The Role of β20–β21 Loop Structure in Insecticidal Activity of Cry1Ac Toxin from <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

The β20–β21 loop is a unique structure in the domain III of Bacillus thuringiensis Cry proteins. In this study, the role of β20–β21 loop on insecticidal activity of Cry1Ac toxin was investigated. 10 residues in β20–β21 loop were substituted with alanine using PCR-based site-directed mutagenesis. All mutants were capable of producing diamond-shaped crystal and expressing a protein sized 130 kDa. The mutants S581A and I585A enhanced toxicity against Helicoverpa armigera larvae dramatically, while most of the rest mutants possess a reduced toxicity at different degrees. Indoor bioassay result revealed that mutants S581A and I585A had a 1.72- and 1.89-fold increasing in toxicity against Helicoverpa armigera larvae compared with the wild-type strain, respectively; On the contrary, G583A experienced a significant reduced insecticidal activity. Three-dimensional analysis of Cry1Ac5 protein demonstrated that the side chain of residues T579, S580, L582, and I585 extended to the surface of the protein, and might participate in the interaction between the protein and its receptor, whereas side chain of residues N576, F578, S581, N584, and V586 preferred the inside of the protein, and which might be critical to the stability of the protein structure. Our study for the first time clarified the special properties and the functions of the β20–β21 loop in domain III of Cry1Ac5. These findings also provided the latest biological evidence for the recognition and binding mechanism of the domain III in Cry1Ac, and its role in maintaining the structure stability of Cry1Ac.     

A Cry1Ac Toxin Variant Generated by Directed Evolution has Enhanced Toxicity against Lepidopteran Insects

Cry1Ac insecticidal crystal proteins produced by Bacillus thuringiensis (Bt) have become an important natural biological agent for the control of lepidopteran insects. In this study, a cry1Ac toxin gene from Bacillus thuringiensis 4.0718 was modified by using error-prone PCR, staggered extension process (StEP) shuffling combined with Red/ET homologous recombination to investigate the insecticidal activity of delta-endotoxin Cry1Ac. A Cry1Ac toxin variant (designated as T524N) screened by insect bioassay showed increased insecticidal activity against Spodoptera exigua larvae while its original insecticidal activity against Helicoverpa armigera larvae was still retained. The mutant toxin T524N had one amino acid substitution at position 524 relative to the original Cry1Ac toxin, and it can accumulate within the acrystalliferous strain Cry-B and form more but a little smaller bipyramidal crystals than the original Cry1Ac toxin. Analysis of theoretical molecular models of mutant and original Cry1Ac proteins indicated that the mutation T524N located in the loop linking β16–β17 of domain III in Cry1Ac toxin happens in the fourth conserved block which is an arginine-rich region to form a highly hydrophobic surface involving interaction with receptor molecules. This study showed for the first time that single mutation T524N played an essential role in the insecticidal activity. This finding provides the biological evidence of the structural function of domain III in insecticidal activity of the Cry1Ac toxin, which probably leads to a deep understanding between the interaction of toxic proteins and receptor macromolecules.     

N546 in β18-β19 loop is important for binding and toxicity of the Bacillus thuringiensis Cry1Ac toxin

Our previous mutagenic analysis showed that the unique residue N546 in the apex of β18-β19 loop of Bacillus thuringiensis Cry1Ac toxin is important for its toxicity. In this study, trypsin digestion susceptibility, binding to BBMV and oligomer formation activity was therefore analyzed to determine the mechanism of toxicity change of these mutant toxins. The results showed that residue N546 was not involved in toxin oligomerisation and maintaining the stability of toxin, the enhanced toxicity of mutant N546A was just because of increased binding to BBMV, and reduction in toxicity of other mutants were caused by reduction in initial or irreversible binding to BBMV. This is the first report that revealed N546 in Cry1Ac domain III played an essential role in its insecticidal activity and binding to insect BBMV.     

