A new vector for insertion of any DNA fragment into the chromosome of transformable Neisseriae

A useful method for inserting any DNA fragment into the chromosome of Neisseriae has been developed. The method relies on recombination-proficient vector plasmid pNLE1, a pUC19 derivative containing (1) genes conferring resistance to ampicillin and erythromycin, as selectable markers; (2) a chromosomal region necessary for its integration into the Neisseria chromosome; (3) a specific uptake sequence which is required for natural transformation; (4) a promoter capable of functioning in Neisseria; and (5) several unique restriction sites useful for cloning. pNLE1 integrates into the leuS region of the neisserial chromosome at high frequencies by transformation-mediated recombination. The usefulness of this vector has been demonstrated by cloning the tetracycline-resistance gene (tet) and subsequently inserting the tet gene into the meningococcal chromosome.     

Construction of plasmid-based expression vectors for Bacillus subtilis exhibiting full structural stability

A series of plasmid-based expression vectors have been constructed allowing stable intracellular expression of recombinant proteins in Bacillus subtilis strains. These expression vectors are based on the recently described Escherichia coli-B. subtilis shuttle vector pMTLBS72 which replicates as theta circles. Besides the weak constitutive promoter P(lepA), we inserted three different controllable promoters: P(gsiB) which can be induced by heat and acid shock, and by ethanol, P(xylA) and P(spac) which respond to the addition of xylose and IPTG, respectively. The versatility of these expression vectors was demonstrated by fusing their promoters to a reporter gene and by overexpression of the HtpG protein with three of them. All recombinant vectors exhibited full structural stability.     

The Bacillus subtilis spoIIA locus is expressed at two times during sporulation

Abstract The Bacillus subtilis spoIIA and spoIIAB genes were fused to the Escherichia coli lacZ gene on a novel integrational plasmid vector. The constructs were integrated into the B. subtilis chromosome, and used to show that the spoIIA locus was expressed at two times during sporulation.     

Integration of various plasmids into the Bacillus subtilis chromosome

Some features of integration of temperature-sensitive pE194, pGG10 and pGG20 plasmids into the Bacillus subtilis chromosome were studied. Several auxotrophic mutations were obtained using insertion of these plasmids into the chromosome. The sites of plasmids for illegitimate recombination were determined. It was shown that the integration into the Bac. subtilis chromosome is characteristic not only for the plasmid pE194 but is the property of Staphylococcus aureus plasmid pC194 and Escherichia coli pBR322 plasmid. The influence of different Bac. subtilis rec mutations on the frequency of integration was studied.     

A novel cold-inducible expression system for Bacillus subtilis

Production of recombinant proteins at low temperatures is one strategy to prevent formation of protein aggregates and the use of an expensive inducer such as IPTG. We report on the construction of two expression vectors both containing the cold-inducible des promoter of Bacillus subtilis, where one allows intra- and the other extracellular synthesis of recombinant proteins. Production of recombinant proteins started within the first 30min after temperature downshock to 25 degrees C and continued for about 5h.     

Novel broad host range shuttle vectors for expression in Escherichia coli, Bacillus subtilis and Pseudomonas putida

Novel shuttle vectors named pEBP were constructed to allow the gene expression in different bacterial hosts including Escherichia coli, Bacillus subtilis and Pseudomonas putida. These vectors share the inducible promoters P(T7) and P(Xyl) and a cos site to enable packaging of plasmid DNA into phage, and carry different multiple cloning sites and antibiotic resistance genes. Vector pEBP41 generally replicates episomally while pEBP18 replicates episomally in Gram-negative bacteria only, but integrates into the chromosome of B. subtilis. Plasmid copy numbers determined for E. coli and P. putida were in the range of 5-50 per cell. The functionality of pEBP18 and pEBP41 was confirmed by expression of two lipolytic enzymes, namely lipase A from B. subtilis and cutinase from the eukaryotic fungus Fusarium solani pisi in three different host strains. Additionally, we report here the construction of a T7 RNA polymerase-based expression strain of P. putida.     

Extracellular production of human cystatin S and cystatin SA by Bacillus subtilis

We herein describe the development of a Bacillus subtilis system that can be used to produce large quantities of recombinant (r-) human salivary cystatins, a cysteine protease inhibitor of family 2 in the cystatin superfamily. The B. subtilis that lacked the alkaline protease E gene (DeltaaprE type mutant strain) was prepared by homologous recombination. The cDNA fragments coding for mature cystatins (S and SA) were ligated in frame to the DNA segment for the signal peptide of endoglucanase in the pHSP-US plasmid vector that was then use to transform the DeltaaprE type mutant strain of B. subtilis. The transformants carrying the expression vectors were cultivated in 5-L jar fermenters for 3 days at 30 degrees C. Both r-cystatin S and r-cystatin SA were successfully expressed and secreted into the culture broth, and were purified using a fast performance liquid chromatography system. The first use of DeltaaprE type mutant strain of B. subtilis made it possible to obtain a high yield of secreted protein, which makes this system an improvement over expression in Escherichia coli. We conclude that this system has high utility for expression of commercial quantities of secreted proteins.     

