Binding of Insecticidal Crystal Proteins of Bacillus thuringiensis to the Midgut Brush Border of the Cabbage Looper, Trichoplusia ni (Hübner) (Lepidoptera: Noctuidae), and Selection for Resistance to One of the Crystal Proteins

The susceptibility of Trichoplusia ni larvae to several Bacillus thuringiensis insecticidal crystal proteins (ICPs) was tested. Neonatal larvae proved to be susceptible to solubilized trypsin-treated CryIA(a), CryIA(b), and CryIA(c) (50% lethal concentrations [LC(50)s], 570, 480, and 320 ng/cm, respectively) but showed little susceptibility to CryIB and CryID (LC(50)s, 5,640 and 2,530 ng/cm, respectively). The toxicity of ICPs was correlated to binding to the epithelial brush border of the midgut, as revealed by immunocytochemical staining with monoclonal antibodies. In vitro binding experiments with iodinated ICPs and brush border membrane vesicles indicated that CryIA(b) and CryIA(c) share the same high-affinity binding site, whereas CryIA(a) binds to a different one. The affinities of CryIA(b) and CryIA(c) for the binding site were similar (K(d) = 3.6 and 4.7 nM, respectively), and the mean binding-site concentration was 0.71 pmol/mg of vesicle protein. Selection of a population with increasing concentrations of CryIA(b) produced 31-fold resistance in seven generations. The realized heritability (h) was 0.19. The increase of homozygosity (for resistance factors) as selection proceeded was reflected in the increase in the slopes of the dose-mortality curves. Resistance was specific for CryIA(b) and did not extend to CryIA(a) or even to CryIA(c). This result was not predicted by the binding-site model, in which CryIA(b) and CryIA(c) bind to the same high-affinity binding site. This result may suggest a more complicated relationship between in vitro binding of ICPs to specific sites in the epithelial membrane of the midgut and the in vivo toxic effect.     

Two Different Bacillus thuringiensis Delta-Endotoxin Receptors in the Midgut Brush Border Membrane of the European Corn Borer, Ostrinia nubilalis (Hübner) (Lepidoptera: Pyralidae)

Binding of three Bacillus thuringiensis insecticidal crystal proteins (ICPs) to the midgut epithelium of Ostrinia nubilalis larvae was characterized by performing binding experiments with both isolated brush border membrane vesicles and gut tissue sections. Our results demonstrate that two independent ICP receptors are present in the brush border of O. nubilalis gut epithelium. From competition binding experiments performed with ¹²⁵I-labeled and native ICPs it was concluded that CryIA(b) and CryIA(c) are recognized by the same receptor. An 11-fold-higher binding affinity of CryIA(b) for this receptor correlated with a 10-fold-higher toxicity of this ICP compared with CryIA(c). The CryIB toxin did not compete for the binding site of CryIA(b) and CryIA(c). Immunological detection of ingested B. thuringiensis ICPs on gut sections of O. nubilalis larvae revealed binding only along the epithelial brush border membrane. CryID and CryIE, two ICPs that are not toxic to O. nubilalis, were not bound to the apical microvilli of gut epithelial cells. In vitro binding experiments performed with native and biotinylated ICPs on tissue sections confirmed the correlation between ICP binding and toxicity. Moreover, by performing heterologous competition experiments with biotinylated and native ICPs, it was confirmed that the CryIB receptor is different from the receptor for CryIA(b) and CryIA(c). Retention of activated crystal proteins by the peritrophic membrane was not correlated with toxicity. Furthermore, it was demonstrated that CryIA(b), CryIA(c), and CryIB toxins interact in vitro with the epithelial microvilli of Malpighian tubules. In addition, CryIA(c) toxin also adheres to the basement membrane of the midgut epithelium.     

