The protoxin composition of Bacillus thuringiensis insecticidal inclusions affects solubility and toxicity.

Most Bacillus thuringiensis strains producing toxins active on lepidoptera contain several plasmid-encoded delta-endotoxin genes and package related protoxins into a single inclusion. It was previously found that in B. thuringiensis subsp. aizawai HD133, which produces an inclusion comprising the CryIAb, CryIC, and CryID protoxins, there is a spontaneous loss in about 1% of the cells of a 45-mDa plasmid containing the cryIAb gene. As a result, inclusions produced by the cured strain were less readily solubilized at pH 9.2 or 9.5 and had a decreased toxicity for Plodia interpunctella, despite the presence of the CryIC protoxin, which was active when solubilized. These results suggested that protoxin composition was a factor in inclusion solubility and toxicity and that the cryIAb gene, which is also present on an unstable plasmid in several other subspecies, may have a unique role in inclusion solubility and toxicity. Introduction of a cloned copy of this gene into the plasmid-cured derivative of B. thuringiensis subsp. aizawai HD133 resulted in an increase in the solubility at pH 9.2 of all of the inclusion proteins from less than 20% to greater than 45% and a lowering of the 50% lethal concentration (LC50, in micrograms [dry weight] per square centimeter) of inclusions for Spodoptera frugiperda from 35 to 10. These values are the same as those found with inclusions from B. thuringiensis subsp. aizawai HD133, and in all cases, the LC50 of the solubilized protoxins was 10. Transformants containing related cryIA genes produced inclusions which were more than 95% solubilized at pH 9.2 but also had LC50 of 10.(ABSTRACT TRUNCATED AT 250 WORDS)     

Toxicity of Bacillus thuringiensis Spore and Crystal Protein to Resistant Diamondback Moth (Plutella xylostella)

A colony of Plutella xylostella from crucifer fields in Florida was used in mortality bioassays with HD-1 spore, CryIA(a), CryIA(b), CryIA(c), CryIB, CryIC, CryID, CryIE, or CryIIA. The data revealed high levels of field-evolved resistance to HD-1 spore and all CryIA protoxins and no resistance to CryIB, CryIC, or CryID. CryIE and CryIIA were essentially not toxic. When HD-1 spore was combined 1:1 with protoxin and fed to susceptible larvae, spore synergized the activity of CryIA and CryIC 5- to 8-fold and 1.7-fold, respectively, and did not synergize the mortality of CryIIA. When fed to Florida larvae, spore failed to synergize the activity of all three CryIA protoxins, synergized the activity of CryIC 5.3-fold, and did not synergize the mortality for CryIIA. Binding studies with CryIA(b), CryIB, and CryIC were performed to determine possible mechanisms of resistance. The two techniques used were (i) binding of biotinylated toxin to tissue sections of larval midguts and (ii) binding of biotinylated toxin to brush border membrane vesicles prepared from whole larvae. Both showed dramatically reduced binding of CryIA(b) in resistant larvae compared with that in susceptible larvae but no differences in binding of CryIB or CryIC.     

Mosquitocidal activity of the CryIC delta-endotoxin from Bacillus thuringiensis subsp. aizawai.

