Co-expression of binary and 100 kDa mosquito larvicidal toxins of Bacillus sphaericus in Escherichia coli

The binary (51 and 42 kDa) and 100 kDa mosquito larvicidal toxins of Bacillus sphaericus are expressed at different growth stages of Bacillus. The genes encoding the binary toxin were expressed using T7 expression system of E. coli. In addition, a PCR amplified product containing the coding sequences of the 100 kDa toxin was cloned upstream to the binary toxin genes, and both the toxins were co-expressed in E. coli. Expression studies with these constructs in different E. coli hosts showed that when these two toxins were co-expressed, there was no augmentation of toxicity in comparison to the construct expressing the binary toxin alone. This result apparently indicates that there is no synergism between these two toxins. © Rapid Science Ltd. 1998     

Enhanced and constitutive expression of mosquito larvicidal protein genes of Bacillus sphaericus under leaky regulation of T7 expression system in Escherichia coli

Expression of the mosquito larvicidal genes coding for 51 and 42kDa proteins from Bacillus sphaericus cloned into E. coli, under the control of T7RNA polymerase promoter system, resulted in a high level of larvicidal activity of the recombinant. The clone MS16 expressed the binary toxins at high level even under uninduced conditions. This indicates that the leaky regulation of the T7RNA polymerase gene was responsible for the constitutive expression of mosquito larvicidal proteins (MLP). The economic advantage of producing the MLP in a rapidly-growing and sugar-utilising organism such as E. coli was demonstrated in a batch cultivation where production of the MLP was growth-associated.     

Cloning and heterologous expression of ectoine biosynthesis genes from Bacillus halodurans in Escherichia coli

The genes involved in the biosynthetic pathway of ectoine (2-methyl-1,4,5,6-tetrahydropyrimidine-4-carboxylic acid) from Bacillus halodurans were cloned as an operon and expressed in E. coli. Analysis of the deduced ectoine biosynthesis cluster amino acid sequence revealed that the ectoine operon contain 2,389 bp, encoded by three genes; ectA, ectB and ectC that encode proteins of 189, 427 and 129 amino acids with deduced molecular masses of 21,048, 47,120 and 14,797 Da respectively. Extracts of induced cells showed two bands at 41 kDa and 17 kDa, possibly corresponding to the products of the later two genes. However the expression of ectA gene could not be ascertained by SDS-PAGE. The activity of the ectA protein was confirmed by an acylation assay. The transgenic E. coli accumulated upto 4.6 mg ectoine/l culture. This is the first report of an engineered E. coli strain carrying the ectoine genes of the alkaliphilic bacterium, B. halodurans.     

Analysis of Expression of the Binary Toxin Genes from Bacillus sphaericus in Anabaena and the Potential in Mosquito Control

Anabaena strains expressing the binary toxin genes of Bacillus sphaericus produce high larvicidal activity with living cells. Western blot analysis showed that the 51-kDa and 42-kDa toxin proteins were stable in Anabaena. When a DNA fragment upstream of the 51-kDa protein gene was deleted, the toxicity was reduced by over a hundred-fold, whereas deletions at the coding regions showed that the cooperation of the two proteins expressed in Anabaena is essential for the larvicidal activity. Outdoor tests showed that the genetically altered Anabaena could keep containers with natural water from being inhabited by Culex larvae for over 2 months. Received: 8 May 2000 / Accepted: 13 June 2000     

Cloning of the gene for the larvicidal toxin of Bacillus sphaericus 2362: evidence for a family of related sequences.