Specific mutations within the α4–α5 loop of the bacillus thuringiensis Cry4B toxin reveal a crucial role for Asn-166 and Tyr-170

The widely accepted model for toxicity mechanisms of the Bacillus thuringiensis Cry δ-endotoxins suggests that helices α4 and α5 form a helix-loop-helix hairpin structure to initiate membrane insertion and pore formation. In this report, alanine substitutions of two polar amino acids (Asn-166 and Tyr-170) and one charged residue (Glu-171) within the α4–α5 loop of the 130-kDa Cry4B mosquito-larvicidal protein were initially made via polymerase chain reaction-based directed mutagenesis. As with the wild-type toxin, all of the mutant proteins were highly expressed in Escherichia coli as inclusion bodies upon isopropyl-β-d-thiogalactopyranoside induction. When E. coli cells expressing each mutant toxin were assayed against Aedes aegypti mosquito larvae, the activity was almost completely abolished for N166A and Y170A mutations, whereas E171A showed only a small reduction in toxicity. Further analysis of these two critical residues by induction of specific mutations revealed that polarity at position 166 and highly conserved aromaticity at position 170 within the α4–α5 loop play a crucial role in the larvicidal activity of the Cry4B toxin.     

The mutation R(423)S in the Bacillus thuringiensis hybrid toxin CryAAC slightly increases toxicity for Mamestra brassicae L

Bacillus thuringiensis Cry1Ac toxin is 100 times less toxic than Cry1C to Mamestra brassicae. An R(423)S mutation abolishes Cry1Ac toxin proteolysis in M. brassicae gut juice but does not increase its toxicity to this insect. The CryAAC hybrid toxin (1Ac/1Ac/1Ca) is toxic to M. brassicae but is susceptible to gut protease digestion at the R(423) residue. Accordingly we have investigated the effect of the R(423)S mutation in CryAAC on its toxicity for M. brassicae and Pieris brassicae. Bioassays demonstrated that the R(423)S mutation slightly increased the toxicity of CryAAC for M. brassicae by having a significantly inhibitory effect on the growth of surviving larvae. The mutant hybrid was still highly toxic to P. brassicae. Features of CryAACR(423)S such as, (1) stability in M. brassicae gut juice and (2) crystal solubility were investigated. Computer simulations suggest that a possible major increase in flexibility in the CryAAC loop beta7/beta8 (G(391)-P(397)) caused by the R(423)S substitution could be a reason for the increase in M. brassicae toxicity.     

New Insight to Structure-Function Relationship of GalNAc Mediated Primary Interaction between Insecticidal Cry1Ac Toxin and HaALP Receptor of Helicoverpa armigera

Over the last few decades Cry1Ac toxin has been widely used in controlling the insect attack due to its high specificity towards target insects. The pore-forming toxin undergoes a complex mechanism in the insect midgut involving sequential interaction with specific glycosylated receptors in which terminal GalNAc molecule plays a vital role. Recent studies on Cry toxins interactions with specific receptors revealed the importance of several amino acid residues in domain III of Cry1Ac, namely Q509, N510, R511, Y513 and W545, serve as potential binding sites that surround the putative GalNAc binding pocket and mediate the toxin-receptor interaction. In the present study, alanine substitution mutations were generated in the Cry1Ac domain III region and functional significance of those key residues was monitored by insect bioassay on Helicoverpa armigera larvae. In addition, ligand blot analysis and SPR binding assay was performed to monitor the binding characteristics of Cry1Ac wild type and mutant toxins towards HaALP receptor isolated from Helicoverpa armigera. Mutagenesis data revealed that, alanine substitutions in R511, Y513 and W545 substantially impacted the relative affinity towards HaALP receptor and toxicity toward target insect. Furthermore, in silico study of GalNAc-mediated interaction also confirmed the important roles of these residues. This structural analysis will provide a detail insight for evaluating and engineering new generation Cry toxins to address the problem of change in insect behavioral patterns.     

