Sporulation-associated activation of Bacillus sphaericus larvicide

Preparations of the larvicidal crystal from 46-h cultures of Bacillus sphaericus 2362 contain 125-, 110-, 63-, and 43-kilodalton (kDa) proteins (P. Baumann, B. M. Unterman, L. Baumann, A.H. Broadwell, S.J. Abbene, and R.D. Bowditch, J. Bacteriol. 163:738-747, 1985). The 63- and 43-kDa proteins, which have been purified, are not immunologically cross-reactive, and only the 43-kDa protein is toxic to mosquito larvae. Since antigenic determinants of the two smaller proteins have been detected in the higher-molecular-weight proteins (125 and 110 kDa), it has been suggested that the latter are precursors of the 43- and 63-kDa peptides. In the present study, purified 110-kDa protein was found to be toxic to the larvae of Culex pipiens (50% lethal concentration = 115 ng/ml). A luciferase-luciferin assay for intracellular ATP as well as an assay based on the exclusion of Trypan Blue by live cells indicated that the 110-kDa protein had no effect on tissue-culture-grown cells of C. quinquefasciatus, while cells exposed to the 43-kDa protein rapidly lost viability (50% lethal concentration = 54 microgram(s)/ml by the intracellular ATP assay). These findings suggested that the 110-kDa protein and, by extension, the 125-kDa protein are protoxins which are activated during sporulation by cleavage to a 43-kDa toxin. To further investigate the origins and relationships of the crystal proteins of B. sphaericus, we analyzed samples during the growth and sporulation of the culture. Synthesis of crystal proteins was initiated at the end of exponential growth and was completed after about 7 h.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification of the larvicidal toxin of Bacillus sphaericus and evidence for high-molecular-weight precursors

Crystals were purified from spore-crystal complexes of Bacillus sphaericus 2362 by disruption in a French pressure cell followed by centrifugation through 48% (wt/vol) NaBr. Crystals from such preparations had a 50% lethal concentration of 6 ng of protein per ml for the larvae of the mosquito Culex pipiens. When subjected to polyacrylamide gel electrophoresis under denaturing conditions, the proteins in B. sphaericus crystals migrated in positions corresponding to 43, 63, 98, 110, and 125 kilodaltons (kDa); solubilization of the crystal at pH 12 with NaOH eliminated all but the bands at 43 and 63 kDa. Since NaOH-solubilized preparations were toxic to mosquito larvae, these proteins were purified to electrophoretic homogeneity and antiserum was obtained to each. Analysis of the two purified proteins indicated that the 43-kDa protein was toxic to mosquito larvae (50% lethal concentration, 35 ng of protein per ml), whereas the 63-kDa protein was not. Further differences between them were their amino acid compositions, their lack of immunological cross-reactivity, their opposite net charges at pH 7.5, and their susceptibility to digestion by larval midgut proteases (the 63-kDa protein was highly susceptible, whereas the 43-kDa protein was not). The sequence of the 40 N-terminal residues of the 43-kDa protein was determined and found to contain a high percentage of hydrophobic amino acids. The sequence of the 63-kDa protein could not be determined, since it had multiple N termini. By electrophoretically separating the crystal proteins and then electroblotting onto nitrocellulose paper and visualizing the bands with antisera to the 43- and 63-kDa proteins in conjunction with an immunoblot assay, it was found that the high-molecular-mass crystal proteins (98 to 125 kDa) contained antigenic determinants of both proteins. These results suggested that the lower-molecular-weight crystal proteins detected in polyacrylamide gels after electrophoresis under denaturing conditions were derivatives of one or more of the higher-molecular-weight crystal proteins. In vivo studies of the products of crystal degradation by larvae of Culex pipiens indicated that the high-molecular-weight proteins and the 63-kDa antigenic determinants were rapidly degraded and that a 40-kDa protein related to the 43-kDa toxin persisted for the duration of the experiment (4 h). Some of the studies performed with B.sphaericus 2362 were extended to strains 1593, 1691, and 2297 of this species with results which indicated a high degree of similarity between the crystal proteins of all these larvicidal strains.     

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.     

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.     

Proteolysis in the gut of mosquito larvae results in further activation of the Bacillus sphaericus toxin.

