions in which Bacillus subtilis genes are essential or dispensable for cell viability. This method utilizes a chloramphenicol-resistant plasmid containing a temperature-sensitive (ts) replication origin. In this method, the target gene is first cloned into the ts vector and the recombinant plasmid is used to transform wild-type B. subtilis. The second step involves transformation of the resulting strain with a linear DNA fragment containing a second antibiotic resistance marker (tet) that disrupts the gene of interest. Selection for tetracycline resistance forces a double crossover between the chromosomal and fragment-borne copies of the gene, thereby replacing the wild-type gene in the chromosome with the disrupted allele. Cells survive even if the gene is essential by virtue of the complementing plasmid. Transformants are then grown at the non-permissive temperature for plasmid replication under various growth conditions. Isolation of chloramphenicol-sensitive colonies indicates that the gene is dispensable, whereas the inability to isolate chloramphenicol-sensitive colonies indicates that the gene is essential. The general utility of this method is demonstrated by allowing disruption of mtrA and trpE under conditions that render each gene non-essential, but not under growth conditions in which each gene is essential.     

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.     

Increased efficiency of transformation ofBacillus stearothermophilus by a plasmid carrying a thermostable kanamycin resistance marker

Recombinant plasmids carrying either the wildtype kanamycin nucleotidyltransferase gene encoded originally by the mesophilic plasmid pUB110 or the gene encoding the thermostable TK101 mutant were constructed and introduced intoBacillus stearothermophilus by a protoplast transformation procedure. When kanamycin-resistant transformants were selected at 47°C, the transformation efficiency of the plasmid bearing the TK101 gene was nine times higher than that of the plasmid encoding the wildtype enzyme. The difference in transformation efficiencies between the two plasmids was increased when transformants were selected at higher temperatures, reflecting the difference in thermostabilities of the respective kanamycin nucleotidyltransferases. We conclude that, even though the pUB110 enzyme is sufficiently active at 47°C to confer kanamycin resistance toB. stearothermophilus, the additional stability of the TK101 mutant is advantageous in transformation ofB. stearothermophilus. The TK101 gene may also have broad utility as a marker for cloning vectors in other thermophiles.     

Molecular cloning and expression ofBacillus subtilis bglS gene inSaccharomyces cerevisiae

A 2.7-kb EcoRI DNA fragment carrying aBacillus subtilis endo--1,3-1,4-glucanase gene (bglS) from theE. coli plasmid pFG1 was cloned into anEscherichia coli/yeast shuttle vector to construct a hybrid plasmid YCSH. The hybrid plasmid was used to transformSaccharomyces cerevisiae, and thebglS gene was expressed. Variation between levels ofbglS gene expression inS. cerevisiae was about 2.3-fold, depending on the orientation of the 2.7-kb DNA fragment. Assay of substrate specificity and optimal pH of the enzyme demonstrated that the enzyme encoded by YCSH (bglS) was identical with that found inB. subtilis, but the expression level ofbglS gene inS. cerevisiae (YCSH) was much lower than that inE. coli (YCSH).     

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.     

Construction of a new shuttle vector pSTE33 and its stabilities in Bacillus stearothermophilus,bacillus subtilis,and Escherichia coli

Summary A shuttle vector that could replicate in B. stearothermophilus, B. subtilis, and E. coli was constructed from B. stearothermophilus cryptic plasmid pSTK1, E. coli vector pUC19, and a thermostable kanamycin-resistance marker. This new vector was stably maintained in B. stearothermophilus at 67°C without selective pressure.     

High Frequency Conjugative Mobilization Accomplished by a Natural Bacillus subtilisStrain Carrying a Large Plasmid

Conjugative properties of the strain Bacillus subtiliscarrying a large plasmid approximately 95 kb in size and isolated in Belarus from forest soil were described. The staphylococcal plasmid pUB110 that had previously been introduced into this strain was transferred to recipient cells of the Bacillus subtilis168 strain with a frequency of approximately 10^–2. The transfer occurred with approximately the same frequency both upon donor and recipient cell contact on the surface of membranes and in a liquid medium. The latter fact makes this system suitable as a model for studying conjugative mobilization in bacilli. A large plasmid cannot be transferred to recipients. An optimal temperature for conjugation of donor and recipient cells was 37°C, but conjugation also proceeded at lower temperatures, up to 21°C.     

Effects on growth and sporulation of inactivation of a Bacillus subtilis gene (ctc) transcribed in vitro by minor vegetative cell RNA polymerases (E-sigma 37, E-sigma 32)

Summary The E-³⁷ gene ctc was inactivated by a site-specific insertion into the Bacillus subtilis chromosome. The resulting mutation inhibited sporulation by 95% at elevated temperatures (48° C). If the ctc ^- mutation is placed in a strain that carries a mutation in the closely linked but distinct spoVC gene, ctc now affects both growth and sporulation at elevated temperatures. Growth of the ctc ^- spoVC285 strain was transiently inhibited when exponentially growing cultures were shifted from 37° C to 48° C. A similar, but less pronounced growth lag, was also seen in a B. subtilis strain carrying only the spoVC-285 mutation. This finding suggests that both the ctc and spoVC products function in vegetatively growing B. subtilis.     