The α-Helix 4 Residue, Asn135, Is Involved in the Oligomerization of Cry1Ac1 and Cry1Ab5 Bacillus thuringiensis Toxins

The insecticidal Cry toxins produced by the bacterium Bacillus thuringiensis are comprised of three structural domains. Domain I, a seven-helix bundle, is thought to penetrate the insect epithelial cell plasma membrane through a hairpin composed of α-helices 4 and 5, followed by the oligomerization of four hairpin monomers. The α-helix 4 has been proposed to line the lumen of the pore, whereas some residues in α-helix 5 have been shown to be responsible for oligomerization. Mutation of the Cry1Ac1 α-helix 4 amino acid Asn135 to Gln resulted in the loss of toxicity to Manduca sexta, yet binding was still observed. In this study, the equivalent mutation was made in the Cry1Ab5 toxin, and the properties of both wild-type and mutant toxin counterparts were analyzed. Both mutants appeared to bind to M. sexta membrane vesicles, but they were not able to form pores. The ability of both N135Q mutants to oligomerize was also disrupted, providing the first evidence that a residue in α-helix 4 can contribute to toxin oligomerization.     

<Emphasis Type="Italic">In vivo</Emphasis> fluorescence observation of parasporal inclusion formation in <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

A recombinant gene expressing a Cry1Ac-GFP fusion protein with a molecular mass of approximately 160 kD was constructed to investigate the expression of cry1Ac, the localization of its gene product Cry1Ac, and its role in crystal development in Bacillus thuringiensis. The cry1Ac-gfp fusion gene under the control of the cry1Ac promoter was cloned into the plasmid pHT304, and this construct was designated pHTcry1Ac-gfp. pHTcry1Ac-gfp was transformed into the crystal-negative strain, HD-73 cry⁻, and the resulting strain was named HD-73⁻(pHTcry1Ac-gfp). The gfp gene was then inserted into the large HD-73 endogenous plasmid pHT73 and fused with the 3′ terminal of the cry1Ac gene by homologous recombination, yielding HD-73Φ(cry1Ac-gfp)3534. Laser confocal microscopy and Western blot analyses showed for the first time that the Cry1Ac-GFP fusion proteins in both HD-73⁻(pHTcry1Ac-gfp) and HD-73Φ(cry1Ac-gfp)3534 were produced during asymmetric septum formation. Surprisingly, the Cry1Ac-GFP fusion protein showed polarity and was located near the septa in both strains. There was no significant difference between Cry1Ac-GFP and Cry1Ac in their toxicity to Plutella xylostella larvae.     

Synergistic activity between Bacillus thuringiensis Cry1Ab and Cry1Ac toxins against maize stem borer (Chilo partellus Swinhoe)

Aim: To select a toxin combination for the management of maize stem borer (Chilo partellus) and to understand possible mechanism of synergism among Bacillus thuringiensis Cry1A toxins tested. Methods and Results: Three Cry1A toxins were over expressed in Escherichia coli strain JM105 and used for diet overlay insect bioassay against C. partellus neonate larvae, both alone and in combinations. Probit analysis revealed that the three Cry1A toxins tested have synergistic effect against C. partellus larvae. In vitro binding analysis of fluorescein isothiocyanate (FITC)‐labelled Cry1A toxins to midgut brush border membrane vesicle (BBMV) shows that increase in toxicity is directly correlated to an increase in binding of toxin mix. Conclusions: A high Cry1Ac to Cry1Ab ratio leads to an increase in efficacy of these toxins towards C. partellus larvae and this increase in toxicity comes from an increase in toxin binding. Significance and Impact of the Study: Use of Cry1Ab and Cry1Ac combination could be an effective approach to control C. partellus. Furthermore, we show it first time that possible reason behind increase in toxicity of synergistic Cry1A proteins is an increase in toxin binding.     

Bacillus thuringiensisδ-Endotoxin Proteins Show a Correlation in Toxicity and Short Circuit Current Inhibition Against Helicoverpa zea

