Molecular cloning of alpha-amylase gene from Bacillus amyloliquefaciens and its expression in B. subtilis

The gene coding for alpha-amylase from Bacillus amyloliquefaciens was isolated by direct shotgun cloning using B. subtilis as a host. The genome of B. amyloliquefaciens was partially digested with the restriction endonuclease MboI and 2- to 5-kb fragments were isolated and joined to plasmid pUB110. Competent B. subtilis amylase-negative cells were transformed with the hybrid plasmids and kanamycin-resistant transformants were screened for the production of alpha-amylase. One of the transformants producing high amounts of alpha-amylase was characterized further. The alpha-amylase gene was shown to be present in a 2.3-kb insert. The alpha-amylase production of the transformed B. subtilis could be prevented by inserting lambda DNA fragments into unique sites of EcoRI, HindIII and KpnI in the insert. Foreign DNA inserted into a unique ClaI site failed to affect the alpha-amylase production. The amount of alpha-amylase activity produced by this transformed B. subtilis was about 2500-fold higher than that for the wild-type B. subtilis Marburg strain, and about 5 times higher than the activity produced by the donor B. amyloliquefaciens strain. Virtually all of the alpha-amylase was secreted into the culture medium. The secreted alpha-amylase was shown to be indistinguishable from that of B. amyloliquefaciens as based on immunological and biochemical criteria.     

Use of plasmid pTV1 in transposon mutagenesis and gene cloning in Bacillus amyloliquefaciens

The plasmid pTV1, constructed in Bacillus subtilis as a tool for insertional mutagenesis by the transposon Tn917, has been transferred to Bacillus amyloliquefaciens by transduction with the phage PBS1. Insertional mutants containing Tn917 were observed in the new host. Southern blot analysis of such mutants indicated no preference for insertion sites. The copy numbers of pTV1 in B. amyloliquefaciens and B. subtilis were found to be 1.4 and 14, respectively; the plasmid is less stable against loss in B. amyloliquefaciens. The overall transposition rate in B. amyloliquefaciens is nevertheless comparable to that in B. subtilis and large numbers of mutants are readily obtained. The yield of auxotrophs was about 0.7% of all mutants, but the preponderance of glutamate auxotrophs seen in B. subtilis was not observed. A number of auxotrophs were identified as to nutritional requirements and those tested were found to be stable. Mutants deficient in extracellular proteases, amylase, and ribonuclease (barnase) were also found and the inactivated barnase gene has been cloned in Escherichia coli. It seems likely, therefore, that any B. amyloliquefaciens gene for which there is a functional test could be cloned by this technique.     

Construction of a promoter-probe vector for a Bacillus subtilis host by using the trpD+ gene of Bacillus amyloliquefaciens.

The trp gene cluster of Bacillus amyloliquefaciens was found to be structurally similar to that of the Enterobacteriaceae. The translation termination codon of the putative trpE gene and the initiation codon for the putative trpD gene overlap at the trpE-trpD junction, and a promoter for the putative trpC gene is suggested to exist. A promoter-probe vector of Bacillus subtilis, pFTB281, was constructed with a DNA fragment of B. amyloliquefaciens, complementing the trpC and trpD mutations of B. subtilis, a 42-base-pair DNA fragment of M13mp7, and the larger EcoRI-PvuII fragment of pUB110, which confers an autonomous replication function and the kanamycin-resistance phenotype to the chimeric plasmid. pFTB281 has BamHI, EcoRI, and SalI cloning sites in the 5'-upstream portion of the protein-coding region of the putative trpD gene, and the insertion of a certain DNA fragment at any of these sites allowed the plasmid to transform a trpD mutant of B. subtilis to the TrpD+ phenotype. DNA fragments showing the promoter function for the trpD gene were obtained from B. amyloliquefaciens and Saccharomyces cerevisiae chromosomes and rho 11 and lambda phage DNAs, but rarely from the DNAs of Escherichia coli and pBR322.     

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.     