Gut proteases from the larvae of the mosquito Culex pipiens convert the 43-kilodalton (kDa) toxin from Bacillus sphaericus 2362 to a 40-kDa peptide. The 50% lethal concentration of this peptide for tissue culture-grown cells of Culex quinquefasciatus was 1.0 microgram/ml (as determined by the intracellular ATP assay), 54-fold less than that of the 43-kDa peptide. Gut proteases from Anopheles gambiae and Aedes aegypti, as well as bovine pancreatic trypsin, also converted the 43-kDa protein to a 40-kDa peptide which was indistinguishable from the peptide formed by the proteases from C. pipiens with respect to its toxicity to tissue culture-grown cells of C. quinquefasciatus. Evidence for the in vivo conversion of the 43-kDa protein to the 40-kDa peptide was also obtained from experiments in which larvae of C. pipiens, Anopheles gambiae, and Aedes aegypti were fed crystals from B. sphaericus 2362. By using the exclusion of trypan blue as an indication of cell viability, it was shown that chitobiose, chitotriose, N-acetylmuramic acid, and N-acetylneuraminic acid decreased the toxicity of the 40-kDa peptide (from 100 to 50% mortality at about 10 mM concentrations of these sugars). Muramic acid, N-acetylgalactosamine, and N-acetylglucosamine were less effective, while several sugars had no effect, suggesting that the 40-kDa toxin binds to specific receptors on the cell membrane. The 40-kDa protein was less toxic to tissue culture-grown cells of Anopheles gambiae and Aedes dorsalis, and the same sugars which reduced the toxicity for cells of C. quinquefasciatus were also effective in reduction of toxicity for these cell lines.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proteolysis in the gut of mosquito larvae results in further activation of the Bacillus sphaericus toxin

Gut proteases from the larvae of the mosquito Culex pipiens convert the 43-kilodalton (kDa) toxin from Bacillus sphaericus 2362 to a 40-kDa peptide. The 50% lethal concentration of this peptide for tissue culture-grown cells of Culex quinquefasciatus was 1.0 microgram/ml (as determined by the intracellular ATP assay), 54-fold less than that of the 43-kDa peptide. Gut proteases from Anopheles gambiae and Aedes aegypti, as well as bovine pancreatic trypsin, also converted the 43-kDa protein to a 40-kDa peptide which was indistinguishable from the peptide formed by the proteases from C. pipiens with respect to its toxicity to tissue culture-grown cells of C. quinquefasciatus. Evidence for the in vivo conversion of the 43-kDa protein to the 40-kDa peptide was also obtained from experiments in which larvae of C. pipiens, Anopheles gambiae, and Aedes aegypti were fed crystals from B. sphaericus 2362. By using the exclusion of trypan blue as an indication of cell viability, it was shown that chitobiose, chitotriose, N-acetylmuramic acid, and N-acetylneuraminic acid decreased the toxicity of the 40-kDa peptide (from 100 to 50% mortality at about 10 mM concentrations of these sugars). Muramic acid, N-acetylgalactosamine, and N-acetylglucosamine were less effective, while several sugars had no effect, suggesting that the 40-kDa toxin binds to specific receptors on the cell membrane. The 40-kDa protein was less toxic to tissue culture-grown cells of Anopheles gambiae and Aedes dorsalis, and the same sugars which reduced the toxicity for cells of C. quinquefasciatus were also effective in reduction of toxicity for these cell lines.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tightly bound binary toxin in the cell wall of Bacillus sphaericus

We have shown that urea-extracted cell wall of entomopathogenic Bacillus sphaericus 2297 and some other strains is a potent larvicide against Culex pipiens mosquitoes, with 50% lethal concentrations comparable to that of the well-known B. sphaericus binary toxin, with which it acts synergistically. The wall toxicity develops in B. sphaericus 2297 cultures during the late logarithmic stage, earlier than the appearance of the binary toxin crystal. It disappears with sporulation when the binary toxin activity reaches its peak. Disruption of the gene for the 42-kDa protein (P42) of the binary toxin abolishes both cell wall toxicity and crystal formation. However, the cell wall of B. sphaericus 2297, lacking P42, kills C. pipiens larvae when mixed with Escherichia coli cells expressing P42. Thus, the cell wall toxicity in strongly toxic B. sphaericus strains must be attributed to the presence in the cell wall of tightly bound 51-kDa (P51) and P42 binary toxin proteins. The synergism between binary toxin crystals and urea-treated cell wall preparations reflects suboptimal distribution of binary toxin subunits in both compartments. Binary toxin crystal is slightly deficient in P51, while cell wall is lacking in P42.     