Pesticidal activity of Bacillus thuringiensisδ-endotoxins, Cry1Aa, Cry1Ab, Cry1Ac, and Cry2A, was determined by using the force-feeding bioassay method to 4^th instar larvae of Helicoverpa zea. H. zea was susceptible to Bt toxins in the order Cry1Ac > Cry1Ab > Cry1Aa > Cry2A with 63.60, 89.04, 159.65, and 375.78 ng/larvae respectively. The abilities of selected Bacillus thuringiensis toxins to inhibit short circuit current (I_SC) in midgut epithelia of H. zea were also investigated by voltage clamp assay. The voltage-clamp studies were conducted on isolated midguts, measuring the inhibition of short circuit current (I_SC) by activated toxin. A Cry1Aa toxin dilution of 33.3 and 500 ng/ml resulted in inhibition of I_SC of −2.29 μA/min (lag time 15 min) and −4.48 μA/min (lag time, 2 min) respectively. The Cry1Ab dilution of 25 ng/ml inhibited I_SC to −1.39 μA/min, a lag time of 14 min, and 333.3 ng/ml dilution resulted in decay of I_SC−2.49 μA/min, lag time 1 min respectively. The Cry1Ac lower dilution 16.7 ng/ml inhibited I_SC to −1.39 μA/min, lag time 4 min, and a high dilution 333.3 ng/ml decay I_SC to −2.44 μA/min, lag time 1 min. The inhibition of I_SC (−1.10 μA/min, lag time 25) at lower dilution (33.3 ng/ml) and high dilution (500 ng/ml), decay (−2.38 μA/min, lag time 5 min), showed a correlation between toxin concentration and inhibitory response with Cry2A toxin. The lag time decreased with increasing concentration of toxin applied, which is additional evidence of dose response besides direct correlation of toxicity assays and I_SC. Received: 7 April 2000 / Accepted: 2 May 2000     

Single amino acid mutations in the cadherin receptor from Heliothis virescens affect its toxin binding ability to Cry1A toxins

Bacillus thuringiensis Cry protein exerts its toxic effect through a receptor-mediated process. Both aminopeptidases and cadherin proteins were identified as putative Cry1A receptors from Heliothis virescens and Manduca sexta. The importance of cadherin was implied by its correlation with a Cry1Ac resistant H. virescens strain (Gahan, L. J., Gould, F., and Heckel, D. G. (2001) Science 293, 857-860). In this study, the Cry1Ac toxin-binding region in H. virescens cadherin was mapped to a 40-amino-acid fragment, from amino acids 1422 to 1440. This site overlaps with a Cry1Ab toxin-binding site, amino acids 1363-1464 recently reported in M. sexta (Hua, G., Jurat-Fuentes, J. L., and Adang, M. J. (2004) J. Biol. Chem. 279, 28051-28056). Further, feeding of the anti-H. virescens cadherin antiserum or the partial cadherins, which contain the toxin-binding region, in combination with Cry1Ab/Cry1Ac reduced insect mortality by 25.5-55.6% to first instar H. virescens and M. sexta larvae, suggesting a critical function for this cadherin domain in insect toxicity. Mutations in this region, to which the Cry1Ac binds through its loop 3, resulted in the loss of toxin binding. For the first time, we show that the cadherin amino acids Leu(1425) and Phe(1429) are critical for Cry1Ac toxin interaction, and if substituted with charged amino acids, result in the loss of toxin binding, with a K(D) of < 10(-5) m. Mutation of Gln(1430) to an alanine, however, increased the Cry1Ac affinity 10-fold primarily due to an increase on rate. The L1425R mutant can result from a single nucleotide mutation, CTG --> CGG, suggesting that these mutants, which have decreased toxin binding, may lead to Cry1A resistance in insects.     

Reduction of Bacillus thuringiensis Cry1Ac toxicity against Helicoverpa armigera by a soluble toxin-binding cadherin fragment

A cadherin-like protein has been identified as a putative receptor for Bacillus thuringiensis (Bt) Cry1Ac toxin in Helicoverpa armigera and plays a key role in Bt insecticidal action. In this study, we produced a fragment from this H. armigera Cry1Ac toxin-binding cadherin that included the predicted toxin-binding region. Binding of Cry1Ac toxin to this cadherin fragment facilitated the formation of a 250-kDa toxin oligomer. The cadherin fragment was evaluated for its effect on Cry1Ac toxin-binding and toxicity by ligand blotting, binding assays, and bioassays. The results of ligand blotting and binding assays revealed that the binding of Cry1Ac to H. armigera midgut epithelial cells was reduced under denaturing or native conditions in vitro. Bioassay results indicated that toxicities from Cry1Ac protoxin or activated toxin were reduced in vivo by the H. armigera cadherin fragment. The addition of the cadherin fragment had no effect on Cry2Ab toxicity.     

