Subdomain organization ofBacillus thuringiensis entomocidal proteins'' N-terminal domains

N-Terminal domain (65 kD) of -endotoxin produced byBacillus thuringiensis ssp.alesti, as shown by limited proteolysis, consists of two subdomains of molecular mass 30 and 33 kD that correspond, respectively, to conservative and variable regions of the -endotoxin primary structure. Furthermore, proteolysis of these subdomains leads to their conversion into at least two fragments of molecular mass 10 kD stable to proteinase action. Such a pattern of molecular organization appears to be common for several structurally related -endotoxins that belong to thekurstaki group. Entomicidal protein produced by ssp.israelensis (70 kD), which differs strongly fromalesti and otherkurstaki group -endotoxins, retains a similar type of molecular organization and consists of two subdomains with molecular mass of 35 kD. Apparently, the characteristic pattern of the -endotoxins' molecular structure reflects separation of functions (e.g., host recognition and toxicityper se) between domains and subdomains of these proteins.     

Limited Proteolysis of Bacillus thuringiensis CryIG and CryIVB δ-Endotoxins Leads to Formation of Active Fragments That Do Not Coincide with the Structural Domains

Bacillus thuringiensis “true” toxins consist of three domains: the N-terminal, α-helical domain followed by two β-structural domains. Their limited proteolysis does not proceed at the domain boundaries, but is directed to the loops within the domains. There are at least two patterns of the limited proteolysis of “true” toxins. The first pattern, observed for CryIA and CryIVD δ-endotoxins, results in the proteolysis of the loops connecting β-strands of the second domain. The second pattern, detected for CryIG and CryIVB proteins, consists in the cleavage of the loop connecting the fifth and the sixth α-helixes of the first domain. The choice between the routes depends on the size, sequence, and dynamics of the loop that define its accessibility to a proteinase. Bioassay of CryIG and CryIVB δ-endotoxin fragments indicates that only two α-helixes, the sixth and the seventh within the first domain, followed by the two β-structural domains are sufficient for the insecticidal activity.     

Effects of Bacillus thuringiensis var. kurstaki δ-endotoxin on isolated lepidopteran mitochondria

An investigation was undertaken to determine the effects of Bacillus thuringiensis var. kurstaki δ-endotoxin on mitochondria isolated from Bombyx mori midgut epithelium. Using manometric and colorimetric techniques, the investigation revealed that toxic polypeptides had stimulatory effects on mitochondria oxygen uptake and inhibitory effects on ATP production. These results indicated that B. thuringiensis δ-endotoxin could act as an uncoupler of oxidative phosphorylation. Loss of ATP production caused by the action of the δ-endotoxin would lead to metabolic imbalance and possible cell death.     

Rapid Identification of δ-endotoxin from Bacillus thuringiensis subsp. kurstaki HD-1 with Proteomic Analysis

This study was carried out to identify rapidly δ-endotoxin from Bacillus thuringiensis (Bt) subsp. kurstaki HD-1 with proteomic analysis. Protoxin was isolated from sporulated cells and purified by ultracen-trifugation using 40-70% sucrose density gradient. Protoxin was treated with trypsin to analyze digested peptides by liquid chromatographytandem mass spectrometry. The proteomic analysis for detected peptides revealed that this methodology is available for discriminating similar Bt strains by identifying Bt subsp. kurstaki HD-1-specific peptides, suggesting that proteomic analysis can be used for rapid identification of Bt strains.     

Degradation of the parasporal crystal produced by Bacillus thuringiensis var. kurstaki

Degradation products of the parasporal crystals of Bacillus thuringiensis var. kurstaki obtained by treatment with alkali, gut juice from larvae of Bombyx mori, and various plant and mammalian enzymes were compared for elution pattern, approximate molecular weight (MW), and toxicity. The results indicated that with alkaline treatment the most toxic extract was obtained with 0.05–0.1 M NaOH. Toxicity was found associated mainly with a protein peak of 230,000 MW although other toxic peaks were found in the tailing. Heat-treated midgut juice from larval B. mori gave similar results. After digestion of parasporal crystals with clarified midgut juice, five peaks causing toxicity and having MW of approximately 235,000, 67,000, 30,200, 5000, and 1000, respectively, were identified. Treatment of B. thuringiensis δ-endotoxin with α-chymotrypsin gave peaks causing mortality of approximate MW 235,000, 34,000, 5000, and 1000. Trypsin, pronase, carboxypeptidase, and enterokinase digests of the B. thuringiensis δ-endotoxin gave toxic components ranging from 235,000 to 30,000 MW. The protein protoxin molecules are digested to give small toxic subunits that may be of practical value for structural determinations and for molecular mode of action studies.     

