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

Larvicidal and histopathological efficacy of inhabitant pathogenic bacterial strains to reduce the dengue vector competence

BACKGROUND

Aedes aegypti is a primary vector of dengue virus, and the causative agent of dengue is emerging globally as one of the most important arboviral diseases currently threatening human populations. Therefore, vector control is presently the primary intervention method of population reduction, in which natural A. aegypti populations would be reduced with inhabitant bacterial strains that are unable to transmit dengue virus.

RESULT

Based on the pathogenicity of strains, only four isolates effectively show larvicidal activity. The 16S rRNA gene sequences and the phylogeny depicted that the potential isolates were Bacillus firmus (MK791255), Bacillus paramycoides (MK788268), Bacillus siamensis (MK788212), and Bacillus licheniformis (MK791256). After 24 and 48 hours exposure, the B. licheniformis strain (cell mass of 2.2 × 10⁷ CFU mL^-1 ) showed potent larvicidal activity with LC₅₀ of 16.22 μg mL^-1 and 9.57 μg mL^-1 and the B. paramycoides (cell mass of 3.1 × 10⁷ CFU mL^-1 ) strain inhibits the larval and pupal development with LC₅₀ of 42.62 μg mL^-1 and 26.97 μg mL^-1 . Intermittent stages and causes of abscess in the gut and siphon regions were observed through histopathological studies. These two bacterial strains extend larval duration up to 15-16 days as well as reduce development.

CONCLUSION

These studies demonstrate the challenge for dengue vector in reducing developmental and reproduction competence. © 2020 Society of Chemical Industry.

Purification and characterization of mosquitocidal Bacillus sphaericus BinA protein

Certain strains of Bacillus sphaericus produce a highly toxic mosquito-larvicidal binary toxin during sporulation. The binary toxin is composed of toxic BinA (41.9kDa) and receptor binding BinB (51.4kDa) polypeptides and is active against vectors of filariasis, encephalitis and malaria. The toxin has been tested with limited use for the control of vector mosquitoes for more than two decades. The binA gene from a local ISPC-8 strain of B. sphaericus that is highly toxic to Culex and Anopheles mosquito species was cloned into pET16b and expressed in Escherichia coli. The purified BinA protein differs by one amino acid (R197M) from BinA of the highest toxicity strains 1593/2362/C3-41. Majority of the expressed protein was observed in inclusion bodies. BinA inclusions alone from E. coli did not show toxic activity, like reported previously. However, the active form of BinA could be purified to homogeneity from the soluble fraction of E. coli cell lysate, grown at reduced temperature after isopropyl beta-d-thiogalactopyranoside induction. The purified BinA protein with and without poly-histidine tag showed LC(50) dose of 82.3 and 66.9ngml(-1), respectively, at 48h against Culex quinquefasciatus larvae. The secondary structure of BinA is expected to be mainly beta strands as estimated using far-UV circular dichroism. The estimates matched well with the secondary structure predictions using amino acid sequence. This is the first report of large-scale purification and accurate toxicity estimation of soluble B. sphaericus BinA. This can help in design and synthesis of improved bacterial insecticide.

A 1.1-kilobase region downstream of the bin operon in Bacillus sphaericus strain 2362 decreases bin yield and crystal size in strain 2297

The 2297 strain of Bacillus sphaericus produces a crystal of the Bin (binary) toxin that is approximately fourfold larger than that of strain 2362, the strain currently used in VectoLex, a commercial mosquito larvicide. Comparison of the regions downstream from the bin operon in these two strains showed that strain 2362 contained a 1.6-kb region with four orf genes not found in strain 2297. Insertion of a 1.1-kb portion of this region from strain 2362 by homologous recombination downstream from the bin operon in strain 2297 reduced Bin toxin production by 50 to 70% and toxicity to fourth-instar larvae of Culex quinquefasciatus by 68%. These results suggest that the 1.6-kb region downstream from the bin operon in B. sphaericus 2362 is responsible for the lower Bin yield and smaller crystal size characteristic of this strain.