Expression of cDNA fragment encoding sperm membrane peptide inE. coli

A secretory high-level expression cloning vector designated as pSBC-20 was constructed by inserting a DNA fragment encoding the signal peptide of ompA protein into pBV 220 vector. Any foreign DNA fragment can be inserted into the polylinker cloning sites located after the secretion signal sequence. The cloned foreign gene is under the control of the P _R -P _L promoter while the expression of the gene is regulated by the cI-gene product. The products are secreted into the periplasmic space of bacteria or into the medium. A recombinant plasmid (pRSD-220) was constructed by inserting the 210 bp from RSD-2, a cDNA encoding a peptide fragment of human sperm protein, into the EcoRI site of pSBC-20. TheE. coli cells transformed with pRSD-220 were propagated at 30 °C, then incubated at 42 °C for several hrs. The cloned gene product was secreted into the culture medium at a high rate. The yield was about 60 mg of gene product per liter of cultured medium.     

The nucleotide sequence of a DNA fragment from the replication origin of the antibiotic resistance factor R1drd19

Summary The recombinant plasmid pRK101 contains a DNA fragment which carries the complete replication origin of the antibiotic resistance factor R1drd-19 inserted into the vector plasmid pBR322. In a spontaneously arising mutant of this plasmid (pRK 103) a deletion of about 215 base pairs (bp) has been detected by heteroduplex analysis and mapping with restriction endonucleases. Essential parts of the replication origin must be located in the deleted sequence. The deletion mutant pRK103, in contrast to its parent plasmid pRK101 is not replicated under the control of the R1 replicon, even when the R1 factor or copy mutants of it are present within the same cell. These latter plasmids can complement a plasmid-specific protein not coded by pRK101 but essential for R1-directed replication. The nucleotide sequence of a 252 bp HpaII fragment covering about 170–200 bp of the deletion was determined. This piece of DNA is rich in G and C and contains a series of small palindromes, symmetrically arranged repeated sequences and short selfcomplementary structures which may be of significance for the initiation of the DNA replication. The possibility that the sequenced DNA fragment comprises a major part of the replication origin of R1drd-19 is discussed.     

Survival of Plasmid-Containing Bacillus subtilis Released into Mushroom Compost

Abstract The survival of a plasmid-containing Bacillus subtilis released into mushroom compost was investigated. The indigenous Bacillus population of mushroom compost exhibited an antibiotic-resistance profile that was distinguished by almost complete absence of chloramphenicol resistance. Bacillus subtilis containing the chloramphenicol-resistance plasmid pC194 was released into mushroom compost microcosms and populations were monitored at different incubation temperatures. The organism colonized both sterile and untreated compost at 37°C, and to a lesser extent at 50°C, but was eliminated after 30 d at 65°C. Although sporulation of the B. subtilis population occurred within compost, the population was maintained for up to 13 weeks at 50°C, largely as vegetative cells. Experiments in which the B. subtilis host strain, without plasmid, was released demonstrated that plasmid carriage had no effect on the ability of the bacterium to colonize and survive in compost. Furthermore, the size and composition of the indigenous bacterial population was unaffected by the presence of the introduced B. subtilis strain. Virtually no loss of plasmid pC194 from the B. subtilis population in compost was observed, and experiments at low growth rates in chemostats confirmed the stability of this host/vector system in the absence of positive selection pressure. Received: 9 July 1997; Accepted: 20 October 1997     

Instability of Rts1 (Drug-Resistant Factor) Replicon: Stabilization by DNA Fragments Derived from Rts1

Rts1 is a large naturally occurring plasmid which has a kanamycin resistance gene and exhibits various temperature-sensitive phenotypes. A smaller derivative of plasmid, pOK, contains the Rts1 replicon and the kanamycin resistance gene of Rts1. This plasmid, pOK, is much more unstable than Rts1 at 42.5°C. A DNA fragment, G₃, 1590 nucleotides long from Rts1 DNA, stabilized pOK completely at 42.5°C but only in thecisconfiguration. G₃did not change the copy number of pOK. The pOK derivative containing G₃was destabilized by the presence of a compatible plasmid containing G₃. G₃has four inverted repeats, two 14-base direct repeats, and three ORFs. Smaller fragment of G₃also had a stabilization effect and these studies showed that the ORF does not play any role in stabilization.     

A thermostable leucine aminopeptidase from<Emphasis Type="Italic"> Bacillus kaustophilus</Emphasis> CCRC 11223

Two degenerate primers established from the consensus sequences of bacterial leucine aminopeptidases (LAP) were used to amplify a 360-bp gene fragment from the chromosomal DNA of thermophilic Bacillus kaustophilus CCRC 11223 and the amplified fragment was successfully used as a probe to clone a leucine aminopeptidase (lap) gene from a genomic library of the strain. The gene consists of an open reading frame (ORF) of 1,494 bp and encodes a protein of 497 amino acid residues with a calculated molecular mass of 53.7 kDa. The complete amino acid sequence of the cloned enzyme showed greater than 30% identity with prokaryotic and eukaryotic LAPs. Phylogenetic analysis showed that B. kaustophilus LAP is closely related to the enzyme from Bacillus subtilis and is grouped with the M17 family. His₆-tagged LAP was generated in Escherichia coli by cloning the coding region into pQE-30 and the recombinant enzyme was purified by nickel-chelate chromatography. The pH and temperature optima for the purified enzyme were 8 and 65°C, respectively, and 50% of its activity remained after incubation at 60°C for 32 min. The enzyme preferentially hydrolyzed l-leucine-p-nitroanilide (l-Leu-p-NA) followed by Cys derivative.Communicated by G. Antranikian