The isolation of lambda phage carrying DNA from the histidine and isoleucine-valine regions of the Bacillus subtilis chromosome

From a lambda gtWES library of the chromosome of Bacillus subtilis, phages carrying DNA from the hisA and ilv-leu regions were isolated. They were identified by their ability to form complementing plaques on hisB, ilvC or leuB mutants of Escherichia coli K12 under selective conditions and in the presence of a helper phage. The his phages complemented E. coli his A, B or D mutations and could transform seven mutations in the hisA region of the B. subtilis chromosome; each carried a single EcoR1 insert of about 8.2 kb. Phages complementing E. coli ilvC or leuB mutations and carrying the equivalent B. subtilis genes ilvC and leuC transformed a range of mutations in the B. subtilis ilv-leu region. The distribution of genetic markers carried by the phages suggests that the entire ilv-leu cluster from az1A through leuD is covered in the collection of phages obtained and is carried in three EcoR1 restriction fragments of approximately 6.7, 4.7 and 2.85 kb.     

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.     

Corrected Version Distribution of Heterogeneous and Homologous Plasmids in Bacillus spp

A total of 75 strains (including 5 reference strains) of Bacillus amyloliquefaciens, B. cereus, B. circulans, B. licheniformis, B. megaterium, B. pumilus, B. sphaericus, B. subtilis, and B. thuringiensis and 36 species-unidentified Bacillus strains were surveyed for plasmids by cesium chloride-ethidium bromide equilibrium centrifugation of cell lysates in a study of antibiotic resistance in host cells. Of the 111 strains, 13 (including 3 reference strains) were found to harbor plasmids, and 5 of the 13 showed antibiotic resistance. This antibiotic resistance appeared not to be due to the plasmids, however, because the trait was not cured by cultivation of cells in nutrient medium containing ethidium bromide (1 mug/ml), sodium dodecyl sulfate (0.2 mug/ml), or novobiocin (1 mug/ml), except in one strain, in which kanamycin and streptomycin resistances were cured by novobiocin. One strain of B. amyloliquefaciens, S294, was found to harbor a plasmid, pFTB14, which differed from the plasmid species of classes 1 to 6 in B. subtilis and B. amyloliquefaciens, as determined by restriction analysis and DNA contour length determination. However, in DNA-DNA hybridization on a filter after Southern blotting from an agarose gel, the pFTB14 DNA hybridized with plasmids of classes 1 to 5. Three strains of B. thuringiensis each carried at least 4 to 11 plasmid species, whereas no plasmids were detected in four strains of B. cereus, which, in relation to B. thuringiensis, is closely related taxonomically and has highly homologous DNA sequences. The plasmid DNAs prepared from species other than B. subtilis and B. amyloliquefaciens did not hybridize with that of pFTB14.     

Cloning and localization of the Bacillus subtilis chromosome replication terminus, terC

A 10.9-kb segment of the Bacillus subtilis 168 chromosome has been cloned in an Escherichia coli plasmid and shown to contain terC (the replication terminus of the chromosome). The terC-containing portion of this plasmid has been subcloned within each of two overlapping fragments of DNA, 1.75 and 1.95 kb, again in E. coli plasmids. These have afforded a more precise definition of the location of terC in the B. subtilis chromosome and provided material for a detailed analysis of the structure and functioning of this site.     

An improved beta-galactosidase alpha-complementation system for molecular cloning in Bacillus subtilis

The recently described beta-galactosidase alpha-complementation system for molecular cloning in Bacillus subtilis [Haima et al., Gene 86 (1990) 63-69]was optimized in several ways. First, the efficiency of translation of the lac Z delta M15 gene was improved. Second, the plasmid-borne lacZ delta M15 gene was segregationally stabilized by integration into the B. subtilis chromosome. Third, a new lacZ alpha complementing cloning vector was constructed, containing more unique target sites. It was shown that large heterologous DNA fragments (up to at least 29 kb) could be cloned with lacZ alpha-complementing vectors carrying the replication functions of the cryptic B. subtilis plasmid pTA1060, and that these inserts were structurally stably maintained for at least 100 generations of growth.     

Direct selection of cloned DNA in Bacillus subtilis based on sucrose-induced lethality.

Expression of the Bacillus subtilis or Bacillus amyloliquefaciens sacB gene in the presence of sucrose is lethal for a variety of bacteria. Sucrose-induced lethality can be used to select for inactivation of sacB by insertion of heterologous DNA in sensitive bacteria. This procedure has not been applicable to B. subtilis heretofore because expression of wild-type sacB is not detrimental to B. subtilis. The W29 mutation in the B. amyloliquefaciens sacB gene interferes with processing of the levansucrase signal peptide. The W29 mutation does not affect growth of B. subtilis in media lacking sucrose. However, this mutation inhibited growth of B. subtilis in media containing sucrose. Inactivation of the fructose polymerase activity encoded by sacB indicated that levan production was essential for sucrose-induced lethality. As a result, it was possible to select for cloned DNA in B. subtilis by insertional inactivation of the mutant sacB gene located on a multicopy plasmid vector in medium containing sucrose.     