The crystal δ-endotoxins of Bacillus thuringiensis: Models for their mechanism of action on the insect gut

The crystal δ-endotoxins of Bacillus thuringiensis (Bt) are a family of insecticidal proteins which have been known for some time to kill insects by lysing their gut epithelial cells, but the precise molecular mechanism of toxicity has remained elusive. The recent publication of the crystal structure of a Bt δ-endotoxin has made it possible for us to model the molecular events that occur as the toxin binds to its receptor and inserts into the membrane to form a pore. Using our knowledge of insect gut physiology, we can also predict the effect on the insect of the formation of a toxic pore. We present a new model to explain the events that occur in the insect gut during toxin action.     

Isolation and characterization of a strain of Bacillus thuringiensis ssp. kurstaki containing a new delta-endotoxin gene

A strain of Bacillus thuringiensis that showed significantly high toxicity to Plutella xylostella and Spodoptera exigua was isolated from a Korean soil sample and characterized. The isolate, named B. thuringiensis K1, was determined to belong to ssp. kurstaki (H3a3b3c) type by an H antisera agglutination test and produced bipyramidal inclusions. Plasmid pattern of K1 was different from that of the reference strain, ssp. kurstaki HD-1, but the parasporal inclusion protein profile of K1 had two major bands that were similar in size to those of ssp. kurstaki HD-1. To verify the δ-endotoxin gene types of K1, PCR analysis with specific cry gene primers was performed to show that K1 contained a new cry gene in addition to cry1Aa, cry1Ab, cry1Ac, cry1E and cry2 genes. PCR-amplified region of the new cry gene, cryX, showed 79% similarity to cry1Fa1 gene (GenBank Accession No. M63897). In an insect toxicity assay, K1 had higher toxicity against Plutella xylostella and S. exigua than ssp. kurstaki HD-1. Received: 21 December 2001 / Accepted: 28 January 2002     

Asporogenous Bacillus thuringiensis Mutant Producing High Yields of δ-Endotoxin

An asporogenous Bacillus thuringiensis subsp. kurstaki strain IK mutant, strain 290-1, which produced high yields of δ-endotoxin, was obtained by ethyl methane sulfonate treatment of a spore suspension. The mutant strain produced about the same amount of δ-endotoxin as that produced by the parent strain, but 10¹⁰ to 10¹¹ cells did not form any detectable dormant spores.     

Interactions between the tobacco budworm,Heliothis virescens,and the δ-endotoxin produced by the HD-1 isolate of Bacillus thuringiensis var. kurstaki: Relationship between length of exposure to the toxin and survival

Larvae of the tobacco budworm, Heliothis virescens, which were fed ad libitum for 24, 48, and 72 hr on a diet treated with various levels of the δ-endotoxin produced by the HD-1 isolate of Bacillus thuringiensis var. kurstaki and then transferred to an untreated diet, showed an unexpected capacity to recover from the effects of the toxin, although, as the length of exposure increased, the capacity decreased. Observations on larvae held to emergence indicated that recovery from the toxin was complete. X-ray studies using Ba²⁺ incorporated into the diet showed that, although the toxin paralyzed the midgut of the treated animals, many animals recovered after the toxin was removed, with food once again passing through the gut.     