During sporulation, Bacillus sphaericus 2362 produces a parasporal crystalline protein which is toxic for the larvae of a number of mosquito species. Using the Escherichia coli cloning vector lambda gt11, in which gene products of the inserts may be fused to beta-galactosidase, we isolated 29 bacteriophages which produced peptides-reacting with antiserum to crystal protein. On the basis of restriction enzyme analyses of the recombinants and Ouchterlony immunodiffusion experiments with induced lysogens as a source of antigens, the recombinants were assigned to three groups, designated A, B, and C. Group A consisted of three clones which appeared to express all or part of the B. sphaericus toxin gene from their own promoters and one clone producing a beta-galactosidase-toxin fusion protein. The host cells of two induced recombinant lysogens of this group were toxic to larvae of Culex pipiens. A cell suspension containing 174 ng (dry weight) of the more toxic recombinant per ml killed 50% of the larvae. Both recombinants formed peptides with molecular sizes of 27, 43, and 63 kilodaltons (kDa). The antigenically related 27- and 43-kDa peptides were distinct from the 63-kDa peptide, which resembled crystals from sporulating cells of B. sphaericus in which antigenically distinct 43- and 63-kDa proteins are derived from a 125-kDa precursor. A 3.5-kilobase HindIII fragment from recombinants having toxic activity against larvae was subcloned into pGEM-3-blue. E. coli cells harboring this fragment were toxic to mosquito larvae and produced peptides of 27, 43, and 63 kDa. The distribution of the A gene among strains of B. sphaericus of different toxicities suggested that it is the sole or principal gene encoding the larvicidal crystal protein. The two recombinants of group B and the 23 of group C were all beta-galactosidase fusion proteins, suggesting that in E. coli these genes were not readily expressed from their own promoters. The distribution of these two genes in different strains of B. sphaericus suggested that they do not have a role in the toxicity of this species to mosquito larvae.     

Gene 26 of bacteriophage T4 basal plate. I. Two expression products of the cloned gene

We have cloned the 1.9 kb EcoRV-BglII DNA fragment with T4 genes 51, 26, and 25 into the expression plasmid pT7-5 carrying a T7 promoter. The resulting recombinant plasmid, pRR5-3, contained T4 genes 26 and 25 in the correct orientation for expression. We expressed these genes using the T7 RNA polymerase/promoter system and the synthesis of three polypeptides with the molecular masses of approximately 24, 15, and 8-9 kDa was observed. Expression of genes from the subcloned DNA fragments and from the fragments carrying deletions was studied as well and the 15 kDa protein appeared to be the product of gene 25, while 24 kDa and 8-9 kDa proteins were identified as products of gene 26. The 8-9 kDa protein was shown to be expressed from the end region of gene 26. Having analysed the proteins expressed from the fragments carrying fusion of genes 26 and 25 we supposed two products of gene 26 to be encoded by the same open reading frame.     

Interaction of the Bacillus subtilis DnaA-like protein with the Escherichia coli DnaA protein.

Plasmids carrying the intact Bacillus subtilis dnaA-like gene and two reciprocal hybrids between the B. subtilis and Escherichia coli dnaA genes were constructed. None of the plasmids could transform wild-type E. coli cells unless the cells contained surplus E. coli DnaA protein (DnaAEc). A dnaA (Ts) strain integratively suppressed by the plasmid R1 origin could be transformed by plasmids carrying either the B. subtilis gene (dnaABs) or a hybrid gene containing the amino terminus of the E. coli gene and the carboxyl terminus of the B. subtilis gene (dnaAEc/Bs). In cells with surplus E. coli DnaA protein, expression of the E. coli dnaA gene was derepressed by the B. subtilis DnaA protein and by the hybrid DnaAEc/Bs protein, whereas it was strongly repressed by the reciprocal hybrid protein DnaABs/Ec. The plasmids carrying the different dnaA genes probably all interfere with initiation of chromosome replication in E. coli by decreasing the E. coli DnaA protein concentration to a limiting level. The DnaABs and the DnaAEc/Bs proteins effect this decrease possibly by forming inactive oligomeric proteins, while the DnaABs/Ec protein may decrease dnaAEc gene expression.     

Delineation of the minimal portion of the Bacillus sphaericus 1593M toxin required for the expression of larvicidal activity

The two genes of Bacillus sphaericus 1953M coding for the 51.4-kDa and 41.9-kDa proteins are both required for the expression of the active larvicidal toxin in Escherichia coli. The minimal size of the active peptide of the 41.9-kDa toxin was defined by in vitro deletion analysis of the gene and found to consist of 338 amino acids (38.3 kDa). N-terminal deletions past the Ile18 residue and C-terminal deletions past the His352 residue result in the loss of toxic activity and rapid degradation of such modified toxins by host proteases. The minimal active 38.3-kDa peptide produced in E. coli seems to mimick the stable processed form of the toxin found in larval midguts. However, it still requires the action of the synergistic 51.4-kDa protein for the larvicidal activity.     

Cloning of the argF gene encoding the ornithine carbamoyltransferase from Corynebacterium glutamicum.