Developing recombinant bacteria for control of mosquito larvae

Genetic engineering techniques have been used to significantly improve mosquito larvicides based on the bacteria Bacillus thuringiensis (Bt) subsp. israelensis (Bti) and Bacillus sphaericus (Bs). These new larvicides hold excellent promise for providing better and more cost-effective control of nuisance mosquitoes and vectors of important diseases, including the anopheline vectors of malaria and culicine vectors responsible for filariasis and viral encephalitides. The toxicity of Bti and Bs is due primarily to endotoxin proteins produced during sporulation. After ingestion by larvae, these are activated and destroy the larval stomach, quickly resulting in death. By cloning the genes encoding various endotoxins from Bt and Bs species, and engineering these for high levels of synthesis, we have been able to generate recombinant bacterial strains based on Bti that are more than 10 times as effective as the conventional strains of Bti or Bs that serve as the active ingredients of commercial bacterial larvicides currently used for mosquito control. The best of these recombinants contain all major Bti endotoxins, specifically, Cry4A, Cry4B, Cry11A, and Cyt1A, plus the binary (Bin) endotoxin of Bs, the principal mosquitocidal protein responsible for the activity of this species. The presence of Cyt1A in these recombinants, which synergizes Cry toxicity and delays resistance to these proteins and Bs Bin, should enable long term use of these recombinants with little if any development of resistance. In the field, these new recombinants should be particularly effective larvicides against most important vectors and nuisance species of the genus Culex, the malaria vectors Anopheles gambiae and An. arabiensis, and species of Aedes and Ochlerotatus sensitive to Bs.

Implications of high-molecular-weight oligomers of the binary toxin from Bacillus sphaericus

The mosquito-larvicidal binary toxin produced by Bacillus sphaericus is composed of BinB and BinA, which have calculated molecular weights of 51.4 and 41.9 kDa, respectively. NaOH extracts of B. sphaericus spores were analyzed using SDS-PAGE. Stained gels showed bands with molecular weights corresponding to those of BinB and BinA as well as two additional bands at 110 and 125 kDa. The matrix-assisted laser desorption/ionization mass spectrum of the purified 110 and 125 kDa bands showed two peaks at 104,160 and 87,358 Da that are assigned to dimers of BinB and BinA, respectively. Mass spectral analysis of trypsin-digested 110 and 125 kDa bands showed peaks at 51,328, 43,523, 43,130, and 40,832 Da that assigned to undigested BinB, two forms of digested BinB and digested BinA, respectively. Dynamic light scattering studies showed a solution of the purified 110 and 125 kDa bands was comprised almost entirely (99.6% of total mass) of a particle with a hydrodynamic radius of 5.6+/-1.2 nm and a calculated molecular weight of 186+/-38 kDa. These data demonstrate that the binary toxin extracted from B. sphaericus spores can exist in solution as an oligomer containing two copies each of BinB and BinA.

Regulation of mosquitocidal toxin synthesis in Bacillus sphaericus

Translational lacZ fusions to the promoters of the parasporal, crystal protein (binary toxin) and 100-kDa ADP-ribosylating mosquitocidal toxin genes of Bacillus sphaericus were prepared and expression of the toxin genes monitored as beta-galactosidase activity. Transcription of the crystal protein gene fusion began immediately before the end of exponential growth and continued into stationary phase in both B. sphaericus and Bacillus subtilis but accompanied exponential-phase growth in Escherichia coli. Expression of this fusion was severely delayed in a B. subtilis spo0A mutant and decreased relative to the wild type in a B. subtilis spoIIAC background. beta-Galactosidase activity from the 100-kDa toxin gene fusion was restricted to early exponential phase in B. sphaericus, but in B.subtilis it continued into late exponential phase. Expression was about eightfold lower in B. sphaericus than B. subtilis suggesting an element of negative control in the native host.