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.     

Subspecies-specific distribution of intervening sequences in the Bacillus subtilis prophage ribonucleotide reductase genes

A collection of 212 gram-positive bacilli isolated from natural habitats was screened for the presence of intervening sequences (introns and intein-coding sequences) in the SPbeta prophage-related ribonucleotide reductase genes bnrdE and bnrdF. Three novel configurations were identified on the basis of the presence of (i) intervening sequences in bnrdE and bnrdF, and (ii) an ORF in the bnrdE-bnrdF spacer. Analysis of the cell wall genetic determinants as well as of the incorporation of radio-labelled glycerol into cell wall allowed newly and previously identified B. subtilis strains with different configurations of bnrdE/bnrdF intervening sequences to be assigned to one of two subspecies. Strains apparently belonging to the subsp. subtilis contain three intervening sequences many of which are associated with the putative homing endonuclease activity. Strains of the subsp. spizizenii contain only one or two ORF-less group I introns. Introns occupying bnrdF are confined to the subspecies subtilis.     

Integration ofhup cosmid pHU52 into the chromosomal DNA ofCicer-Rhizobium using Tn5 as an homologous sequence

Cosmid pHU52, which carrieshup genes ofBradyrhizobium japonicum, has been integrated into theCicer-Rhizobium G36-84 genome via Tn5-mediated homologous recombination. Tn5 was inserted into both the cosmid pHU52 and the chromosome ofCicer-Rhizobium to provide a region of DNA homology, without affecting the expression of necessary genes. An incompatible plasmid, pPH1JI, was used to select those few cells that had undergone recombination. The integration of the cosmid was demonstrated by Southern blot analysis. Chromosomal integration of thehup genes maximized stability and minimized the potential for their horizontal transfer to other bacterial species. The integratedhup genes were found to expressex planta as well in nodules. The method described illustrates how a given gene can be stably integrated into the chromosome.     

Chromosomal localization of foreign genes in Petunia hybrida

Summary A F1 hybrid of Petunia hybrida, heterozygous for at least one marker on each of the seven chromosomes, was transformed with a modified strain of Agrobacterium tumefaciens in which the phytohormone biosynthetic genes in the transferred DNA (T-DNA) were replaced with a NOS/NPTII/NOS chimeric gene and a wildtype nopaline synthase (NOS) gene. The chimeric gene, which confers kanamycin resistance, was used as selectable marker during the transformation process and the NOS gene was used as a scorable marker in the genetic studies. After plants had been regenerated from the transformed tissues, the transgenic plants that expressed both of these markers were backcrossed to the parental lines. The offspring were examined for the segregation of the NOS gene and the Petunia markers. Genetic mapping was thus accomplished in a single generation.By Southern hybridization analysis we confirmed the presence of the expected T-DNA fragments in the transformed plants. Four out of the six plants presented here, had just one monomeric T-DNA insertion. The sizes of the plant/T-DNA junction fragments suggest that the integration occurred in different sites of the Petunia genome. One transformant gave a more complicated hybridization pattern and possibly has two T-DNA inserts. Another transgenic plant was earlier reported (Fraley et al. 1985) to have two, possibly tandemly repeated T-DNAs.Data is presented on the genetic localization of the T-DNA inserts in six independently obtained transgenic plants. The T-DNA inserts in three plants were mapped to chromosome I. However, the distances between the NOS gene and the marker gene on this chromosome were significantly different. In another transgenic plant the NOS gene was coinherited with the marker on chromosome IV. Two other transgenic plants have the T-DNA insert on chromosome III. A three point cross enabled us to determine that both plants have the NOS gene distally located from the peroxidaseA (prxA) marker and both plants showed about 18% recombination. However, Southern hybridization analysis shows that the sizes of the plant/T-DNA junction fragments in these transgenic plants are different, thus suggesting that the integrations occurred in different sites.     