Dual production of amylase and δ-endotoxin by Bacillus thuringiensis subsp. kurstaki during biphasic fermentation

This study examined the efficacy of a Bacillus thuringiensis (Bt) strain in producing amylase (EC 3.2.1.1) as a by-product without affecting its unique ability for producing δ-endotoxin, thus to establish a cultivation strategy for the dual production and recovery of both δ-endotoxin and amylase from the fermented medium with an industrial perspective. LB medium was individually supplemented (5 to 100%, wt/vol) with flour from six naturally available starchy stored foods (banana, Bengal gram, jack seed, potato, taro or tapioca); after initial fermentation (12 h), the supernatant in the medium obtained by centrifugation (1000 g, 10 min) was used for harvesting amylase and the resultant pellet was further incubated aseptically for the production of endospores and δ-endotoxin by solid-state fermentation. Maximum crude amylase activity (867 U/gram dry substrate, 12 h) was observed in potato flour-supplemented medium (10% wt/vol, 12 h), while the activity in LB control was only 4.36 U/mL. SDS-PAGE profile of the crude (supernatant), as well as partially purified (40–60% (NH₄)₂SO₄ fractionation) amylase showed that its apparent molecular mass was 51 kDa, which was further confirmed by native PAGE. The harvest of industrially significant extracellular amylase (probably α-amylase) produced as a byproduct during early growth phase would boost the economics of the Bt-based bio-industry engaged in δ-endotoxin production.     

High-resolution crystal structure of activated Cyt2Ba monomer from Bacillus thuringiensis subsp. israelensis

The Cyt family of proteins consists of δ-endotoxins expressed during sporulation of several subspecies of Bacillus thuringiensis. Its members possess insecticidal, hemolytic, and cytolytic activities through pore formation and attract attention due to their potential use as vehicles for targeted membrane destruction. The δ-endotoxins of subsp. israelensis include three Cyt species: a major Cyt1Aa and two minor proteins, Cyt2Ba and Cyt1Ca. A cleaved Cyt protein that lacks the N- and C-terminal segments forms a toxic monomer. Here, we describe the crystal structure of Cyt2Ba, cleaved at its amino and carboxy termini by bacterial endogenous protease(s). Overall, its fold resembles that of the previously described volvatoxin A2 and the nontoxic form of Cyt2Aa. The structural similarity between these three proteins may provide information regarding the mechanism(s) of membrane-perforating toxins.     

Structural features of crystal-forming proteins produced by Bacillus thuringiensis subspecies israelensis

Entomocidal crystals produced by Bacillus thuringiensis ssp. israelensis are formed by two proteins with molecular masses of 130 and 28 kDa, whereas the protein with a molecular mass of 70 kDa appears as a result of 130 kDa protein limited proteolysis by admixtures of bacterial proteinases in the course of its dissolution. The comparison of the N-terminal sequences of the protein with molecular mass of 70 kDa (Met-Glu-Asn-Xaa-Pro-Leu-Asp-Thr-Leu-Ser-Ile-Val-Asn-Glu-Thr-Asp) and that of 28 kDa (Met-Glu-Asn-Leu-Asn-[Phe]-[Trp]-Pro-Leu-Gln-Asp-Ile-Lys-Val-Asn-Pro) reveals only marginal similarity between them (only 4 identical residues among 16 aligned). Both B. thuringiensis israelensis crystal-forming proteins appear hardly related to those contained in the crystal produced by other B. thuringiensis subspecies, e.g. kurstaki. It might be concluded that at least some of the entomocidal proteins found in the crystalline inclusion bodies of various B. thuringiensis subspecies revealed rather strong variations in their primary structures that facilitate their adaptation to different hosts.Bacillus thuringiensis ssp. israelensis δ-EndotoxinEntomocidal crystalInsecticideMosquito     

Binding of Bacillus thuringiensis Cry1A toxins with brush border membrane vesicles of maize stem borer (Chilo partellus Swinhoe)

Maize stem borer (Chilo partellus) is a major insect pest of maize and sorghum in Asia and Africa. Bacillus thuringiensis (Bt) δ-endotoxins have been found effective against C. partellus, both in diet-overlay assay and in transgenic plants. Gene stacking as one of the resistance management strategies in Bt maize requires an understanding of receptor sharing and binding affinity of δ-endotoxins. In the present study, binding affinity of three fluorescein isothiocyanate labeled Cry1A toxins showed high correlation with the toxicity of respective δ-endotoxins. Competitive binding studies showed that Cry1Ab toxins share some of the binding sites with Cry1Aa and Cry1Ac with low affinity and that Cry1Ab may have additional binding sites that are unavailable to the other two toxins tested.     