Mosquitocidal toxins of bacilli and their genetic manipulation for effective biological control of mosquitoes

The identification, cloning, and characterization of protein toxins from various species of bacilli have demonstrated the existence of mosquitocidal toxins with different structures, mechanisms of action, and host ranges. A start has been made in understanding the polypeptide determinants of toxicity and insecticidal activity, and the purification of toxins from recombinant organisms may lead to the elucidation of their X-ray crystal structures and the cloning of brush border membrane receptors. The results of cloning mosquitocidal toxins in heterologous microorganisms show the potential of expanding the range of susceptible mosquito species by combining several toxins of different host specificity in one cell. Toxins have been expressed in new microorganisms with the potential for increasing potency by persisting at the larval feeding zone. The powerful tools of bacterial genetics are being applied to engineer genetically stable, persistent toxin expression and expand the insecticidal host ranges of Bacillus sphaericus and Bacillus thuringiensis strains. These techniques, together with modern formulation technology, should eventually lead to the construction of mosquitocidal microorganisms which are effective enough to have a real impact on mosquito-borne diseases.

Cytotoxicity and ADP-ribosylating activity of the mosquitocidal toxin from Bacillus sphaericus SSII-1: possible roles of the 27- and 70-kilodalton peptides

Clones expressing regions of the 100-kDa Bacillus sphaericus SSII-1 mosquitocidal toxin (Mtx) as fusion proteins with glutathione S-transferase were constructed, and the toxin-derived peptides were purified. The in vitro ADP-ribosylation activities of these peptides and their effects on larvae and cells in culture were studied. Mtx25 (amino acids 30 to 493) was found to ADP-ribosylate two proteins with molecular masses of 38 and 42 kDa, respectively, in Culex quinquefasciatus (G7) cell extracts, in addition to ADP-ribosylating itself. Mtx21 (amino acids 30 to 870; or a combination of Mtx25 and Mtx26 (amino acids 259 to 870) caused mortality in C. quinquefasciatus larvae. Mtx25, Mtx26, or Mtx24 (amino acids 30 to 276) alone and Mtx24 in combination with Mtx26 were not toxic to larvae. Mtx21 and Mtx26 produced marked morphological changes in G7 cells and to a lesser extent in Aedes aegypti cells but had no effect on Anopheles gambiae or HeLa cells. Thus, a domain in the N-terminal region of the Mtx protein is sufficient for ADP-ribosylation of C. quinquefasciatus cell protein, and a domain in the C-terminal region is sufficient for toxicity to cultured C. quinquefasciatus cells; however, both regions are necessary for toxicity to mosquito larvae.

Proteolytic processing of the mosquitocidal toxin from Bacillus sphaericus SSII-1

The 97-kDa protein Mtx21, derived from the 100-kDa mosquitocidal protein (Mtx) from Bacillus sphaericus SSII-1 by the deletion of the putative signal sequence, was expressed as a fusion protein with glutathione S-transferase in Escherichia coli, and the fusion protein was purified by affinity chromatography. The fusion protein bound to glutathione agarose was cleaved with thrombin to release the Mtx21 protein. The 97-kDa Mtx21 protein was found to be toxic to Culex quinquefasciatus larvae with a 50% lethal concentration of 15 ng/ml. Treating Mtx21 with crude mosquito larval gut extracts gave rise to two major peptides of 70 and 27 kDa. Treating the 97-kDa Mtx21 protein with trysin also gave rise to a similar proteolytic cleavage pattern. N-terminal sequencing showed that the 27-kDa peptide was derived from the N-terminal region of the 97-kDa protein and that the 70-kDa protein was from the C-terminal region of the 97-kDa protein. The 27-kDa peptide has all the previously identified regions of homology with the catalytic peptides of the ADP-ribosyltransferase toxins, such as pertussis toxin S1 peptide, while the 70-kDa peptide has three internal regions of homology.