Biotinylation of Bacillus thuringiensis Insecticidal Crystal Proteins

Biotinylation of Bacillus thuringiensis insecticidal crystal proteins (ICPs) was evaluated for its potential use in an alternative ICP screening method and in the characterization of ICP receptors. In vivo biological activity of CryIA(b), as inferred from bioassays with Manduca sexta and Ostrinia nubilalis and from histopathological effects on O. nubilalis midgut cells induced by force feeding, was not affected by biotinylation at moderate biotinylation ratios. A competitive radioreceptor assay showed that there was only a minor reduction in binding affinity of biotin-labeled CryIA(b) for M. sexta brush border membrane vesicles. On midgut tissue sections, the binding pattern along the midgut epithelium and the staining intensity of biotinylated ICPs detected with streptavidin-enzyme conjugate were virtually identical to the binding pattern and staining intensity of native CryIA(b) detected with antibodies. The specificity of biotinylated ICP binding to larval midgut tissue was demonstrated by performing homologous competition experiments. The relationship between different ICP receptor types in Plutella xylostella, as inferred from radioligand binding studies, was confirmed by the results of heterologous competition experiments performed with biotinylated and native ICPs.     

Two Different Bacillus thuringiensis Delta-Endotoxin Receptors in the Midgut Brush Border Membrane of the European Corn Borer, Ostrinia nubilalis (Hübner) (Lepidoptera: Pyralidae)

Binding of three Bacillus thuringiensis insecticidal crystal proteins (ICPs) to the midgut epithelium of Ostrinia nubilalis larvae was characterized by performing binding experiments with both isolated brush border membrane vesicles and gut tissue sections. Our results demonstrate that two independent ICP receptors are present in the brush border of O. nubilalis gut epithelium. From competition binding experiments performed with I-labeled and native ICPs it was concluded that CryIA(b) and CryIA(c) are recognized by the same receptor. An 11-fold-higher binding affinity of CryIA(b) for this receptor correlated with a 10-fold-higher toxicity of this ICP compared with CryIA(c). The CryIB toxin did not compete for the binding site of CryIA(b) and CryIA(c). Immunological detection of ingested B. thuringiensis ICPs on gut sections of O. nubilalis larvae revealed binding only along the epithelial brush border membrane. CryID and CryIE, two ICPs that are not toxic to O. nubilalis, were not bound to the apical microvilli of gut epithelial cells. In vitro binding experiments performed with native and biotinylated ICPs on tissue sections confirmed the correlation between ICP binding and toxicity. Moreover, by performing heterologous competition experiments with biotinylated and native ICPs, it was confirmed that the CryIB receptor is different from the receptor for CryIA(b) and CryIA(c). Retention of activated crystal proteins by the peritrophic membrane was not correlated with toxicity. Furthermore, it was demonstrated that CryIA(b), CryIA(c), and CryIB toxins interact in vitro with the epithelial microvilli of Malpighian tubules. In addition, CryIA(c) toxin also adheres to the basement membrane of the midgut epithelium.     

Occurrence of three different binding sites for Bacillus thuringiensis δ-endotoxins in the midgut brush border membrane of the potato tuber moth,phthorimaea operculella (zeller)

The potato tuber moth is susceptible to at least three insecticidal crystal proteins (ICPs) from Bacillus thuringiensis: CrylA(b), CrylB, and CrylC. To design useful combinations of toxin genes either in transgenic plants or in new genetically modified B. thuringiensis strains, it is necessary to determine the binding characteristics of the different ICPs so as not to combine a pair sharing the same binding site. This has been accomplished using two different techniques: ¹²⁵I-labeling of the ICPs with further measurement of the radioactivity bound to brush border membrane vesicles, and microscopic visualization of the bound ICPs by enzyme-linked reagents such as antibodies or streptavidin using biotinylated ICPs. Our results show that CrylA(b), CrylB, and CrylC bind to different sites in the brush border membrane of midgut epithelial cells. Also, the affinity of the binding sites for the ICPs and their concentration in brush border membrane vesicles has been determined in a laboratory strain and a storage collected population. No significant differences were found between these two strains. © 1994 Wiley-Liss, Inc.     

Changes in Permeability of Brush Border Membrane Vesicles from Spodoptera littoralis Midgut Induced by Insecticidal Crystal Proteins from Bacillus thuringiensis

Bacillus thuringiensis insecticidal crystal proteins (ICPs) are thought to induce pore formation in midgut cell membranes of susceptible insects. Cry1Ca, which is significantly active in Spodoptera littoralis, made brush border membrane vesicles permeable to KCl (osmotic swelling was monitored by the light scattering technique); the marginally active ICPs Cry1Aa, Cry1Ab, and Cry1Ac did not.     