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.     

Deletion analysis of the 51-kilodalton protein of the Bacillus sphaericus 2362 binary mosquitocidal toxin: construction of derivatives equivalent to the larva-processed toxin.

Bacillus sphaericus 2362 produces a binary toxin consisting of 51- and 42-kDa proteins, both of which are required for toxicity to mosquito larvae. Upon ingestion by larvae, these proteins are processed to 43 and 39 kDa, respectively. Using site-directed mutagenesis, we have obtained N- and C-terminal deletions of the 51-kDa protein and expressed them in B. subtilis by using the subtilisin promoter. Removal of 21 amino acids from the N terminus and 53 amino acids from the C terminus resulted in a protein with the same electrophoretic properties as the 43-kDa degradation product which accumulates in the guts of mosquito larvae. This protein was toxic only in the presence of the 42-kDa protein. A deletion of 32 amino acids at the N terminus combined with a 53-amino-acid deletion at the C terminus resulted in a protein which retained toxicity. Toxicity was lost upon a further deletion of amino acids at potential chymotrypsin sites (41 at the N terminus, 61 at the C terminus). Comparison of the processing of the 51- and the 42-kDa proteins indicated that in spite of their sequence similarity proteolysis occurred at different sites.     

Construction by site-directed mutagenesis of a 39-kilodalton mosquitocidal protein similar to the larva-processed toxin of Bacillus sphaericus 2362.

After ingestion of the parasporal crystals of Bacillus sphaericus, mosquito larvae process the 42-kilodalton (kDa) toxin to a protein of 39 kDa, which has an increased toxicity (A. H. Broadwell and P. Baumann, Appl. Environ. Microbiol. 53:1333-1337, 1987). A similar activation is performed by trypsin and chymotrypsin. Using site-directed mutagenesis, we have constructed derivatives of the 42-kDa toxin with a deletion of 10 amino acids at the N terminus and deletions of 7, 17, or 20 amino acids at the C terminus. Toxicity for mosquito larvae was retained upon deletion of 7 or 17 amino acids but was lost upon deletion of 20 amino acids. Evidence is presented indicating that the protein containing deletions of 10 amino acids at the N terminus and 17 amino acids at the C terminus (corresponding to potential chymotrypsin cleavage sites) is similar to the 39-kDa protein produced in mosquito larvae or by digestion with chymotrypsin. Digestion with trypsin appears to generate a protein lacking 16 or 19 amino acids from the N terminus and 7 amino acids from the C terminus. As is the case with the recombinant-made 42-kDa protein, toxicity of its derivatives is dependent on the presence of a 51-kDa protein which is a component of the parasporal crystal of B. sphaericus 2362.     

Interaction of the Bacillus sphaericus mosquito larvicidal proteins

Genes for 51.4- and 41.9-kDa insecticidal proteins of Bacillus sphaericus were separately cloned and expressed in Escherichia coli. Both proteins were required for toxicity. Approximately equal numbers of cells containing the 51.4- and 41.9-kDa proteins produced the greatest toxicity; excess 41.9-kDa protein did not affect toxicity, whereas excess 51.4-kDa protein reduced activity. Larvae were killed when 41.9-kDa protein was fed up to 24 h after the 51.4-kDa protein, but not when the order of feeding was reversed. Radiolabelled toxins bound in approximately equal amounts to the gastric caecum and posterior midgut of Culex quinquefasciatus larvae. Radiolabelled 51.4-kDa protein was rapidly degraded by ca. 12-13 kDa in the larval gut, while 41.9-kDa protein was degraded by 1-2 kDa. Nonreduced toxin extracted from B. sphaericus produced a band on SDS-PAGE of ca. 68-74 kDa that contained both 51.4- and 41.9-kDa proteins based on sequence analysis, and a band of ca. 51 kDa that contained primarily 41.9-kDa protein. Escherichia coli containing 51.4-kDa protein enhanced toxicity of the latter eluted SDS-PAGE band. These proteins may associate very strongly, and trace amounts of 51.4-kDa protein in preparations of 41.9-kDa protein from B. sphaericus may be responsible for the previously reported toxicity of the latter.     