Characterization and toxicity to mosquito larvae of four Bacillus sphaericus strains isolated from Brazilian soils

Four Bacillus sphaericus strains, S1, S2, S5, and L2, isolated from Brazilian soils, were found to be toxic to larvae of the mosquitoes Culex pipiens and Anopheles stephensi at a level similar to that of strain 2362 which is now used operationally. Like strain 2362, the four strains belonged to the serotype H5 and produced major proteins of apparent molecular weights of 125, 110, 56, and 43 kDa. These latter two proteins were immunologically related to toxins of the same molecular weight as B. sphaericus 2362. Although the four Brazilian strains were very similar to strain 2362, gas chromatography analysis of the fatty acids revealed that these strains were different from strain 2362 and from each other, except for a possible similarity between strains S1 and S5.

Genomic variations in mosquitocidal strains of Bacillus sphaericus detected by M13 DNA fingerprinting

The genomic variation of Bacillus sphaericus reference and local strains belonging to different serotypes was examined by DNA fingerprinting. A phage M13 DNA probe detected a number of variable fragments in the restriction digests of total strain DNAs. The patterns of band distribution showed a certain homology among mosquitocidal strains, expressed by similarity index D and might be a reliable criterion for assessing the level of genomic similarity between closely related strains. An important advantage of DNA fingerprinting is the differentiation of one bacterial strain from another, both expressing common phenotype and possessing highly similar genomic portions. The strain variation revealed by the M13 probe will be useful for characterization of individual strains within a serotype. It could help as well to solve some uncertain cases based on the results obtained by other methods of identification.

Bacillus sphaericus as a mosquito pathogen: properties of the organism and its toxins

In the course of sporulation, Bacillus sphaericus produces an inclusion body which is toxic to a variety of mosquito larvae. In this review we discuss the general biology of this species and concentrate on the genetics and physiology of toxin production and its processing in the midgut of the larval host. The larvicide of B. sphaericus is unique in that it consists of two proteins of 51 and 42 kDa, both of which are required for toxicity to mosquito larvae. There is a low level of sequence similarity between these two proteins, which differ in their sequences from all the other known insecticidal proteins of Bacillus thuringiensis. Within the midgut the 51- and 42-kDa proteins are processed to proteins of 43 and 39 kDa, respectively. The conversion of the 42-kDa protein to a 39-kDa protein results in a major increase in toxicity; the significance of the processing of the 51-kDa protein is not known. In contrast to the results with mosquito larvae, the 39-kDa protein is alone toxic for mosquito-derived tissue culture-grown cells, and this toxicity is not affected by the 51-kDa protein or its derivative, the 43-kDa protein. Comparisons of larvae from species which differ in their susceptibility to the B. sphaericus toxin indicate that the probable difference resides in the nature of the target sites of the epithelial midgut cells and not in uptake or processing of the toxin. A similar conclusion is derived from experiments involving tissue culture-grown cells from mosquito species which differ in their susceptibility to the B. sphaericus toxin.

Isolation and identification of Bacillus sphaericus strains pathogenic for mosquito larvae

Three selective media for the isolation of Bacillus sphaericus have been compared. BATS medium and a formulation employing adenosine as the principal carbon source were the most effective for the recovery of spores of strain 1593. Anthranilic acid as the principal carbon source was less efficient. Eighty-four strains were isolated from mud samples using these media and were identified by computer. Identifications were confirmed for representative strains using DNA sequence homology. Most were B. sphaericus sensu stricto or members of an unnamed group. However, one strain (BSE 18) was identified as the DNA homology group IIB and this organism was found to be highly toxic toward larvae of Culex pipiens. Southern hybridization of BSE 18 DNA to a probe prepared from the cloned toxin gene from strain 1593 revealed that BSE 18 contained a typical gene for the 41.9-kDa toxin.