The argF gene encoding ornithine carbamoyl-transferase (OTCase; EC2.1.3.3) has been cloned from Corynebacterium glutamicum by transforming the Escherichia coli arginine auxotroph with the genomic DNA library. The cloned DNA also complements the E. coli argG mutant, suggesting a clustered organization of the genes in the genome. We have determined the DNA sequence of the minimal fragment complementing the E. coli argF mutant. The coding region of the cloned gene is 957 nucleotides long with a deduced molecular mass of about 35 kDa polypeptide. The enzyme activity and size of the expressed protein in the E. coli auxotroph carrying the argF gene revealed that the cloned gene indeed codes for OTCase. Analysis of the amino acid sequence of the predicted protein revealed a strong similarity to the corresponding protein of other bacteria.     

Efficient Expression of the Mosquito Larvicidal Binary Toxin Gene from <Emphasis Type="Italic">Bacillus sphaericus</Emphasis> in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The binary toxin gene encoding BinA (42 kDa) and BinB (51 kDa) from Bacillus sphaericus strain 2297 was cloned and expressed in E. coli. Low expression level was found when both proteins were expressed from a single operon. High expression was observed when the gene encoding an individual protein was placed downstream of the T7 promoter. The expression level of BinB was not different when expressed alone (non-fusion) or as a fusion form with T7 peptide (T7-BinB). Both forms of BinB were equally stable. Unlike BinB, the non-fusion form of BinA was less stable than T7-BinA. The mosquito larvicidal test showed that BinA or BinB alone was not toxic to mosquito larvae, but high toxicity was found when both BinA and BinB were applied. The results suggest that a short peptide of T7 linked to the N-terminus of either BinA or BinB does not affect their toxicity, but may make the toxin, especially BinA, more stable.     

Molecular cloning of a major cell wall protein gene from protein-producing Bacillus brevis 47 and its expression in Escherichia coli and Bacillus subtilis

Bacillus brevis 47 contains two major cell wall proteins. Each protein forms a hexagonal array in the cell wall. A 4.8-kilobase HindIII fragment of B. brevis 47 DNA cloned into Escherichia coli with pBR322 as a vector directed the synthesis of polypeptides cross-reactive with antibody to the middle wall protein. A 700-base-pair BamHI-HpaI fragment was shown to be the essential region for the synthesis of immunoreactive polypeptides. Furthermore, this fragment appeared to contain the promoter activity. The 3.5-kilobase BamHI fragment covering the essential region as well as its downstream sequence was subcloned into the corresponding restriction site of pUB110 by using Bacillus subtilis as the cloning host. Both E. coli and B. subtilis carrying the cloned DNA synthesized several immunoreactive polypeptides which were mainly found in the cytoplasm. B. subtilis secreted polypeptides cross-reactive with antibody to the middle wall protein. These extracellular polypeptides were degraded upon prolonged culture.     

Vegetative expression of the delta-endotoxin genes of Bacillus thuringiensis subsp. kurstaki in Bacillus subtilis.

Bacillus thuringiensis subsp. kurstaki total DNA was digested with BglII and cloned into the BamHI site of plasmid pUC9 in Escherichia coli. A recombinant plasmid, pHBHE, expressed a protein of 135,000 daltons that was toxic to caterpillars. A HincII-SmaI double digest of pHBHE was then ligated to BglII-cut plasmid pBD64 and introduced into Bacillus subtilis by transformation. The transformants were identified by colony hybridization and confirmed by Southern blot hybridization. A 135,000-dalton protein which bound to an antibody specific for the crystal protein of B. thuringiensis was detected from the B. subtilis clones containing the toxin gene insert in either orientation. A toxin gene insert cloned into a PvuII site distal from the two drug resistance genes of the pBD64 vector also expressed a 135,000-dalton protein. These results suggest that the toxin gene is transcribed from its own promoter. Western blotting of proteins expressed at various stages of growth revealed that the crystal protein expression in B. subtilis begins early in the vegetative phase, while in B. thuringiensis it is concomitant with the onset of sporulation. The cloned genes when transferred to a nonsporulating strain of B. subtilis also expressed a 135,000-dalton protein. These results suggest that toxin gene expression in B. subtilis is independent of sporulation. Another toxin gene encoding a 130,000- to 135,000-dalton protein was cloned in E. coli from a library of B. thuringiensis genes established in lambda 1059. This gene was then subcloned in B. subtilis. The cell extracts from both clones were toxic to caterpillars. Electron microscope studies revealed the presence of an irregular crystal inclusion in E. coli and a well-formed bipyramidal crystal in B. subtilis clones similar to the crystals found in B. thuringiensis.     