The cloned 135-kDa CryIC delta-endotoxin from Bacillus thuringiensis is a lepidopteran-active toxin, displaying high activity in vivo against Spodoptera litoralis and Spodoptera frugiperda larvae and in vitro against the S. frugiperda Sf9 cell line. Here, we report that the CryIC delta-endotoxin cloned from B. thuringienesis subsp. aizawai HD-229 and expressed in an acrystalliferous B. thuringiensis strain is also toxic to Aedes aegypti, Anophles gambiae, and Culex quinquefasciatus mosquito larvae. Furthermore, when solubilized and proteolytically activated by insect gut extracts, CryIC is cytotoxic to cell lines derived from the first two of these dipteran insects. This activity was not observed for two other lepidopteran-active delta-endotoxins, CryIA(a) and CryIA(c). However, in contrast to the case with a lepidopteran and dipteran delta-endotoxin cloned from B. thuringiensis subsp. aizawai IC1 (M.Z. Haider, B. H. Knowles, and D. J. Ellar, Eur. J. Biochem. 156:531-540, 1986), no differences in the in vitro specificity or processing of CryIC were found when it was activated by lepidopteran or dipteran gut extract. The recombinant CryIC delta-endotoxin expressed in Escherichia coli was also toxic to A. aegypti larvae. By contrast, a second cryIC gene cloned from B. thuringiensis subsp. aizawai 7.29 (V. Sanchis, D. Lereclus, G. Menou, J. Chaufaux, S. Guo, and M. M. Lecadet, Mol. Microbiol. 3:229-238, 1989) was nontoxic. DNA sequencing showed that the two genes were identical. However, CryIC from B. thuringiensis subsp. aizawai 7.29 had been cloned with a truncated C terminus, and when it was compared with the full-length CryIC delta-endotoxin, it was found to be insoluble under alkaline reducing conditions. These results show that CryIC from B. thuringiensis subsp. aizawai is a dually active delta-endotoxin.     

Development of Bacillus thuringiensis CryIC Resistance by Spodoptera exigua (Hubner) (Lepidoptera: Noctuidae)

Selection of resistance in Spodoptera exigua (Hubner) to an HD-1 spore-crystal mixture, CryIC (HD-133) inclusion bodies, and trypsinized toxin from Bacillus thuringiensis subsp. aizawai and B. thuringiensis subsp. entomocidus was attempted by using laboratory bioassays. No resistance to the HD-1 spore-crystal mixture could be achieved after 20 generations of selection. Significant levels of resistance (11-fold) to CryIC inclusion bodies expressed in Escherichia coli were observed after seven generations. Subsequent selection of the CryIC-resistant population with trypsinized CryIC toxin resulted, after 21 generations of CryIC selection, in a population of S. exigua that exhibited only 8% mortality at the highest toxin concentration tested (320 (mu)g/g), whereas the 50% lethal concentration was 4.30 (mu)g/g for the susceptible colony. Insects resistant to CryIC toxin from HD-133 also were resistant to trypsinized CryIA(b), CryIC from B. thuringiensis subsp. entomocidus, CryIE-CryIC fusion protein (G27), CryIH, and CryIIA. In vitro binding experiments with brush border membrane vesicles showed a twofold decrease in maximum CryIC binding, a fivefold difference in K(infd), and no difference in the concentration of binding sites for the CryIC-resistant insects compared with those for the susceptible insects. Resistance to CryIC was significantly reduced by the addition of HD-1 spores. Resistance to the CryIC toxin was still observed 12 generations after CryIC selection was removed. These results suggest that, in S. exigua, resistance to a single protein is more likely to occur than resistance to spore-crystal mixtures and that once resistance occurs, insects will be resistant to many other Cry proteins. These results have important implications for devising S. exigua resistance management strategies in the field.     

Resistance to Toxins from Bacillus thuringiensis subsp. kurstaki Causes Minimal Cross-Resistance to B. thuringiensis subsp. aizawai in the Diamondback Moth (Lepidoptera: Plutellidae)

Repeated exposure in the field followed by laboratory selection produced 1,800- to >6,800-fold resistance to formulations of Bacillus thuringiensis subsp. kurstaki in larvae of the diamondback moth, Plutella xylostella. Four toxins from B. thuringiensis subsp. kurstaki [CryIA(a), CryIA(b), CryIA(c), and CryIIA] caused significantly less mortality in resistant larvae than in susceptible larvae. Resistance to B. thuringiensis subsp. kurstaki formulations and toxins did not affect the response to CryIC toxin from B. thuringiensis subsp. aizawai. Larvae resistant to B. thuringiensis subsp. kurstaki showed threefold cross-resistance to formulations of B. thuringiensis subsp. aizawai containing CryIC and CryIA toxins. This minimal cross-resistance may be caused by resistance to CryIA toxins shared by B. thuringiensis subsp. kurstaki and B. thuringiensis subsp. aizawai.     