Cloning, sequencing, and expression of a gene encoding a 100-kilodalton mosquitocidal toxin from Bacillus sphaericus SSII-1

A cosmid library was prepared from a partial BamHI digest of total DNA from Bacillus sphaericus SSII-1. Two hundred fifty Escherichia coli clones were screened for toxicity against larvae of the mosquito Culex quinquefasciatus. One toxic clone, designated pKF2, was chosen for further study. Two toxic subclones, designated pXP33 and pXP34, obtained by ligating PstI-derived fragments of pKF2 into pUC18, contained the same 3.8-kb fragment, but in opposite orientations. Sequence analysis revealed the presence of an open reading frame corresponding to a 100-kDa protein and the 3' end of a further open reading frame having significant homology to open reading frames of transposons Tn501 and Tn21. The sequence of the SSII-1 toxin was compared with those of known toxins and was found to show regional homology to those of ADP-ribosyltransferase toxins. The distribution of the toxin gene among other B. sphaericus strains was examined.

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.

The 42- and 51-kilodalton mosquitocidal proteins of Bacillus sphaericus 2362: construction of recombinants with enhanced expression and in vivo studies of processing and toxicity

After site-directed mutagenesis, the genes coding for the 42- and 51-kilodalton (kDa) mosquitocidal proteins of Bacillus sphaericus 2362 were placed under the regulation of the aprE (subtilisin) promoter of the Bacillus subtilis vector pUE (a derivative of pUB18). The levels of expression of the gene products in B. subtilis DB104 and B. sphaericus 718 were assessed by bioassays with larvae of Culex pipiens and by Western immunoblots. The results indicated that a higher amount of protein was produced in B. subtilis DB104. Electron microscopic examination of B. subtilis DB104 and B. sphaericus 718 containing the 42- and 51-kDa proteins indicated that amorphous inclusions accumulated in the former species and that crystals identical in appearance to that found in B. sphaericus 2362 were produced in the latter. Strains producing only the 42- or the 51-kDa protein were not toxic to larvae of C. pipiens. A mixture of both strains, a single strain producing both proteins, or a fusion of the 51- and the 42-kDa proteins was toxic. The amount of B. subtilis DB104 containing the 42- and the 51-kDa proteins necessary to kill 50% of the larvae of C. pipiens was 5.6 ng (dry weight) of cells per ml. This value was significantly lower than that for B. sphaericus 2362 (14 ng [dry weight] per ml). Larvae consuming purified amorphous inclusions containing the 42-kDa protein degraded this protein this protein to primarily 39- and 24-kDa peptides, whereas inclusions with the 51-kDa protein were primarily degraded to a protein of 44 kDa. Past studies involving purified proteins from B. sphaericus 2362 indicate an associate of toxicity with the 39-kDa peptide. The results presented here suggest that the 44-kDa degradation product of the 51-kDa protein may also be required for toxicity.

Transfer of the toxin protein genes of Bacillus sphaericus into Bacillus thuringiensis subsp. israelensis and their expression

The genes encoding the toxic determinants of Bacillus sphaericus have been expressed in a nontoxic and a toxic strain of Bacillus thuringiensis subsp. israelensis. In both cases, the B. sphaericus toxin proteins were produced at a high level during sporulation of B. thuringiensis and accumulated as crystalline structures. B. thuringiensis transformants expressing B. sphaericus and B. thuringiensis subsp. israelensis toxins did not show a significant enhancement of toxicity against Aedes aegypti, Anopheles stephensi, and Culex pipiens larvae.

On the respective roles of the two proteins encoded by the Bacillus sphaericus 1593M toxin genes expressed in Escherichia coli and Bacillus subtilis

The 3.6 kb HindIII DNA fragment of B. sphaericus 1593M chromosomal DNA bears two genes encoding two polypeptides of 41.9 kDa (protein "42") and 51.4 kDa (protein "51"). DNA fragments carrying only one of these two genes when expressed in E. coli yield products that are inactive towards Culex larvae. The larvicidal activity is recovered when Triton X-100 treated E. coli cells containing each one of the two genes are incubated together. In E. coli these two polypeptides are acting synergistically. The protein "51" appears to be involved in the maturation of protein "42" for expression of the larvicidal activity. In B. subtilis however the toxicity is expressed by cells carrying only the gene coding for protein "42". There is no need of the "51" gene product for the maturation of the "42" polypeptide, suggesting that the maturation is most likely accomplished by host enzymes.