Mode of action of CryIIA: a Bacillus thuringiensis delta-endotoxin

CryIIA is an effective insecticidal delta-endotoxin produced by several strains of Bacillus thuringiensis. Unlike CryI and CryIIIA-toxins that demonstrate some degree of saturable binding on the brush border of susceptible insects, neither saturable binding nor a saturable binding component was found for CryIIA on the midgut brush border of Helicoverpa zea. CryIIA did not dilute and block CryIA(c) binding, however, CryIA(c) effectively diluted CryIIA and stopped the initial binding of CryIIA to the brush border. These observations suggest that CryIIA and CryIA(c) toxins share a common component for binding on the midgut brush border. CryIIA formed voltage-dependent and not highly cation-selective channels in planar lipid bilayers unlike CryIA(c) and CryIIIA. Both CryIA(c) and CryIIA were stable in the digestive fluids of H. zea, but CryIIA was significantly less soluble than CryIA(c). Despite this difference in solubility, CryIIA arrested the feeding of third instar H. zea as rapidly as did CryIA(c), however, the onset of acute morbidity was delayed for CryIIA. Differences in solubility, binding, and ion channels formed by CryIIA toxin, resulted in reduced bioactivity against H. zea when compared with CryIA(c) but represent a unique mode of action among the delta endotoxins.     

Specificity of Activated CryIA Proteins from Bacillus thuringiensis subsp. kurstaki HD-1 for Defoliating Forest Lepidoptera

The insecticidal activity of the CryIA(a), CryIA(b), and CryIA(c) toxins from Bacillus thuringiensis subsp. kurstaki HD-1 was determined in force-feeding experiments with larvae of Choristoneura fumiferana, C. occidentalis, C. pinus, Lymantria dispar, Orgyia leucostigma, Malacosoma disstria, and Actebia fennica. The toxins were obtained from cloned protoxin genes expressed in Escherichia coli. The protoxins were activated with gut juice from Bombyx mori larvae. Biological activity of the individual gene products as well as the native HD-1 toxin was assessed as the dose which prevented 50% of the insects from producing frass within 3 days (frass failure dose [FFD₅₀]). The three toxins were about equally active against M. disstria. In the Choristoneura species, CryIA(a) and CryIA(b) were up to fivefold more toxic than CryIA(c). In the lymantriid species, CryIA(a) and CryIA(b) were up to 100-fold more toxic than CryIA(c). The toxicity of HD-1 was similar to that of the individual CryIA(a) or CryIA(b) toxins in all of these species. None of the CryIA toxins or HD-1 exhibited and toxicity towards A. fennica. Comparison of the observed FFD₅₀ of HD-1 with the FFD₅₀ expected on the basis of its crystal composition suggested a possible synergistic effect of the toxins in the two lymantriid species. Our results further illustrate the diversity of activity spectra of these highly related proteins and provide a data base for studies with forest insects to elucidate the molecular basis of toxin specificity.     

Receptors on the brush border membrane of the insect midgut as determinants of the specificity of Bacillus thuringiensis delta-endotoxins.

To investigate the biochemical basis of the differences in the insecticidal spectrum of Bacillus thuringiensis insecticidal crystal proteins (ICPs), we performed membrane binding and toxicity assays with three different ICPs and three lepidopteran species. The three ICPs have different toxicity patterns in the three selected target species. Binding studies with these 125I-labeled ICPs revealed high-affinity saturable binding to brush border membrane vesicles of the sensitive species. ICPs with no toxicity against a given species did not bind saturably to vesicles of that species. Together with previous data that showed a correlation between toxicity and ICP binding, our data support the statement that differences in midgut ICP receptors are a major determinant of differences in the insecticidal spectrum of the entire lepidopteran-specific ICP family. Receptor site heterogeneity in the insect midgut occurs frequently and results in sensitivity to more than one type of ICP.     

Receptors on the brush border membrane of the insect midgut as determinants of the specificity of Bacillus thuringiensis delta-endotoxins

To investigate the biochemical basis of the differences in the insecticidal spectrum of Bacillus thuringiensis insecticidal crystal proteins (ICPs), we performed membrane binding and toxicity assays with three different ICPs and three lepidopteran species. The three ICPs have different toxicity patterns in the three selected target species. Binding studies with these 125I-labeled ICPs revealed high-affinity saturable binding to brush border membrane vesicles of the sensitive species. ICPs with no toxicity against a given species did not bind saturably to vesicles of that species. Together with previous data that showed a correlation between toxicity and ICP binding, our data support the statement that differences in midgut ICP receptors are a major determinant of differences in the insecticidal spectrum of the entire lepidopteran-specific ICP family. Receptor site heterogeneity in the insect midgut occurs frequently and results in sensitivity to more than one type of ICP.     