Enhanced production of insecticidal proteins in Bacillus thuringiensis strains carrying an additional crystal protein gene in their chromosomes.

A two-step procedure was used to place a cryIC crystal protein gene from Bacillus thuringiensis subsp. aizawai into the chromosomes of two B. thuringiensis subsp. kurstaki strains containing multiple crystal protein genes. The B. thuringiensis aizawai cryIC gene, which encodes an insecticidal protein highly specific to Spodoptera exigua (beet armyworm), has not been found in any B. thuringiensis subsp. kurstaki strains. The cryIC gene was cloned into an integration vector which contained a B. thuringiensis chromosomal fragment encoding a phosphatidylinositol-specific phospholipase C, allowing the B. thuringiensis subsp. aizawai cryIC to be targeted to the homologous region of the B. thuringiensis subsp. kurstaki chromosome. First, to minimize the possibility of homologous recombination between cryIC and the resident crystal protein genes, B. thuringiensis subsp. kurstaki HD73, which contained only one crystal gene, was chosen as a recipient and transformed by electroporation. Second, a generalized transducing bacteriophage, CP-51, was used to transfer the integrated cryIC gene from HD73 to two other B. thuringiensis subsp. kurstaki stains. The integrated cryIC gene was expressed at a significant level in all three host strains, and the expression of cryIC did not appear to reduce the expression of the endogenous crystal protein genes. Because of the newly acquired ability to produce the CryIC protein, the recombinant strains showed a higher level of activity against S. exigua than did the parent strains. This two-step procedure should therefore be generally useful for the introduction of an additional crystal protein gene into B. thuringiensis strains which have multiple crystal protein genes and which show a low level of transformation efficiency.     

Resistance to Bacillus thuringiensis by the Indian meal moth, Plodia interpunctella: comparison of midgut proteinases from susceptible and resistant larvae

Midgut homogenates from susceptible and resistant strains of the Indian meal moth, Plodia interpunctella, were compared for their ability to activate the entomocidal parasporal crystal protein from Bacillus thuringiensis. The properties of midgut proteinases from both types of larvae were also examined. Electrophoretic patterns of crystal protein from B. thuringiensis subspecies kurstaki (HD-1) and aizawai (HD-133 and HD-144) were virtually unchanged following digestion by either type of midgut homogenate. Changes in pH (9.5 to 11.5) or midgut homogenate concentration during digestion failed to substantially alter protein electrophoretic patterns of B. thuringiensis HD-1 crystal toxin. In vitro toxicity of crystal protein activated by either type of midgut preparation was equal toward cultured insect cells from either Manduca sexta or Choristoneura fumiferana. Electrophoresis of midgut extracts in polyacrylamide gels containing gelatin as substrate also yielded matching mobility patterns of proteinases from both types of midguts. Quantitation of midgut proteolytic activity using tritiated casein as a substrate revealed variation between midgut preparations, but no statistically significant differences between proteolytic activities from susceptible and resistant Indian meal moth larvae. Inhibition studies indicated that a trypsin-like proteinase with maximal activity at pH 10 is a major constituent of Indian meal moth midguts. The results demonstrated that midguts from susceptible and resistant strains of P. interpunctella are similar both in their ability to activate B. thuringiensis protoxin and in their proteolytic activity.     

The hypervariable region in the genes coding for entomopathogenic crystal proteins of Bacillus thuringiensis: nucleotide sequence of the kurhd1 gene of subsp. kurstaki HD1

One of the genes for the entomophatogenic crystal protein of Bacillus thuringiensis (subsp. kurstaki strain HD1) has been cloned in Escherichia coli, and its nucleotide sequence determined completely. The gene is contained within a 4360-bp-long HpaI-PstI DNA restriction fragment and codes for a polypeptide of 1,155 amino acid residues. The protoxin protein has a predicted Mr of 130,625. The E. coli-derived protoxin gene product is biologically active against Heliothis virescens larvae in a biotest assay. Extensive computer comparisons with other published B. thuringiensis subsp. kurstaki strains HD1, HD73, and B. thuringiensis subsp. sotto gene sequences reveal hypervariable regions in the first half of the protoxin coding sequence. These regions are responsible for the biological activity of the protein product of the cloned gene, and may explain the different biological activities of these different protoxins.     