Helicoverpa armigera cadherin fragment enhances Cry1Ac insecticidal activity by facilitating toxin-oligomer formation

The interaction between Bacillus thuringiensis insecticidal crystal protein Cry1A and cadherin receptors in lepidopteran insects induces toxin oligomerization, which is essential for membrane insertion and mediates Cry1A toxicity. It has been reported that Manduca sexta cadherin fragment CR12-MPED and Anopheles gambiae cadherin fragment CR11-MPED enhance the insecticidal activity of Cry1Ab and Cry4Ba to certain lepidopteran and dipteran larvae species, respectively. This study reports that a Helicoverpa armigera cadherin fragment (HaCad1) containing its toxin binding region, expressed in Escherichia coli, enhanced Cry1Ac activity against H. armigera larvae. A binding assay showed that HaCad1 was able to bind to Cry1Ac in vitro and that this event did not block toxin binding to the brush border membrane microvilli prepared from H. armigera. When the residues ¹⁴²³GVLSLNFQ¹⁴³⁰ were deleted from the fragment, the subsequent mutation peptide lost its ability to bind Cry1Ac and the toxicity enhancement was also significantly reduced. Oligomerization tests showed that HaCad1 facilitates the formation of a 250-kDa oligomer of Cry1Ac-activated toxin in the midgut fluid environment. Oligomer formation was dependent upon the toxin binding to HaCad1, which was also necessary for the HaCad1-mediated enhancement effect. Our discovery reveals a novel strategy to enhance insecticidal activity or to overcome the resistance of insects to B. thuringiensis toxin-based biopesticides and transgenic crops.     

Degradation of the insecticidal toxin produced by Bacillus thuringiensis var. kurstaki by extracellular proteases produced by Chrysosporium sp

Aims: Some Cry proteins produced by the soil bacterium Bacillus thuringiensis (Bt) or by transgenic Bt plants persist in agricultural soils for an extended period of time, which may pose a hazard for nontarget soil organisms. The aims of our study were to screen for soil fungi capable of degrading the Cry1Ac toxin and to identify the mechanisms that lead to the inactivation of this protein. Methods and Results: Of the eight fungal strains screened, only one, Chrysosporium sp., was found to produce extracellular proteases capable of degrading the 66‐kDa Cry1Ac at the N‐terminal end of amino acid 125 (alanine). The proteolytic products of the Cry1Ac toxin did not exhibit any insecticidal activity against Helicoverpa armigera, in contrast to its high toxicity exhibited in the native form. Conclusions: Proteases elaborated by the Chrysosporium sp. degrade the Cry1Ac toxin in a way that it looses its insecticidal activity against H. armigera. Significance and Impact of the Study:  Chrysosporium sp., a specific soil micro‐organism capable of producing proteases that degrade the Cry1Ac toxin into inactive products under controlled conditions is being reported for the first time. Application of this observation needs to be further tested in field conditions.     

Preliminary comparing the toxicities of the hybrid cry1Acs fused with different heterogenous genes provided guidance for the fusion expression of Cry proteins

In order to provide guidance for selecting suitable heterogenous gene that can efficiently enhance toxicity or broaden insecticidal spectrum of Cry1Ac through fusion expression, two hybrid cry1Acs fused with chitinase-encoding gene tchiB and neurotoxin gene hwtx-1 respectively were constructed and their toxicities were compared. A Bacillus thuringiensis strain harboring the cry1Ac gene in vector pHT315 was used as control. Bioassay revealed that LC₅₀ (after 72 h) of Cry1Ac protoxin was 41.01 μg mL⁻¹, while the hybrid cry1Acs fused with tchiB and hwtx-1 were 4.89 and 23.14 μg mL⁻¹, which were 8.23- and 1.77-fold higher than Cry1Ac protoxin in terms of relative toxicity respectively. Both fusion crystals had a higher toxicity than the original Cry1Ac protein and the toxicity of hybrid cry1Acs fused with hwtx-1 experienced a more significant increase than that fused with tchiB.     