Physical Mapping of the Bacillus thuringiensis subsp. kurstaki and alesti Chromosomes

Two strains of the well-known insect pathogen and biopesticide, Bacillus thuringiensis (Bt), belonging to subspecies alesti (strain Bt5) and kurstaki (strain Bt213), were chosen for genetic characterization. The two strains belong to different serotypes and are currently classified into different subspecies, although their insecticidal activity is similar. Physical maps were constructed of Bt alesti and Bt kurstaki using Pulsed Field Gel Electrophoreses (PFGE), and the map positions of several genes were determined. The 5.5 Mb combined genetic and physical chromosome maps of the two strains were found to be indistinguishable, and the only differences detected between the strains were of extrachromosomal origin. A cryIA toxin gene probe hybridised to a chromosome fragment and to two extrachromosomal elements in both strains, migrating as 100 kb and 350 kb, respectively. In addition a cry hybridizing extrachromosomal element migrating as 80 kb was present only in Bt alesti. Both strains were also found to contain sequences hybridizing to an enterotoxin (hbla) gene probe. Such sequences were positioned on the 350 kb extrachromosomal element, as well as on the chromosome. Received: 20 April 2001 / Accepted: 29 May 2001     

Transgenic organisms expressing genes from Bacillus thuringiensis to combat insect pests

Various subspecies (ssp.) of Bacillus thuringiensis (Bt) are considered the best agents known so far to control insects, being highly specific and safe, easily mass produced and with long shelf life.1 The para-crystalline body that is produced during sporulation in the exosporium includes polypeptides named δ-endotoxins, each killing a specific set of insects. The different entomopathogenic toxins of various Bt ssp. can be manipulated genetically in an educated way to construct more efficient transgenic bacteria or plants that express combinations of toxin genes to control pests.2 Joint research projects in our respective laboratories during the last decade demonstrate what can be done by implementing certain ideas using molecular biology with Bt ssp. israelensis (Bti) as a model system. Here, we describe our progress achieved with Gram-negative bacterial species, including cyanobacteria, and some preliminary experiments to form transgenic plants, mainly to control mosquitoes (Diptera), but also a particular Lepidopteran and Coleopteran pest species. In addition, a system is described by which environment-damaging genes can be removed from the recombinants thus alleviating procedures for obtaining permits to release them in nature.     

Role of Proteolysis in Determining Potency of Bacillus thuringiensis Cry1Ac δ-Endotoxin

Bacillus thuringiensis protein δ-endotoxins are toxic to a variety of different insect species. Larvicidal potency depends on the completion of a number of steps in the mode of action of the toxin. Here, we investigated the role of proteolytic processing in determining the potency of the B. thuringiensis Cry1Ac δ-endotoxin towards Pieris brassicae (family: Pieridae) and Mamestra brassicae (family: Noctuidae). In bioassays, Cry1Ac was over 2,000 times more active against P. brassicae than against M. brassicae larvae. Using gut juice purified from both insects, we processed Cry1Ac to soluble forms that had the same N terminus and the same apparent molecular weight. However, extended proteolysis of Cry1Ac in vitro with proteases from both insects resulted in the formation of an insoluble aggregate. With proteases from P. brassicae, the Cry1Ac-susceptible insect, Cry1Ac was processed to an insoluble product with a molecular mass of ~56 kDa, whereas proteases from M. brassicae, the non-susceptible insect, generated products with molecular masses of ~58, ~40, and ~20 kDa. N-terminal sequencing of the insoluble products revealed that both insects cleaved Cry1Ac within domain I, but M. brassicae proteases also cleaved the toxin at Arg423 in domain II. A similar pattern of processing was observed in vivo. When Arg423 was replaced with Gln or Ser, the resulting mutant toxins resisted degradation by M. brassicae proteases. However, this mutation had little effect on toxicity to M. brassicae. Differential processing of membrane-bound Cry1Ac was also observed in qualitative binding experiments performed with brush border membrane vesicles from the two insects and in midguts isolated from toxin-treated insects.     