Cloning and analysis of delta-endotoxin genes from Bacillus thuringiensis subsp. alesti.

Bacillus thuringiensis subsp. alesti produced only CryIA(b)-type protoxins, and three cryIA(b) genes were cloned. One was cryptic because of an alteration near the 5' end, and the other two were very similar to each other. The protoxin encoded by one of the latter genes differed from other CryIA(b) protoxins in its greater stability and relative toxicity for two members of the order Lepidoptera.     

Domain III substitution in Bacillus thuringiensis delta-endotoxin CryIA(b) results in superior toxicity for Spodoptera exigua and altered membrane protein recognition.

To test our hypothesis that substitution of domain III of Bacillus thuringiensis delta-endotoxin (Cry) proteins might improve toxicity to pest insects, e.g., Spodoptera exigua, in vivo recombination was used to produce a number of cryIA(b)-cryIC hybrid genes. A rapid screening assay was subsequently exploited to select hybrid genes encoding soluble protoxins. Screening of 120 recombinants yielded two different hybrid genes encoding soluble proteins with domains I and II of CryIA(b) and domain III of CryIC. These proteins differed by only one amino acid residue. Both hybrid protoxins gave a protease-resistant toxin upon in vitro activation by trypsin. Bioassays showed that one of these CryIA(b)-CryIC hybrid proteins (H04) was highly toxic to S. exigua compared with the parental CryIA(b) protein and significantly more toxic than CryIC. In semiquantitative binding studies with biotin-labelled toxins and intact brush border membrane vesicles of S. exigua, this domain III substitution appeared not to affect binding-site specificity. However, binding to a 200-kDa protein by CryIA(b) in preparations of solubilized and blotted brush border membrane vesicle proteins was completely abolished by the domain III substitution. A reciprocal hybrid containing domains I and II of CryIC and domain III of CryIA(b) did bind to the 200-kDa protein, confirming that domain III of CryIA(b) was essential for this reaction. These results show that domain III of CryIC protein plays an important role in the level of toxicity to S. exigua, that substitution of domain III may be a powerful tool to increase the repertoire of available active toxins for pest insects, and that domain III is involved in binding to gut epithelium membrane proteins of S. exigua.     

Toxicity to Spodoptera exigua and Trichoplusia ni of individual P1 protoxins and sporulated cultures of Bacillus thuringiensis subsp. kurstaki HD-1 and NRD-12

The toxicities to neonate Spodoptera exigua and Trichoplusia ni of lyophilized powders obtained from sporulated liquid cultures (referred to as sporulated cultures) and Escherichia coli-expressed P1 [cryIA(a) cryIA(b) cryIA(c)] protoxins from three-gene strains of NRD-12 and HD-1 of Bacillus thuringiensis subsp. kurstaki were determined by using diet incorporation bioassays. Although sporulated cultures from both strains were more toxic to T. ni than S. exigua, there were no differences in toxicity between NRD-12 and HD-1. Toxicities of the three individual P1 protoxins against S. exigua varied by at least fivefold, with the cryIA(b) protein being the most toxic. These same protoxins varied in toxicity against T. ni by at least 16-fold, with the cryIA(c) protein being the most toxic. However, when tested against either S. exigua or T. ni, there were no differences in toxicity between an NRD-12 P1 protoxin and the corresponding HD-1 P1 protoxin. Comparing the toxicities of individual protoxins with that of sporulated cultures demonstrates that no individual protoxin was as toxic to S. exigua as the sporulated cultures. However, this same comparison against T. ni shows that both the cryIA(b) and cryIA(c) proteins are at least as toxic as the sporulated cultures. Results from this study suggest that NRD-12 is not more toxic to S. exigua than HD-1, that different protein types have variable host activity, and that other B. thuringiensis components are not required for T. ni toxicity but that other components such as spores might be required for S. exigua toxicity.     