Molecular cloning of the 130-kilodalton mosquitocidal delta-endotoxin gene of Bacillus thuringiensis subsp. israelensis in Bacillus sphaericus

A 3.7-kilobase (kb) XbaI fragment harboring the cryIVB gene (L. Thorne, F. Garduno, T. Thompson, D. Decker, M. A. Zounes, M. Wild, A. M. Walfield, and T. J. Pollock, J. Bacteriol. 166:801-811, 1986) which encoded a 130-kilodalton (kDa) mosquitocidal toxin from a 110-kb plasmid of Bacillus thuringiensis subsp. israelensis 4Q2-72 was cloned into pUC12 and transformed into Escherichia coli. The clone with a recombinant plasmid (designated pBT8) was toxic to Aedes aegypti larvae. The fragment (3.7 kb) was ligated into pBC16 (tetracycline resistant [Tcr]) and transformed by the method of protoplast transformation into Bacillus sphaericus 1593 and 2362, which were highly toxic to Anopheles and Culex mosquito larvae but less toxic to Aedes larvae. After cell regeneration on regeneration medium, the Tcr plasmids from transformants (pBTC1) of both strains of B. sphaericus were prepared and analyzed. The 3.7-kb XbaI fragment from the B. thuringiensis subsp. israelensis plasmid was shown to be present by agarose gel electrophoresis and Southern blot hybridization. In addition, B. sphaericus transformants produced a 130-kDa mosquitocidal toxin which was detected by Western (immuno-) blot analysis with antibody prepared against B. thuringiensis subsp. israelensis 130-kDa mosquitocidal toxin. The 50% lethal concentrations of the transformants of strains 1593 and 2362 against A. aegypti larvae were 2.7 X 10(2) and 5.7 X 10(2) cells per ml, respectively. This level of toxicity was comparable to the 50% lethal concentration of B. thuringiensis subsp. israelensis but much higher than that of B. sphaericus 1593 and 2362 (4.7 X 10(4) cells per ml) against A. aegypti larvae.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning of the 130-kilodalton mosquitocidal delta-endotoxin gene of Bacillus thuringiensis subsp. israelensis in Bacillus sphaericus.

A 3.7-kilobase (kb) XbaI fragment harboring the cryIVB gene (L. Thorne, F. Garduno, T. Thompson, D. Decker, M. A. Zounes, M. Wild, A. M. Walfield, and T. J. Pollock, J. Bacteriol. 166:801-811, 1986) which encoded a 130-kilodalton (kDa) mosquitocidal toxin from a 110-kb plasmid of Bacillus thuringiensis subsp. israelensis 4Q2-72 was cloned into pUC12 and transformed into Escherichia coli. The clone with a recombinant plasmid (designated pBT8) was toxic to Aedes aegypti larvae. The fragment (3.7 kb) was ligated into pBC16 (tetracycline resistant [Tcr]) and transformed by the method of protoplast transformation into Bacillus sphaericus 1593 and 2362, which were highly toxic to Anopheles and Culex mosquito larvae but less toxic to Aedes larvae. After cell regeneration on regeneration medium, the Tcr plasmids from transformants (pBTC1) of both strains of B. sphaericus were prepared and analyzed. The 3.7-kb XbaI fragment from the B. thuringiensis subsp. israelensis plasmid was shown to be present by agarose gel electrophoresis and Southern blot hybridization. In addition, B. sphaericus transformants produced a 130-kDa mosquitocidal toxin which was detected by Western (immuno-) blot analysis with antibody prepared against B. thuringiensis subsp. israelensis 130-kDa mosquitocidal toxin. The 50% lethal concentrations of the transformants of strains 1593 and 2362 against A. aegypti larvae were 2.7 X 10(2) and 5.7 X 10(2) cells per ml, respectively. This level of toxicity was comparable to the 50% lethal concentration of B. thuringiensis subsp. israelensis but much higher than that of B. sphaericus 1593 and 2362 (4.7 X 10(4) cells per ml) against A. aegypti larvae.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modification of the Bacillus sphaericus 51- and 42-kilodalton mosquitocidal proteins: effects of internal deletions, duplications, and formation of hybrid proteins