A universal instinct for designing thermoregulated promotors in gram-positive bacteria]

The construction of plasmid pVKH300, which is useful for modifying any promoter into the thermoregulated form in B. subtilis cells, is presented. The main features of the plasmid are the presence of effectively expressed in B. subtilis lambda C1857 gene and recognition site of BglII restriction enzyme between OR2 and OR3 lambda phage operator sites. Promoterless alpha-amylase gene of B. amyloliquefaciens is used as a reporter gene for promoter cloning into BglII site of pVKH300. Examples of promoter-containing DNA fragments cloning with pVKH300 as vector are presented. It was found that the best regulated promoter, in a plasmid named pVKH332, was cloned in such a way that the distance between central nucleotides of OR2 and OR3 is equal to integer number of DNA helix turns (84 b.p. in the case).     

Transformation of Bacillus amyloliquefaciens protoplasts with plasmid DNA

Abstract A method for efficient polyethylene glycol (PEG)-mediated transformation of Bacillus amyloliquefaciens protoplasts with plasmid DNA is described. The best conditions found for protoplast regeneration included using 0.45 M sucrose both during the cultivation of the cells and (as an osmotic stabilizer) during their treatment with lysozyme, whereas 0.25 M sodium-succinate was added to the regeneration plates. Under these conditions about 5–10% of input cells regenerated. The highest transformation frequency with plasmid DNA was obtained with a PEG 6000 concentration of 22.5% (w/v). Transforming B. amyloliquefaciens strains with the plasmid pUB110 isolated from B. amyloliquefaciens resulted in 2–4 · 10⁵ transformants/μg DNA, 100–1 000-times as high as with DNA from Bacillus subtilis , suggesting a restriction barrier between the two species. Transformation of B. amyloliquefaciens with plasmids pC194 or pE194 cop -6 gave poor yields and no restriction barrier could be demonstrated for these plasmids. However, by curing pC194 from one of the transformants, a mutant strain compatible to both the plasmids could be isolated, yielding 2–3·10⁴ transformants/μg DNA. Both laboratory and industrial B. amyloliquefaciens strains could be transformed with the procedure.     

Cloning of genetic material in Bacillus

Plasmid vectors capable for propagation of Bacillus subtilis DNA fragments containing riboflavin genes were constructed. Cloning of rib operon using pUB110 derivatives was performed in recE4 strain by using sequentional rescue of plasmids containing subfragments of the operon. Also, rib operon was cloned on the vectors containing DNA repeats. It was shown that the presence of direct and inverted repeats within plasmids allows to transform B. subtilis cells by monomers of plasmid DNA. Vectors that contained repeated sequences of DNA and ensured efficient cloning of genetic material in B. subtilis recipient cells were constructed. The use of streptococcal plasmid pSM19035 allowed to obtain vectors which were suitable for cloning large DNA fragments (6 MD and even more) in B. subtilis. A model of B. subtilis transformation by various types of plasmid DNA is presented. The model is in agreement with the general conception of chromosomal DNA transformation.     

多效调控基因degU32(Hy),degQa和degR对枯草芽孢杆菌Ki-2-132生长和蛋白酶发酵的影响

通过向枯草芽孢杆菌Ki-2-132染色体和／或细胞质导入来自枯草杆菌168菌株的degU32（Hy）和degR基因,以及来自芽孢杆菌解淀粉菌株（Bacillus amyloliquefaciens）的degQa基因,对上述基因对枯草芽孢杆菌Ki-2-132细胞的生长、孢子发生、蛋白酶发酵的影响进行了研究。尽管上述多效调控基因来自不同的芽孢杆菌种和菌株,它们在枯草芽孢杆菌Ki-2-132中依然表现多效性。枯草杆菌Ki-2-132degU32（Hy）表现出增高了的蛋白酶产量;当和质粒或染色体上的degQa基因协作,可以进一步依赖葡萄糖的水平和degQa的基因剂量影响细胞生长,增加蛋白酶产量,以及影响孢子的形成。与此不同,degR在degU32（Hy）突变体中并不显著影响其蛋白酶的产量,这一发现支持DegR蛋白通常稳定磷酸化的DegU,而其在degU32（Hy）菌株中不再进一步放大该突变体内已被磷酸化的DegU的调控作用。     