Toxicity to Spodoptera exigua and Trichoplusia ni of individual P1 protoxins and sporulated cultures of Bacillus thuringiensis subsp. kurstaki HD-1 and NRD-12.

The toxicities to neonate Spodoptera exigua and Trichoplusia ni of lyophilized powders obtained from sporulated liquid cultures (referred to as sporulated cultures) and Escherichia coli-expressed P1 [cryIA(a) cryIA(b) cryIA(c)] protoxins from three-gene strains of NRD-12 and HD-1 of Bacillus thuringiensis subsp. kurstaki were determined by using diet incorporation bioassays. Although sporulated cultures from both strains were more toxic to T. ni than S. exigua, there were no differences in toxicity between NRD-12 and HD-1. Toxicities of the three individual P1 protoxins against S. exigua varied by at least fivefold, with the cryIA(b) protein being the most toxic. These same protoxins varied in toxicity against T. ni by at least 16-fold, with the cryIA(c) protein being the most toxic. However, when tested against either S. exigua or T. ni, there were no differences in toxicity between an NRD-12 P1 protoxin and the corresponding HD-1 P1 protoxin. Comparing the toxicities of individual protoxins with that of sporulated cultures demonstrates that no individual protoxin was as toxic to S. exigua as the sporulated cultures. However, this same comparison against T. ni shows that both the cryIA(b) and cryIA(c) proteins are at least as toxic as the sporulated cultures. Results from this study suggest that NRD-12 is not more toxic to S. exigua than HD-1, that different protein types have variable host activity, and that other B. thuringiensis components are not required for T. ni toxicity but that other components such as spores might be required for S. exigua toxicity.     

Insecticidal properties of a crystal protein gene product isolated from Bacillus thuringiensis subsp. kenyae.

A protoxin gene, localized to a high-molecular-weight plasmid from Bacillus thuringiensis subsp. kenyae, was cloned on a 19-kb BamHI DNA fragment into Escherichia coli. Characterization of the gene revealed it to be a member of the CryIE toxin subclass which has been reported to be as toxic as the CryIC subclass to larvae from Spodoptera exigua in assays with crude E. coli extracts. To directly test the purified recombinant gene product, the gene was subcloned as a 4.8-kb fragment into an expression vector resulting in the overexpression of a 134-kDa protein in the form of phase-bright inclusions in E. coli. Treatment of solubilized inclusion bodies with either trypsin or gut juice from the silkworm Bombyx mori resulted in the appearance of a protease-resistant 65-kDa protein. In force-feeding bioassays, the purified activated protein was highly toxic to larvae of B. mori but not to larvae of Choristoneura fumiferana. In diet bioassays with larvae from S. exigua, the purified protoxin was nontoxic. However, prior activation of the protoxin by tryptic digestion resulted in the appearance of some toxic activity. These results demonstrate that this new subclass of protein toxin may not be useful for the control of Spodoptera species as previously reported. Hierarchical clustering of the nine known lepidopteran-specific CryI toxin subclasses through multiple sequence alignment suggests that the toxins fall into four possible subgroups or clusters.     

Cross-Resistance to Bacillus thuringiensis Toxin CryIF in the Diamondback Moth (Plutella xylostella)

Selection with Bacillus thuringiensis subsp. kurstaki, which contains CryIA and CryII toxins, caused a >200-fold cross-resistance to CryIF toxin from B. thuringiensis subsp. aizawai in the diamondback moth, Plutella xylostella. CryIE was not toxic, but CryIB was highly toxic to both selected and unselected larvae. The results show that extremely high levels of cross-resistance can be conferred across classes of CryI toxins of B. thuringiensis.     