The 51- and 42-kDa proteins which constitute the binary mosquitocidal toxin of Bacillus sphaericus 2362 have a low overall sequence similarity but share several regions of near identity (L. Baumann, A. H. Broadwell, and P. Baumann, J. Bacteriol. 170:2045-2050, 1988). By using site-directed mutagenesis, deletions of 6 to 16 amino acids in three of these regions of the 51- and 42-kDa proteins were made, and the modified proteins were expressed in Bacillus subtilis. Deletions in both of these proteins resulted in a loss of toxicity for mosquito larvae. Hybrid proteins containing exchanged fragments of the 51- and 42-kDa proteins were inactive when tested in a variety of combinations, thereby indicating that potentially analogous fragments of these two proteins were not functionally equivalent. An internal duplication of 73 amino acids in the 51-kDa protein and 72 amino acids in the 42-kDa protein resulted in a major reduction in toxicity. These results indicate that the conserved regions of the 51- and 42-kDa proteins are necessary for toxicity to larvae and that the 51- and 42-kDa proteins, despite their sequence similarity, are unique, differing from each other by at least one essential attribute.     

Modification of the Bacillus sphaericus 51- and 42-kilodalton mosquitocidal proteins: effects of internal deletions, duplications, and formation of hybrid proteins.

The 51- and 42-kDa proteins which constitute the binary mosquitocidal toxin of Bacillus sphaericus 2362 have a low overall sequence similarity but share several regions of near identity (L. Baumann, A. H. Broadwell, and P. Baumann, J. Bacteriol. 170:2045-2050, 1988). By using site-directed mutagenesis, deletions of 6 to 16 amino acids in three of these regions of the 51- and 42-kDa proteins were made, and the modified proteins were expressed in Bacillus subtilis. Deletions in both of these proteins resulted in a loss of toxicity for mosquito larvae. Hybrid proteins containing exchanged fragments of the 51- and 42-kDa proteins were inactive when tested in a variety of combinations, thereby indicating that potentially analogous fragments of these two proteins were not functionally equivalent. An internal duplication of 73 amino acids in the 51-kDa protein and 72 amino acids in the 42-kDa protein resulted in a major reduction in toxicity. These results indicate that the conserved regions of the 51- and 42-kDa proteins are necessary for toxicity to larvae and that the 51- and 42-kDa proteins, despite their sequence similarity, are unique, differing from each other by at least one essential attribute.     

Efficient expression of a 100-kilodalton mosquitocidal toxin in protease-deficient recombinant Bacillus sphaericus.

The expression of the 100-kDa mosquitocidal toxin (Mtx) during vegetative growth and sporulation in nine different mosquito-larvicidal strains of Bacillus sphaericus has been analyzed. In five out of the nine strains the 100-kDa toxin was found to be expressed predominantly in the vegetative phase of growth, and in all nine strains the level of the toxin in sporulated cells was very low or undetectable. Strains in four out of the six DNA homology groups of B. sphaericus produced intracellular and extracellular proteases, which degraded the 100-kDa toxin, during sporulation. The 100-kDa toxin gene was expressed by using its native promoter on a multicopy number plasmid in B. sphaericus 1693 (protease negative) and B. sphaericus 13052 (protease positive). High levels of the 100-kDa toxin were produced in vegetative cells of both strains as well as in sporulated cells of protease-negative strain 1693, which is in contrast to the low levels of the 100-kDa toxin produced in sporulated cells of protease-positive strain 13052. Thus, the small amount of the 100-kDa toxin in sporulated cells of the nine mosquito-larvicidal strains is probably due to degradation of the 100-kDa toxin synthesized during vegetative growth by a protease(s) produced during sporulation. B. sphaericus 1693 transformed with the 100-kDa toxin gene was as toxic to mosquito larvae during both vegetative growth and sporulation as the natural high-toxicity strains of sporulated B. sphaericus.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

球形芽孢杆菌杀蚊毒素蛋白及其 遗传操作研究进展

蚊虫是多种人类传染疾病的主要传播媒介,如疟疾、丝虫病、乙型脑炎、黄热病和登革热等,对人类的健康造成了极大的危害［１］。控制蚊虫被认为是消除这些蚊媒疾病的有效途径。在过去的４５年里,尽管化学杀虫剂和各种抗病药物的使用对降低疟疾和蚊媒疾病的发病率和死亡率...     