Investigation into the nature of a Bacillus promoter cloned into a promoter-probe plasmid

The alpha-amylase-coding gene (amy) of Bacillus amyloliquefaciens NCP1 was cloned into the Bacillus subtilis promoter probe vector pPL603b.1, using a BglII digest of chromosomal DNA. The resulting plasmid, pVC102, was shown to have a BglII site within the insert. It was determined that this was the result of the fortuitous co-cloning of 2.88-kb and 0.92-kb BglII fragments separated in NCP1 DNA by approx. 3 kb. Unexpectedly, this co-cloning was readily repeated. Subcloning showed that while the 2.88-kb amy-bearing fragment was sufficient for amylase production, it might not have been capable of promoting sufficient levels of chloramphenicol resistance under the conditions used in the cloning experiments. The promoter on the 0.92-kb BglII fragment was more efficient, although its sequence differed from the canonical promoter sequence recognised by B. subtilis RNA polymerase E.sigma 43. As other promoter-bearing fragments from NCP1 DNA operated equally efficiently when cloned into pPL603b.1, the reason for the repeated co-cloning of the 2.88-kb and 0.92-kb NCPI BglII fragments may well be due to structural parameters, whereby certain nucleotide sequences are more readily cloned than others.     

Mapping and cloning of the gene coding for beta-glucanase from various bacilli

Beta-glucanase gene from Bacillus subtilis 168 has been mapped by bacteriophage pBS1 transduction technique between sacA and purA genes. The stimulating effect of pleiotropic mutations pap, amyB and sacUh on beta-glucanase production in Bacillus subtilis and Bacillus amyloliquefaciens has been described. Beta-glucanase gene from Bacillus amyloliquefaciens has been cloned ona Charon 4A vector. Expression of the gene in E. coli cells depended on the orientation of the cloned DNA on a pBR322 vector plasmid. Maximal enzymatic activity was registered in periplasm. Beta-glucanase gene was recloned in Bacillus subtilis cells. Bacillus subtilis strain, harbouring pBG1, produces 500 times more beta-glucanase as compared with the wild type strain of Bacillus subtilis.     

Expression of the staphylococcal protein A gene in Bacillus subtilis by gene fusions utilizing the promoter from a Bacillus amyloliquefaciens alpha-amylase gene.

Gene fusions of DNA sequences encoding protein A from Staphylococcus aureus (spa) with expression elements from an alpha-amylase gene from Bacillus amyloliquefaciens (amyEBamP) directed the synthesis and efficient secretion of protein A in Bacillus subtilis. The fusions were established on multicopy pUB110-based plasmid vectors, in contrast to the intact spa gene, which could not be stably established on plasmids in B. subtilis. Some of the resulting B. subtilis strains secreted protein A at levels in excess of 1 g/liter, demonstrating that a foreign protein encoded by an engineered gene can be secreted by B. subtilis at levels comparable to endogenous exoproteins.     

Improving the production of E. coli beta-lactamase in Bacillus subtilis: the effect of glucose, pH and temperature on the production level.

Bacillus subtilis has been considered a promising host for the production of foreign proteins. However, proteases released by the host organism can often cause rapid breakdown of secreted heterologous proteins. Here we report that the addition of 6% glucose and 100 mM potassium phosphate to the growth medium significantly reduces the degradation of E. coli TEM beta-lactamase secreted from B. subtilis, when applying an expression system based on B. amyloliquefaciens alpha-amylase. The yield of beta-lactamase was increased 10-20-fold when compared to the yield in Luria medium. The promoter of B. amyloliquefaciens alpha-amylase gene is repressed by glucose. However, here we show that the repression does not take place in a multicopy plasmid, thus enabling our approach to efficiently reduce the protease action by catabolite repression. We have also studied the role of pH and temperature on the beta-lactamase production in laboratory scale bioreactors. Low temperature and low pH are both favorable for a high level beta-lactamase production by the high copy plasmid construction.