Cloning and sequencing of the gene encoding a 125-kilodalton surface-layer protein from Bacillus sphaericus 2362 and of a related cryptic gene

Using the vector pGEM-4-blue, a 4,251-base-pair DNA fragment containing the gene for the surface (S)-layer protein of Bacillus sphaericus 2362 was cloned into Escherichia coli. Determination of the nucleotide sequence indicated an open reading frame (ORF) coding for a protein of 1,176 amino acids with a molecular size of 125 kilodaltons (kDa). A protein of this size which reacted with antibody to the 122-kDa S-layer protein of B. sphaericus was detected in cells of E. coli containing the recombinant plasmid. Analysis of the deduced amino acid sequence indicated a highly hydrophobic N-terminal region which had the characteristics of a leader peptide. The first amino acid of the N-terminal sequence of the 122-kDa S-layer protein followed the predicted cleavage site of the leader peptide in the 125-kDa protein. A sequence characteristic of promoters expressed during vegetative growth was found within a 177-base-pair region upstream from the ORF coding for the 125-kDa protein. This putative promoter may account for the expression of this gene during the vegetative growth of B. sphaericus and E. coli. The gene for the 125-kDa protein was followed by an inverted repeat characteristic of terminators. Downstream from this gene (11.2 kilobases) was an ORF coding for a putative 80-kDa protein having a high sequence similarity to the 125-kDa protein. Evidence was presented indicating that this gene is cryptic.

Expression in Bacillus subtilis of the 51- and 42-kilodalton mosquitocidal toxin genes of Bacillus sphaericus

A 3,080-base-pair KpnI-HindIII DNA fragment from Bacillus sphaericus 2362 coding for 51- and 42-kilodalton mosquitocidal proteins was cloned into Bacillus subtilis DB104 by using the vector pUB18. In B. subtilis these proteins were not detected during vegetative growth but were expressed during sporulation at levels comparable to those found in B. sphaericus.

Toxicity of Bacillus sphaericus crystal toxin to adult mosquitoes

Adult Culex quinquefasciatus mosquitoes were killed by alkaline-solubilized Bacillus sphaericus toxin when it was introduced by enema into the midgut of the insect but not when it was administered orally. Adult Aedes aegypti mosquitoes were not affected by the toxin.

Sequence analysis of the mosquitocidal toxin genes encoding 51.4- and 41.9-kilodalton proteins from Bacillus sphaericus 2362 and 2297

The nucleotide sequences of a 3,479-base-pair HindIII DNA fragment from Bacillus sphaericus 2362 and a 2,940-base-pair fragment from strain 2297 were determined; only minor differences were detected between them. Each contained two open reading frames coding for proteins of 51.4 and 41.9 kilodaltons. Both proteins were required for toxicity to larvae of the mosquito Culex pipiens.

Bacillus sphaericus asporogenous mutants: morphology, protein pattern and larvicidal activity

Asporogenous mutants from Bacillus sphaericus strains 2297 and 1593-4, blocked at different stages of the sporulation process, were isolated. Two mutants (2297 Aspo30A and 2297 Aspo34) which were blocked early in sporulation did not possess any crystalline inclusions and were poorly toxic to Culex pipiens mosquito larvae. Other mutants (2297 Aspo115, 2297 Aspo24 and 1593-4 Aspo12) which were blocked at later stages synthesized crystal-like inclusions next to the forespores, and were highly toxic to mosquito larvae. Electrophoretic protein analysis of alkali extracts from mutants and wild type strains confirmed the absence of toxic crystal-related proteins in early-blocked mutants and their presence in later ones. Western blots with antisera directed against the crystal proteins confirmed those observations.