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.     

Identification and characterization of Heliothis virescens midgut membrane proteins binding Bacillus thuringiensis delta-endotoxins.

To investigate the specificity of Bacillus thuringiensis var. kurstaki strain HD1 insecticidal crystal proteins (ICP), we used membrane preparations obtained from the midgut of Heliothis virescens larvae to perform separate ligand-blot experiments with the three activated CryIA toxins. The CryIA(a) and the CryIA(b) toxins bind the same 170-kDa protein, but most likely at two different binding sites. The CryIA(c) toxin binds two proteins of molecular masses 140 kDa and 120 kDa. We also demonstrate that the binding proteins for each of the B. thuringiensis toxins are not part of a covalent complex. Although the 170-kDa protein is a glycoprotein, endoglycosidase treatment does not prevent the binding of the CryIA(a) or CryIA(b) toxin. This indicates that the sugars are not important for the binding of these toxins. A model for a protein complex binding the B. thuringiensis HD1 ICPs is presented. Our results support the idea that binding proteins on membranes of the gut epithelial cells of H. virescens larvea are important for the specificity of the bacterial toxins.     

Location of a Bombyx mori receptor binding region on a Bacillus thuringiensis delta-endotoxin.

Receptor binding studies were performed with 125I-labeled trypsin-activated insecticidal toxins, CryIA(a) and CryIA(c), from Bacillus thuringiensis on brush-border membrane vesicles (BBMV) prepared from Bombyx mori larval midgut. Bioassays were performed by gently force feeding B. mori with diluted toxins. CryIA(a) toxin (LD50; 0.002 micrograms) was 200 times more active against B. mori larvae than CryIA(c) toxin (LD50; 0.421 micrograms) and showed high-affinity saturable binding. The Kd and the binding site concentration for CryIA(a) toxin were 3.5 nM and 7.95 pmol/mg, respectively. CryIA(c) toxin (Kd, 50.35 nM; Bmax, 2.85 pmol/mg) did not demonstrate high-affinity binding to B. mori BBMV. Control experiments with CryIA(a) and CryIA(c) toxins revealed no binding to mouse small intestine BBMV and nonspecific binding to pig kidney BBMV. These data provide evidence that binding to a specific receptor on the membrane of midgut epithelial cells is an important determinant with respect to differences in insecticidal spectrum of insecticidal crystal proteins. To locate a B. mori receptor binding region on the CryIA(a) toxin, homologous and heterologous competition binding studies were performed with a set of mutant proteins which had previously been used to define the B. mori "specificity domain" on this toxin (Ge, A. Z., Shivarova, N. I., and Dean, D. H. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 4037-4041). These mutant proteins have had regions of their genes reciprocally exchanged with the cryIA(c) gene. A B. mori receptor binding region on CryIA(a) toxin includes the amino-terminal portion of the hypervariable region, amino acids 332-450, which is identical to the previously described B. mori specificity determining region. These data provide direct evidence that delta-endotoxins contain a tract of amino acids that comprise a binding region and as a results determines the specificity of a toxin.     

Comparison of toxin overlay and solid-phase binding assays to identify diverse CryIA(c) toxin-binding proteins in Heliothis virescens midgut.

The binding proteins, or receptors, for insecticidal Bacillus thuringiensis subsp. kurstaki delta-endotoxins are located in the brush border membranes of susceptible insect midguts. The interaction of one of these toxins, CryIA(c), with proteins isolated from Heliothis virescens larval midguts was investigated. To facilitate the identification of solubilized putative toxin-binding proteins, a solid-phase binding assay was developed and compared with toxin overlay assays. The overlay assays demonstrated that a number of proteins of 170, 140, 120, 90, 75, 60, and 50 kDa bound the radiolabeled CryIA(c) toxin. Anion-exchange fractionation allowed the separation of these proteins into three toxin binding fractions, or pools. Toxin overlay assays demonstrated that although the three pools had distinct protein profiles, similar-size proteins could be detected in these three pools. However, determination of toxin affinity by using the solid-phase binding assay showed that only one of the three pools contained high-affinity binding proteins. The Kd obtained, 0.65 nM, is similar to that of the unsolubilized brush border membrane vesicles. Thus, the solid-phase binding assay in combination with the toxin overlay assay facilitates the identification and purification of high-affinity B. thuringiensis toxin-binding proteins from the insect midgut.     