Development of a pair of bifunctional expression vectors for <Emphasis Type="Italic">Escherichia coli</Emphasis> and <Emphasis Type="Italic">Bacillus licheniformis</Emphasis>

A pair of bifunctional expression vectors, pBL-WZX and pHY-WZX, for Escherichia coli and Bacillus licheniformis was constructed to express interesting genes in a secretory manner. The vectors contain an expression cassette consisted of the promoter and signal peptide region of B. licheniformis amyL as well as an artificial multiple cloning site and a terminator and utilize kanamycin-resistance and/or tetracycline-resistance for selection in both B. licheniformis and E. coli. Both vectors contain a part of 3′ terminal fragment of B. licheniformis amyL. The 5′-terminal or 3′-terminal fragment of B. licheniformis amyL can cause the integration and amplification of expression cassette in the chromosome of B. licheniformis under a kanamycin-selection pressure. pBL-WZX is an integrational vector while pHY-WZX is free one for B. licheniformis. Both vectors were succeeded in secretory expression of manL in both B. licheniformis and E. coli.     

A general system to integrate lacZ fusions into the chromosomes of gram-negative eubacteria: regulation of the Pm promoter of the TOL plasmid studied with all controlling elements in monocopy.

Summary A new procedure is described to recombine plasmid-bornelacZ fusions into the chromosome of gram-negative eubacteria in order to study promoter activity in monocopy. The procedure is based upon the insertion into the chromosome of a target bacterium of a recombinant transposon that carries DNA sequence homology to the regions flankinglacZ fusions present in multicopy promotor-probe vectors, which can be mobilized via RP4-mediated transfer but are unable to replicate in non-enteric bacteria. Double recombination between the promoter-probe vectors and the chromosomal homology region of the transposon is genetically selected by reconstruction and expression of wild-type sequences from truncatedlacZ andaadA (streptomycin/spectinomycin) resistance genes in the homology fragment and from an amber mutation carryinglacZ andaadA genes present in the plasmid vectors. The structure of desired clones is confirmed by screening for loss of the transposon-encoded kanamycin resistance marker. We have used this procedure to assemble in monocopy inPseudomonas putida the regulatory elements controlling expression of the Xy1S-activatedPm promoter of the TOL catabolic plasmid pWWO. We show here that thePm promoter undergoes a Xy1S-independent, strictly growth-phase-controlled activation by benzoate but not meta-toluate. In the presence of XylS, however, activation by both effectors involves a combination of growth phase-dependent and -independent controls.     

Identification of plasmid and Bacillus subtilis chromosomal recombination sites used for pE194 integration.

The plasmid pE194 (3.7 kilobases) is capable of integrating into the genome of the bacterial host Bacillus subtilis in the absence of the major homology-dependent RecE recombination system. Multiple recombination sites have been identified on both the B. subtilis chromosome and pE194 (J. Hofemeister, M. Israeli-Reches, and D. Dubnau, Mol. Gen. Genet. 189:58-68, 1983). The B. subtilis chromosomal recombination sites were recovered by genetic cloning, and these sites were studied by nucleotide sequence analysis. Recombination had occurred between regions of short nucleotide homology (6 to 14 base pairs) as indicated by comparison of the plasmid and the host chromosome recombination sites with the crossover sites of the integration products. Recombination between the homologous sequences of the plasmid and the B. subtilis genome produced an integrated pE194 molecule which was bounded by direct repeats of the short homology. These results suggest a recombination model involving a conservative, reciprocal strand exchange between the two recombination sites. A preferred plasmid recombination site was found to occur within a 70-base-pair region which contains a GC-rich dyad symmetry element. Five of seven pE194-integrated strains analyzed had been produced by recombination at different locations within this 70-base-pair interval, located between positions 860 and 930 in pE194. On the basis of these data, mechanisms are discussed to explain the recombinational integration of pE194.     

Novel plasmid-based expression vectors for intra- and extracellular production of recombinant proteins in Bacillus subtilis

Two plasmid-based expression vectors have been constructed where one allows intracellular production of recombinant proteins while the second directs the proteins into the culture medium. Both vectors use the strong promoter preceding the groESL operon (codes for the essential heat shock proteins GroES and GroEL) of Bacillus subtilis fused to the lac operator allowing their induction by addition of ITPG. While the background level of expression of these expression cassettes is very low in the absence of the inducer, an induction factor of about 1300 was measured. When the genes htpG and pbpE (coding for a heat shock protein and a penicillin-binding protein, respectively) were fused to the groE promoter, the amount of recombinant protein produced after addition of IPTG represented 10 and 13%, respectively, of the total cellular protein. To obtain secretion of recombinant proteins, the coding region for the signal peptide of the amyQ gene encoding an alpha-amylase from Bacillus amyloliquefasciens was fused to the groE promoter. High-level secretion of amyQ alpha-amylase and cellulase A and B of Clostridium thermocellum was demonstrated.