Two novel strains of Bacillus thuringiensis toxic to coleopterans.

Two novel strains of Bacillus thuringiensis were isolated from native habitats by the use of genes coding for proteins toxic to coleopterans (cryIII genes) as hybridization probes. Strain EG2838 (isolated by the use of the cryIIIA probe) contained a cryIIIA-hybridizing plasmid of approximately 100 MDa and synthesized crystal proteins of approximately 200 (doublet), 74, 70, 32, and 28 kDa. Strain EG4961 (isolated by the use of a cryIIIA-related probe) contained a cryIIIA-hybridizing plasmid of approximately 95 MDa and synthesized crystal proteins of 74, 70, and 30 kDa. Structural relationships among the crystal proteins of strains EG2838 and EG4961 were detected; antibodies to the CryIIIA protein toxic to coleopterans reacted with the 74- and 70-kDa proteins of EG2838 and EG4961, antibodies to the 32-kDa plus 28-kDa proteins of EG2838 reacted with the 30-kDa protein of EG4961, and antibodies to the 200-kDa proteins of EG2838 reacted with the 28-kDa protein of EG2838. Experiments with B. thuringiensis flagella antibody reagents demonstrated that EG2838 belongs to H serotype 9 (reference strain B. thuringiensis subsp. tolworthi) and that EG4961 belongs to H serotype 18 (reference strain B. thuringiensis subsp. kumamotoensis). A mixture of spores plus crystal proteins of either EG2838 or EG4961 was toxic to the larvae of Colorado potato beetle (Leptinotarsa decemlineata), and significantly, the EG4961 mixture was also toxic to the larvae of southern corn rootworm (Diabrotica undecimpunctata howardi). DNA restriction blot analysis suggested that strains EG2838 and EG4961 each contained a unique gene coding for a protein toxic to coleopterans.     

Two novel strains of Bacillus thuringiensis toxic to coleopterans.

Two novel strains of Bacillus thuringiensis were isolated from native habitats by the use of genes coding for proteins toxic to coleopterans (cryIII genes) as hybridization probes. Strain EG2838 (isolated by the use of the cryIIIA probe) contained a cryIIIA-hybridizing plasmid of approximately 100 MDa and synthesized crystal proteins of approximately 200 (doublet), 74, 70, 32, and 28 kDa. Strain EG4961 (isolated by the use of a cryIIIA-related probe) contained a cryIIIA-hybridizing plasmid of approximately 95 MDa and synthesized crystal proteins of 74, 70, and 30 kDa. Structural relationships among the crystal proteins of strains EG2838 and EG4961 were detected; antibodies to the CryIIIA protein toxic to coleopterans reacted with the 74- and 70-kDa proteins of EG2838 and EG4961, antibodies to the 32-kDa plus 28-kDa proteins of EG2838 reacted with the 30-kDa protein of EG4961, and antibodies to the 200-kDa proteins of EG2838 reacted with the 28-kDa protein of EG2838. Experiments with B. thuringiensis flagella antibody reagents demonstrated that EG2838 belongs to H serotype 9 (reference strain B. thuringiensis subsp. tolworthi) and that EG4961 belongs to H serotype 18 (reference strain B. thuringiensis subsp. kumamotoensis). A mixture of spores plus crystal proteins of either EG2838 or EG4961 was toxic to the larvae of Colorado potato beetle (Leptinotarsa decemlineata), and significantly, the EG4961 mixture was also toxic to the larvae of southern corn rootworm (Diabrotica undecimpunctata howardi). DNA restriction blot analysis suggested that strains EG2838 and EG4961 each contained a unique gene coding for a protein toxic to coleopterans.