Formation of Crystalline δ-Endotoxin or Poly-β-Hydroxybutyric Acid Granules by Asporogenous Mutants of Bacillus thuringiensis

Parental strains and asporogenous mutants of Bacillus thuringiensis subspp. kurstaki and aizawai produced high yields of δ-endotoxin on M medium, which contained 330 μg of potassium per ml, but not on ST and ST-a media, each of which contained only 11 μg of potassium per ml. On ST and ST-a media, refractile granules were formed instead. These granules had no insecticidal activity against silkworms and were isolated and identified as poly-β-hydroxybutyric acid. Supplementation of the potassium-deficient ST-a medium with 0.1% KH₂PO₄ (3.7 mM) led to the formation of crystalline δ-endotoxin. The replacement of KH₂PO₄ with equimolar amounts of KCl, KNO₃, and potassium acetate or an equivalent amount of K₂SO₄ had a similar effect, whereas the addition of an equimolar amount of NaH₂PO₄ or NH₄H₂PO₄ did not cause the endotoxin to form. An asporogenous mutant, B. thuringiensis subsp. kurstaki strain 290-1, produced δ-endotoxin on ST-a medium supplemented with 3 mM or more potassium but formed only poly-β-hydroxybutyric acid granules on the media containing ≤1 mM potassium. These results clearly indicate that a certain concentration of potassium is essential for the fermentative production of δ-endotoxin by these isolates of B. thuringiensis. Manganese could not be substituted for potassium. Phosphate ions stimulated poly-β-hydroxybutyric acid formation by strain 290-1. The sporulation of B. thuringiensis and several other Bacillus strains was suppressed on the potassium-deficient ST medium. This suggests that potassium plays an essential role not only in Bacillus cell growth and δ-endotoxin formation but also in sporulation.     

Study of the irreversible binding of Bacillus thuringiensis Cry1Aa to brush border membrane vesicles from Bombyx mori midgut

The binding of Bacillus thuringiensis δ-endotoxin to brush border membrane vesicles (BBMVs) from the target insect larval midgut comprises with not only a reversible but also an irreversible component. The irreversible binding of δ-endotoxin is thought to be a pathologically important factor. Here, we studied the irreversible binding of Cry1Aa to the BBMVs of Bombyx mori. The ¹²⁵I-labeled Cry1Aa bound to the solubilized brush border membrane (BBM) through rapid dissociation only, unlike the binding to BBMVs, indicating that the toxin bound to the solubilized BBM through only a reversible process. Low-temperature sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis revealed that the toxin bound irreversibly to BBMVs formed an oligomer of 220 kDa, whereas that bound reversibly to the solubilized BBM did not oligomeraize. When the ¹²⁵I-labeled Cry1Aa bound irreversibly to the BBMVs was digested by proteinase K, approximately 40% of the toxin observed to be resistant to proteinase K. The molecular mass of the toxin resistant to proteinase K was 60 kDa, suggesting that the irreversible binding comprise two forms. These results support the notion that the irreversible binding of the toxin to BBMVs is due to the insertion of the toxin into the lipid bilayers and oligomerization to form channels.     

Semi-solid state fermentation of food waste for production of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> biopesticide

In this study, Bacillus thuringiensis (Bt) biopesticide was produced through different fermentation processes using food waste with different water contents. The semi-solid state sample with 75% water content presented the highest δ-endotoxin efficiency of 862 μg/mL. δ-endotoxin efficiency increased by 30.2% from that of the solid-state sample (50% water content) and 73.8% from that of the submerged sample (99% water content). Results confirmed that semi-solid state fermentation presents considerable advantages compared with other fermentation types (solid-state and submerged). The timing adjustment of pH and recycling fermentation effectively counteracted the inhibition of pH and product, thereby increasing δ- endotoxin efficiency to 1,648 and 2,478 μg/mL (accumulated value of all four fermentation loops), respectively. A δ- endotoxin slow-release formulation using polylactic acid as the carrier was also developed to effectively promote the stability of Bt biopesticide.     

Computational Modeling Deduced Three Dimensional Structure of Cry1Ab16 Toxin from Bacillus thuringiensis AC11

The first theoretical structural model of newly reported Cry1Ab16 δ-endotoxin produced by Bacillus thuringiensis AC11 was predicted using homology modeling technique. Cry1Ab16 resembles the Cry1Aa protein structure by sharing a common three domains structure responsible in pore forming and specificity determination along with few structural deviations. The main differences between the two is in the length of loops, absence of α7b, α9a, α10b, α11a and presence of additional β12b, α13 components while α10a is spatially located at downstream position in Cry1Ab16. A better understanding of the 3D structure shall be helpful in the design of domain swapping and mutagenesis experiments aimed at improving toxicity.