Specific Binding of Bacillus thuringiensis Cry2A Insecticidal Proteins to a Common Site in the Midgut of Helicoverpa Species

For a long time, it has been assumed that the mode of action of Cry2A toxins was unique and different from that of other three-domain Cry toxins due to their apparent nonspecific and unsaturable binding to an unlimited number of receptors. However, based on the homology of the tertiary structure among three-domain Cry toxins, similar modes of action for all of them are expected. To confirm this hypothesis, binding assays were carried out with ¹²⁵I-labeled Cry2Ab. Saturation assays showed that Cry2Ab binds in a specific and saturable manner to brush border membrane vesicles (BBMVs) of Helicoverpa armigera. Homologous-competition assays with ¹²⁵I-Cry2Ab demonstrated that this toxin binds with high affinity to binding sites in H. armigera and Helicoverpa zea midgut. Heterologous-competition assays showed a common binding site for three toxins belonging to the Cry2A family (Cry2Aa, Cry2Ab, and Cry2Ae), which is not shared by Cry1Ac. Estimation of K_d (dissociation constant) values revealed that Cry2Ab had around 35-fold less affinity than Cry1Ac for BBMV binding sites in both insect species. Only minor differences were found regarding R_t (concentration of binding sites) values. This study questions previous interpretations from other authors performing binding assays with Cry2A toxins and establishes the basis for the mode of action of Cry2A toxins.     

Fluorometric Assay of Potential Change of Bombyx mori Midgut Brush Border Membrane Induced by δ-Endotoxin from Bacillus thuringiensis

Bacillus thuringiensis δ-endotoxin, CryIA(a), increased ion permeability of brush border membrane vesicles isolated from midgut epithelia of Bombyx mori larvae. This ion permeability change was measured with a potential-sensitive fluorescent dye, 3,3′-dipropylthiadicarbocyanine iodide. This effect was observed at concentrations of the toxin that correspond to normal effective doses in vivo. CryIA(b) and heat-treat CryIA(a) did not show this effect. CryIA(a) did not show this effect on rat renal brush border membranes. The effects depended on the toxin dose in saturable manner. These suggest that this assay system reflects the mode of action of δ-endotoxin in vivo. The toxin increased various ion permeabilities, suggesting that δ-endotoxin forms non-selective cation pores on brush border membranes.     

Susceptibility of the Coffee Leaf Miner (Perileucoptera spp.) to Bacillus thuringiensisδ-Endotoxins: A Model for Transgenic Perennial Crops Resistant to Endocarpic Insects

Binding of several Bacillus thuringiensisδ-endotoxins was studied on histological midgut sections of larvae of coffee leaf miner Perileucoptera coffeella from Brazil and Perileucoptera sp from Madagascar. CryIA(a), CryIA(b), CryIA(c), CryIB, CryIE, and CryIIA were tested for binding, and only CryIA(c), CryIB, and CryIE yielded a positive response. The toxins bound to the whole midgut, and the result was identical on both insect populations. The same toxins, to the number of which CryIC was added, were tested on larvae of P. coffeella. CryIA(c) and CryIB were toxic with an LC50 of 1.47 μg/ml and 21.93 μg/ml, respectively. CryIE was not toxic to P. coffeella. CryIA(c) and CryIB were tested for synergistic activity and were shown to act by cumulative effect when delivered to the insect larvae as a mixture. Received: 30 July 1997 / Accepted: 26 August 1997     

Comparison of the response of midgut epithelial cells and cell lines from lepidopteran larvae to CryIA toxins from Bacillus thuringiensis