Increase in Insecticidal Toxicity by Fusion of the <Emphasis Type="Italic">cry1Ac</Emphasis> Gene from <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> with the Neurotoxin Gene <Emphasis Type="Italic">hwtx-I</Emphasis>

A fusion gene was constructed by combining the cry1Ac gene of Bacillus thuringiensis strain 4.0718 with a neurotoxin gene, hwtx-1, which was synthesized chemically. In this process, an enterokinase recognition site sequence was inserted in frame between two genes, and the fusion gene, including the promoter and the terminator of the cry1Ac gene, was cloned into the shuttle vector pHT304 to obtain a new expression vector, pXL43. A 138-kDa fusion protein was mass-expressed in the recombinant strain XL002, which was generated by transforming pXL43 into B. thuringiensis acrystalliferous strain XBU001. Quantitative analysis indicated that the expressed protein accounted for 61.38% of total cellular proteins. Under atomic force microscopy, there were some bipyramidal crystals with a size of 1.0 × 2.0 μm. Bioassay showed that the fusion crystals from recombinant strain XL002 had a higher toxicity than the original Cry1Ac crystal protein against third-instar larvae of Plutella xylostella, with an LC₅₀ (after 48 h) value of 5.12 μg/mL. The study will enhance the toxicity of B. thuringiensis Cry toxins and set the groundwork for constructing fusion genes of the B. thuringiensis cry gene and other foreign toxin genes and recombinant strains with high toxicity. LiQiu Xia and XiaoShan Long contributed equally to this work.     

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.     

Evidence of the Involvement of E358, A498 and C571 of a New Cry1Ac δ-endotoxin of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> in its High Insecticidal Activity Against <Emphasis Type="Italic">Ephestia kuehniella</Emphasis>

A new cry1Ac-type gene was cloned from Bacillus thuringiensis strain BLB1, sequenced and expressed. The deduced amino acid sequence of the polypeptide has a predicted molecular mass of 132.186 kDa. The amino acid sequence alignment of BLB1 Cry1Ac with those of the published ones showed that this is a new delta-endotoxin. When compared with Cry1Ac of Bacillus thuringiensis strain HD1, it was found that BLB1 Cry1Ac harbours three mutations: V358E localized in domain II and V498A and Y571C localized in domain III. When the BLB1 Cry1Ac toxin was expressed in an acrystalliferous strain of B. thuringiensis (HD1CryB), bipyramidal crystals were produced. The spore–crystal mixture of this recombinant strain was at least two-fold more active against larvae of the lepidopteran Ephestia kuehniella than that of the recombinant strain expressing Cry1Ac of HD1. The study of the structural effect of these mutations suggested that they may stabilize key regions involved in the binding of the domains II and III to insect receptors.     

Effects of Midgut-Protein-Preparative and Ligand Binding Procedures on the Toxin Binding Characteristics of BT-R1, a Common High-Affinity Receptor in Manduca sexta for Cry1A Bacillus thuringiensis Toxins

The identity of the physiologically important Cry1A receptor protein(s) in the lepidopteran Manduca sexta has been a matter of dispute due to the multiple proteins which bind the Cry1Ac toxin. Cry1Aa, Cry1Ab, and Cry1Ac exhibit essentially identical toxicities toward M. sexta larvae and show a high degree of sequence and presumed structural identities. These similarities make it likely that there is a common mechanism of toxicity in these lepidopteran-specific toxins in terms of both mode of action and the receptor proteins through which these toxins exert their lepidopteran-specific toxicity. Investigators in our laboratory previously demonstrated that the cloned 210-kDa glycoprotein BT-R₁ binds all three Cry1A toxins (T. P. Keeton and L. A. Bulla, Jr., Appl. Environ. Microbiol. 63:3419–3425, 1997). This protein remains a common binding protein even after being subjected to various midgut membrane preparation and processing protocols. The method used to isolate proteins from the M. sexta larval midgut in no significant way affects the results of ligand binding and vacuum blotting experiments, and we have been unable to detect specific, high-affinity binding of any Cry1A toxin to Cry1Ac binding proteins other than BT-R₁. Alterations in blot substrate and blocking, hybridization, and washing buffers support these conclusions. Collectively, these results indicate that in M. sexta the cadherin-like BT-R₁ protein is a common high-affinity receptor protein for the Cry1A family of toxins.     

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.