Characterization and comparison of midgut proteases of Bacillus thuringiensis susceptible and resistant diamondback moth (Plutellidae: Lepidoptera)

The midgut proteases of the Bacillus thuringiensis resistant and susceptible populations of the diamondback moth, Plutella xylostella L. were characterized by using protease specific substrates and inhibitors. The midgut contained trypsin-like proteases of molecular weights of 97, 32, 29.5, 27.5, and 25 kDa. Of these five proteases, 29.5 kDa trypsin-like protease was the most predominant in activation of protoxins of Cry1Aa and Cry1Ab. The activation of Cry1Ab protoxin by midgut protease was fast (T(1/2) of 23-24 min) even at a protoxin:protease ratio of 250:1. The protoxin activation appeared to be multi-step process, and at least seven intermediates were observed before formation of a stable toxin of about 57.4 kDa from protoxin of about 133 kDa. Activation of Cry1Aa was faster than that of Cry1Ab on incubation of protoxins with midgut proteases and bovine trypsin. The protoxin and toxin forms of Cry proteins did not differ in toxicity towards larvae of P. xylostella. The differences in susceptibility of two populations to B. thuringiensis Cry1Ab were not due to midgut proteolytic activity. Further, the proteolytic patterns of Cry1A protoxins were similar in the resistant as well as susceptible populations of P. xylostella.     

Detection of chromosomally located and plasmid-borne genes on 20 kb DNA fragments in parasporal crystals from <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

The association of 20 kb heterologous DNA fragments with the parasporal crystals from native and recombinant Bacillus thuringiensis strains was analyzed, respectively. The cry2Aa10 gene cloned in plasmid pHC39 was transformed into B. thuringiensis subsp. kurstaki strains CryˉB and HD73, producing recombinant strains CryˉB(pHC39) and HD73(pHC39). SDS-PAGE and scanning electron microscopy analyses demonstrated that the recombinant CryˉB(pHC39) produced cuboidal crystals of Cry2Aa10 protoxin, while recombinant HD73(pHC39) produced both bipyramidal crystals of Cry1Ac1 protoxin and cuboidal crystals of Cry2Aa10 protoxin. Bioassay results proved that recombinant HD73(pHC39) showed higher insecticidal activity to Helicoverpa armigera than CryˉB(pHC39). It was found that 20 kb DNA fragments were present in bipyramidal and cuboidal crystals from both native and recombinant strains, and the 20 kb heterologous DNAs contained chromosome-specific and resident large plasmid-borne DNA fragments, suggesting the 20 kb heterologous DNA fragment embodied in crystals came randomly from the bacterial chromosomal and plasmid genome. This was the first investigation devoted exclusively on the origin of 20 kb DNA fragments in the parasporal crystals of B. thuringiensis. The data provides a basis for further investigation of the origin of 20 kb DNAs in the crystals and the interaction of DNA and protoxins.     

Altered binding of the Cry1Ac toxin to larval membranes but not to the toxin-binding protein in Plodia interpunctella selected for resistance to different Bacillus thuringiensis isolates.

Immunoblotting and cytochemical procedures were used to determine whether toxin binding was altered in strains of the Indianmeal moth, Plodia interpunctella, selected for resistance to various strains of Bacillus thuringiensis. Each of these B. thuringiensis subspecies produces a mixture of protoxins, primarily Cry1 types, and the greatest insect resistance is to the Cry1A protoxins. In several cases, however, there was also resistance to toxins not present in the B. thuringiensis strains used for selection. The Cry1Ab and Cry1Ac toxins bound equally well over a range of toxin concentrations and times of incubation to a single protein of ca. 80-kDa in immunoblots of larval membrane extracts from all of the colonies. This binding protein is essential for toxicity since a mutant Cry1Ac toxin known to be defective in binding and thus less toxic bound poorly to the 80-kDa protein. This binding protein differed in size from the major aminopeptidase N antigens implicated in toxin binding in other insects. Binding of fluorescently labeled Cry1Ac or Cry1Ab toxin to larval sections was found at the tips of the brush border membrane prepared from the susceptible but not from any of the resistant P. interpunctella. Accessibility of a major Cry1A-binding protein appears to be altered in resistant larvae and could account for their broad resistance to several B. thuringiensis toxins.