The cytotoxic responses of midgut epithelial cells (MEC) from spruce budworm (SBW), gypsy moth (GM) and silkworm (SW) larvae were compared with the cytotoxic response of lepidopteran cell lines (SF-9, SE-1a, and CF-1) to CryIA toxins from Bacillus thuringiensis. The MEC from SBW, SW and GM had binding proteins for CryIA(a,b,c) toxins, whereas the lepidopteran cell lines had binding proteins for CryIA(c). Single MEC exposed to CryIA(a,b,c) toxins in a qualitative lawn assay were equally susceptible to the toxins with a threshold response at about 1ng. The cell lines were not susceptible to CryIA(a,b) toxins in the dose range tested, but had threshold responses for CryIA(c) of 3.4ng for SF-9, 50.2ng for SE-1a and 5.9ng for CF-1. In the quantitative Live/Dead assay, MEC were equally susceptible to CryIA(a,b,c) toxins with a threshold effect at about 1ng and a maximum effect at about 10ng. CF-1 was most sensitive to CryIA(c) with a threshold effect at 0.39ng and a maximal effect at about 1ng. In contrast, a 25-50 times greater dose of CryIA(a) or CryIA(b) was required to elicit a similar response as CryIA(c) for CF-1. SF-9 and SE-1a were most susceptible to CryIA(c) with a threshold effect observed at about 0.5ng and maximal effects at about 2ng. SF-9 cells have a threshold and maximum response to CryIA(a,b) of about 10ng and 20ng, respectively. SE-1a cells have a threshold and maximal response to CryIA(a,b) of 5ng and 10ng, respectively. Intact midgut epithelium exposed to CryIA(a,b,c) toxins had a threshold dose of 2ng for CryIA(b), 10-30ng for CryIA(a) and 2-30ng for CryIA(c). This study has shown that MEC are affected by a broader spectrum of toxins compared to the lepidopteran larvae and insect cell lines.     

Identification of putative insect brush border membrane-binding molecules specific to Bacillus thuringiensis delta-endotoxin by protein blot analysis.

Binding sites for insecticidal toxins of Bacillus thuringiensis are located in the brush border membranes of insect midguts. Two approaches were used to investigate the interactions of B. thuringiensis subsp. kurstaki HD-73 CryIA(c) toxin with brush border membrane vesicles from sensitive and naturally resistant insects: 125I-toxin-vesicle binding assays and protein blots probed with 125I-CryIA(c) toxin. In bioassays, Manduca sexta and Heliothis virescens larvae were highly sensitive, Helicoverpa zea larvae were moderately sensitive, and Spodoptera frugiperda larvae were resistant to CryIA(c) toxin. Studies of binding of 125I-CryIA(c) toxin to brush border membrane vesicles from the larval midguts revealed that all insects tested had high-affinity, saturable binding sites. Significantly, S. frugiperda larvae bind but are not killed by CryIA(c) toxin. Labeled CryIA(c) toxin incubated with protein blots identifies a major binding molecule of 120 kDa for M. sexta and 148 kDa for S. frugiperda. H. virescens and H. zea are more complex, containing 155-, 120-, 103-, 90-, and 63-kDa proteins as putative toxin-binding molecules. H. virescens also contains a minor toxin-binding protein of 81 kDa. These experiments provide information that can be applied toward a more detailed characterization of B. thuringiensis toxin-binding proteins.     

Identification of putative insect brush border membrane-binding molecules specific to Bacillus thuringiensis delta-endotoxin by protein blot analysis.

Binding sites for insecticidal toxins of Bacillus thuringiensis are located in the brush border membranes of insect midguts. Two approaches were used to investigate the interactions of B. thuringiensis subsp. kurstaki HD-73 CryIA(c) toxin with brush border membrane vesicles from sensitive and naturally resistant insects: 125I-toxin-vesicle binding assays and protein blots probed with 125I-CryIA(c) toxin. In bioassays, Manduca sexta and Heliothis virescens larvae were highly sensitive, Helicoverpa zea larvae were moderately sensitive, and Spodoptera frugiperda larvae were resistant to CryIA(c) toxin. Studies of binding of 125I-CryIA(c) toxin to brush border membrane vesicles from the larval midguts revealed that all insects tested had high-affinity, saturable binding sites. Significantly, S. frugiperda larvae bind but are not killed by CryIA(c) toxin. Labeled CryIA(c) toxin incubated with protein blots identifies a major binding molecule of 120 kDa for M. sexta and 148 kDa for S. frugiperda. H. virescens and H. zea are more complex, containing 155-, 120-, 103-, 90-, and 63-kDa proteins as putative toxin-binding molecules. H. virescens also contains a minor toxin-binding protein of 81 kDa. These experiments provide information that can be applied toward a more detailed characterization of B. thuringiensis toxin-binding proteins.