Overproduction and purification of the connector protein of Bacillus subtilis phage phi 29.

A phi 29 DNA fragment containing genes 10 and 11, coding for the connector protein and the lower collar protein, respectively, has been cloned in the pBR322 derivative plasmid pKC30 under the control of the PL promoter of phage lambda. Two polypeptides with the electrophoretic mobility of proteins p10 and p11 were labelled with 35S-methionine after heat induction. The proteins were characterized as p10 and p11 by radioimmunoassay and they represented about 10% and 7%, respectively, of the total E. coli protein after 4 hours of induction. These proteins represent less than 1% of the B. subtilis protein in phi 29-infected cells. Protein p10 has been highly purified from the E. coli cells carrying the recombinant plasmid. Antibodies raised against the purified protein p10 reacted with the connector protein produced in phi 29-infected B. subtilis.     

Cloning and expression of the nitrile hydratase and amidase genes from Bacillus sp. BR449 into Escherichia coli

A moderate thermophile, Bacillus sp. BR449 was previously shown to exhibit a high level of nitrile hydratase (NHase) activity when growing on high levels of acrylonitrile at 55 degrees C. In this report, we describe the cloning of a 6.1 kb SalI DNA fragment encoding the NHase gene cluster of BR449 into Escherichia coli. Nucleotide sequencing revealed six ORFs encoding (in order), two unidentified putative proteins, amidase, NHase beta- and alpha-subunits and a small putative protein of 101 amino acids designated P12K. Spacings and orientation of the coding regions as well as their gene expression in E. coli suggest that the beta-subunit, alpha-subunit, and P12K genes are co-transcribed. Analysis of deduced amino acid sequences indicate that the amidase (348 aa, MW 38.6 kDa) belongs to the nitrilase-related aliphatic amidase family, and that the NHase beta- (229 aa, MW 26.5 kDa) and alpha- (214 aa, MW 24.5 kDa) subunits comprise a cobalt-containing member of the NHase family, which includes Rhodococcus rhodochrous J1 and Pseudomonas putida 5B NHases. The amidase/NHase gene cluster differs both in arrangement and composition from those described for other NHase-producing strains. When expressed in Escherichia coli DH5alpha, the subcloned NHase genes produced significant levels of active NHase enzyme when cobalt ion was added either to the culture medium or cell extracts. Presence of the P12K gene and addition of amide compounds as inducers were not required for this expression.     

Cloning and expression of Clostridium thermocellum F7 cellulase genes in Escherichia coli and Bacillus subtilis cells

The Clostridium thermocellum total DNA Sau 3A fragments' library was constructed on the basis of shuttle vector pMK4 for the Escherichia coli - Bacillus subtilis. 14 clones with endoglucanase activity and one with beta-glucosidase activity were selected in E. coli cells. Recombinant plasmids pCE were characterized by structural instability of various degree in B. subtilis cells. The results of the physical mapping, analysis of gene products in E. coli mini-cells as well as the DNA-DNA blot hybridization have led to conclusion on cloning of 7 individual genes for endoglucanases. Up to 3 polypeptides of various molecular weight corresponding to the products of cel gene were revealed in E. coli mini-cells containing the recombinant plasmids. The hybridization analysis demonstrated considerable homology of the majority of cel genes.     

Organization of genes expressing the blood-group-M-specific hemagglutinin of Escherichia coli: identification and nucleotide sequence of the M-agglutinin subunit gene

The organization of genes encoding the blood group M-specific hemagglutinin (M-agglutinin) of Escherichia coli strain IH11165 was studied with a cloned 6.5-kb DNA segment. This DNA segment contains at least five genes which code for the polypeptides of 12.5, 30, 80, 18.5 and 21 kDa. The 30-, 80- and 21-kDa polypeptides are synthesized as precursors that are approximately 2 kDa larger. The 21-kDa polypeptide was identified as the M-agglutinin subunit by its reactivity with anti-M-agglutinin serum. Nucleotide sequence analysis of the corresponding gene showed that the M-agglutinin precursor had a 24-amino acid (aa) signal sequence, while the mature protein is 146 aa residues long. Although the organization of the M-agglutinin gene cluster resembles those of other E. coli adhesins, there is no significant sequence homology between the M-agglutinin subunit and the subunits of the other potentially related proteins in E. coli.